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ANTISEPTIC SUEGEEY

ANTISEPTIC SURGERY

ITS PRINCIPLES, PRACTICE, HISTORY AND RESULTS

W. WATSON CHEYNE, M.B., F.K.C.S.

ASSISTAXT-SURGEON TO KING'S COLLEGE HOSPITAL DEMOXSTRATOU OF SURGICAL PATHOLOGY AT KING'S COLLEGE

Mit^ Illustrations

LONDON iSMlTH, EI.DEK, & CO., 15 WATEKLOO PLACE

1882

[All riijhts reserveil ]

I

PREFACE.

The interest which Antiseptic Snrgery has awakened' throughout the profession has led to many j)ublic debates and to the accumulation of a great mass of literature on the subject. The time seems now to have come for a detailed account and discussion of the whole matter, and it is with the view of furnishing such an account that the present volume has been published. The question might have been dealt with in two ways ; either by the discussion of the present standpoint of the principles and practice of Antiseptic Surgery, with but little reference to former literature ; or, as I have attempted to do, by tracing in addition the development of its theory and practice, and following out and criticising the various steps by which the present state of knowledge on the subject has been reached. The former mode might no doubt have produced a shorter work, but it could not have been made complete in the present transitory state of our knowledge, and, taken alone, it would have necessarily raised side issues confusing to readers unacquainted with tlie earlier literature. I have therefore, in addition to tlie discussion (jf the present state of knowledge on the subject, tried to trace out its development, and 1 have done this the more readily because it seems to me that when an attempt is made, almost for the first time, to

X riiEFACE.

discuss fully a new department of science, the work of those who have chiefly helped by experiment or criticism to build it up should be acknowledged and properly estimated. Such a way of treating the subject will perhaps also supply a want to those who have not the time nor the opportunity of searching out the literature for themselves. Among other facts which have been brought forward here I may draw special attention to the folio wino;, which I think have been now made certain: Fermentations in wounds occur as the result of the entrance of particles micro-organisms from without ; a variety of methods of treatment may be grouped under the heading ' Antiseptic treatment ' ; lives are saved in proportion to the asepticity of the wound, and, when the wound is kept aseptic, infective diseases more especially are avoided ; the aseptic or Listerian method prevents the development of micro-organisins and the occurrence of fermentation in wounds.

Portions of this work have been previously published. Some investigations on micro-organisms in wounds and on temperature after operations formed part of my essay Avhich gained the Syme Surgical Fellowship of the University of Edinburgh in 1877. I have since that time repeated and extended these investigations. In the essay to which was awarded the Boylston Medical Prize and the Boylston Gold Medal ^ of the Harvard

' By an order adopted in 1826 the Secretary of the Boylston Prize Committee was directed to publish annually the following votes :

1st. That the Board do not consider tliemselves as approving tlie doctrines contained in any of the dissertations to which pi-eniiiinis may be adj udgt'd.

2\\(\. That in case of publication of a successful dissertation, tlio autlior be considered bound to print tlie above vote in connection therewilli.

TREFA CE. xi

University, United States, in 1880, 1 discussed the various methods of Antiseptic Surgery and the best modes of apply mg them to practice. And, in 1881, the council of the College of Surgeons of England awarded me the Jacksonian prize for a discussion of the history, prin- ciples, practice, and results of Antiseptic Surgery. This work is the outcome and development of these essays.

The drawings in this book (both the woodcuts and the plates) have been made by Mr. Edgar Thurston, to whom I am much indebted for the great pains which he has bestowed m their preparation. Mr. Groves also kindly took some photographs, from which certain of the woodcuts have been drawn. Dr. Heron has ren- dered me great assistance in revising the proof-sheets and in preparing the Index.

In dedicating this work to Mr. Lister I have attempted to acknowledge my great indebtedness to him.

W. WATSON CHEYNE. 0 Old Cavendish St., \V. October 1881.

CONTENTS.

CHAPTER I.

THE PARTICULATE THEORY OF FERMENTATION. ON THE FERMENTATION OF BOILED SUBSTANCES.

TAGR

Definition of putrefaction and fermentation Chemical fermentations Living ferments Various views on fermentation Lavoisier Fa- broni Tlienard \ppert Gay-Lussac's experiments and conclusions Caignard-Latour Schwann, heated air inert Schulze Ure and Helmholtz, nascent oxj^gen inert Liebig's views— Review of the subject Schroeder and Dusch, filtered air inert Schroeder, ozone inert Schroeder's final views Pasteur's researches Lister Roberts Tyndall^My own results, carbolised air inert Conclusions as to the cause of the fermentation of boiled substances .... 1

CHAPTER II.

THE PARTICULATE THEORY OF FERMENTATION {continued).

ON THE FERMENTATION OF UNBOILED SUBSTANCES.

{jVAiiti yncc—Gaif-Liiasa' Van tier Brocck— Pasteur Boberts; blood Van (Icr Broech Pasteur Bvrdoii- Sanderson Lister 3Iy own re- sults; unboiled urine Van der Broeelt Pasteur Lister My own results— Boberts Cazeneure and Liron; milk Hoppe-Seyler Bo- hrrts LAster My own, experiments ; egg albumen Van der Liroerk

Gayon BobeHs My own experiments; vegetable tissues Boberts; animal tissues Billroth 'Hegel Burdon-Sanderson My own ex- periments— C'Mene and Ewart Meissner General review of the facts

Behaviour of fluids and tissues in the living body— Principles of aseptic surgery ;{()

CHAPTER in.

ASEPTU; SUR(;EKY materials EMPLOYED,

Problems to be solved in order to kcoi) a wound aseptic : Carbolic acid - Carbolic lotions - Pure earbolic aeid Solution in methylated spirit rarbol/e oil - Carbo/ie aeid and ylyrerine : Spray fjroducers: Catgut

CONTENTS.

Carholisrd caffpit- Mr. Litsfcr'a earholtsi'd chromic catf/nt Dr. J\fac- Ewcn's chromic catf/iit Caft/iit troiir/h a)id j/ochct caxc: Carbolised silk: Protective: Carbolic gauze Composition Method of preparation Yon lirun\'< gauze : Macintosh : Sponges : Boracic acid Boracic lotion Boradc lint Boracic ointment : Salicylic acid —SalicijUc acid, cream. Salici/Uc ointment : Chloride of zinc : Iodoform : Carbolised cotton wool 52

CHAPTER IV.

ASEPTIC SURGERY [confinned).

Example of an aseptic operation : Purification of the skin Fingers Instruments: Spray Precautions— Probable errors, and mode of re- medying them : Guard : Ligature of arteries : Drainage of wounds India-rubber tubes Catgut drains —Horse hair Decalcified bone tubes (Neuber's and MacBwen's) : Sutures: Button stitches Stitches of re- laxation— Stitches of coaptation Aseptic strapping Protective : DeeiJ dressing : Loose gauze : Gauze dressing : Elastic bandage. Changing THE DRESSINGS Time Method. Treatment of ulcers : Purifica-* tion of the sore : Boracic dressing : Boracic and salicylic ointment : Boracic poultice 67

CHAPTER V.

ASEPTIC SURGERY (cOUtintieJ).

Special dressings : Head dressfiiigs : Neck dres.tings : Bread dresKinfiK Abscess of mamma Excision of mamma alone Excision, of mamma, and axillary glands : Axillary dressings : Dressings on the limhs : Dressings for psoas abscess : Lumbar abscess : Hip-joint abscess : Dressings in cases of hernia a7id operations on the scrotum: Excisions of joints. AsejDtic treatment of abscesses. Chief points to be con- sidered in opening abscesses Method of opening abscesses Drainage of absresscs— After-treatment of abscesses Empyema Perineal and anal abscesses. Treatment of wounds produced accidentally : Problem to be solved— Purification of wound Further treatment of the n'ound. Special wounds : Compound fractures : Wounds innolring tendons, nerves, <^'c. : Wounds of joints : Compound fr act w'es of the skull: Pene- trating wounds of the thorax: Wounds of the abdomen. Putrid sinuses and wounds. Treatment cf burns. Treatment of gangrene. Treat- ment of na;vi and varicose veins ........ 0(5

CHAPTER VL

ASEPTIC SURGERY MODIFICATIONS.

Country practice : How to dispense with the spray during the operation and during the aft:;-: '^-eatment: How to render the ilreasings less fre-

CONTEXTS. XV

PAOK

quent. Is the aseptic method applicable in war ? 3rr. Lister' s< snggestians : Esmarch's X}liui : Jiei/Jier's method. Development of Aseptic Surgery in Mr. Lister's hands : Compound fractures— Pvre carbolic acid Formation of crust Carbolic putty Lead 2)laster Imc plaster, syringing wounds with carbolic lotion, protect'n^e, catgut ligatm-es, method in 1870 Present method in the main introduced in 1871 Further introduction of wet gauze, steam spray, elastic bandages: abscesses Method of opening them under carbolic oil : wounds . .120

CHAPTER Vll.

ASEPTIC SURGERY {concluded).

other methods of carrying out Aseptic Surgery. Substitutes for carbolic acid: Salicylic acid : Thymol: Acetate of Alumina : Eucaltjptus oil. Aseptic surgery by filtration of the air. Subcutaneous surgery . . i.SO

CHAPTER Vni.

THEORIES OF SPONTANEOUS GENERATION, HETEROGENESIS AND ABIOGENESIS.

Principles on which other methods of Antiseptic Surgery act. Organisms are always present in fermenting liquids : their significance. Theory of the origin of organisms independently of a parent. Theories of Needham and Buffon : Needham's proofs. Spallanzani"s experiments : Needham's objections : Spallanzani's replies. Schulze's experiments. Schwann Schroeder and Duscli Schroeder. Doctrine of Hetero- genesis. Poiichet's work : his method of test ing the matter : proofs that the source of the organisms in infusions is neither the air, water, nor the putrescible substances : modes of repeating Schulze's and Schwann's experiments : examination of dust. Criticism of his re- sults. Pasteur's experiments : results with ordinary fluids : introduc- tion of dust into sterilised fluids : results with milk and alkaline fluids : the cause in the air which gives rise to the growth of organ- isms is particulate : Pasteur's cultivating fluid : estimate of Pasteur's work. Pouchet's reply : New experiments— Criticism of tliese . . 14")

CHAPTER IX.

SPONTANEOUS GENERATION {continued).

The experiments of Jeffries Wyman : explanation of the results : VVyman's views on the subject. Dr. Uastian's views: Cases in which it is still possible that abiogcnesis may occur : Growth in vacuo— Bastian's ex- periments—my own results Cohn's facts Dj- Roberts's ohjection.s, the walls of the ve.s.sels remain impure Basfian's reply Objections to the latter Graitlmiscn's experiments Pau i.i-rt's results wiili

CONTENTS.

compressed air Pouchct looks on a vacuum as preventing spontaneous generation Paul Bert's results with rarefied air Ur. Bastian does not always get positive results : Experiments in airless and hermetically sealed flasks raised to a high temperature Objections— Prof. Huxley's and Dr. Sanderson's statements Ray Lankester's results Hartley: expei'imen-ts with alkaline fluids Roberts's counter-experiment. Mr. Lister's experiments. Experiments by Roberts and Tyndall . .172

CHAPTER X.

SPONTANEOUS GENERATION (conchtded).

Facts with regard to unboiled fluids and tissues : Mr. Lister's facts with regard to milk : my own experiments with animal tissues. Present state of the question Dr. Bastian's latest standpoint : Lie- big's doctrine. Can organic molecules derived otherwise than from pre-existing bacteria give rise to bacteria ? Firstly, there is nothing unreasonable in looking on these particles as bacteria or their germs: seeds carried by air : excessive minuteness of the germs of bacteria : Mr. Lister's experience with micrococci. Secondly, there is no direct evidence that organic molecules not derived from bacteria can give rise to bacteria : facts with regard to unboiled fluids and tissues conclusions from these facts : Paul Bert's experimenTs : Cazeneuve and Livon: Pasteur: Dr. Bastian. Thirdly, there is no evidence that active organic molecules (chemical ferments, &c.) can resist heat more than living things can : effects of heaJt on ptyalin, pepsin, •&c. : my own case of difficulty in sterilising mil'k : Wyman's fact as to an alga living at 208 F I94

CHAPTER XT,

RELATION OF MICRO-ORGANISMS TO FERMENTATION.

■Summary of what has preceded with reference to fermentation. Relation between ' vital ' and ' chemical ' fermentations : theories of fermen- tation. Liebig's views. Alcoholic fermentation : Paxte^ir'' » experiments tnid eonchishms. Rfsnmc. Butyric fermentation. Formation of pig- iiTicnt by bacteria. Schroeter : Cohn. Viscous fermentation. Lactic fermentation : Panteur : Lister. Other fermentations, especiaJly tJbe putrefactive: Levi aire ; Cazeneuve and Liron:: Paul Bert. C'onclu- ■sions ............. 20;'i

(mAPTER Xn.

RELATION -OF MI€RO-ORGANISMS TO THE FLUIDS AND TISSUES OF THE LIVING BODY.

Propo.sed mode of cnquir;- Does the aseptic met liod prevent putref^ac- tion? Does it exclude organisms from wound.s? Kanke's results:

CONTENTS.

Klebs' objection: Ranke's reply: Demarquay : Fischer: Schiiller : my own method Results in aseptic wounds Results in wounds treated otherwise Koch's method of staining pus Results in cases not treated aseptically Examples of complete exclusion of organ- isms in aseptic cases Examples of the entrance of micrococci in aseptic cases Detiuition of micrococci Distinctions between micro- cocci and bacteria. Are organisms present in the healthy living body ? ' Bistournage.' Are organisms present in the body in states of disease ?— Experiments with ammonia, phosphorus, &c. The healthy blood and tissues can destroy organisms Relation of organ- isms to abscesses. How do micrococci enter aseptic wounds 1 Car- bolic lotion a salficient germicide ; Spray, its value Stimson's experiments ; Gauze dressing as a protection against entrance of organisms ; Carbolic acid as a germicide in albuminous fluids ; Rela- tions of micrococci aud bacteria to fluids containing carbolic acid. Conclusions . . ......... 225

CHAPTER XIII.

ANTISEPTIC SURGERY.

Complete definition of antiseptic surgery. Varieties of antiseptic sur- gery. Treatment by Antiseptics : Carbolic acid objections to it : Chloride of zinc : Boracic acid : Sulphurous acid : Chlorinated Soda : Alcohol Hutchinson's method : Terebene and Sanitas Bilguer's method Neudorfer's salicylic powder. Free drainage as an an- tiseptic 3IETHOD. Irrigation and immersion. Open method: Modes in which it acts antiseptically : Bartscher and Vezin's method : Burow's method: Rose's modification. Healing by scabbing: Methods of forming a crust : Bouisson's ventilation method : other modes. Cuerin's cotton-wool dressing. Modes in which

THE destructive ACTION OF THE TISSUES ON BACTERIA IS AS- SISTED. Wliy does not fermentation always occur in the blood in wounds in wliich organisms are present ? Best practical methods. Conclusions 265

CHAPTER XIV.

HISTORY OF ANTISEPTIC SURGERY.

Practice of the ancient writers. Attempts of the ancients to secure im- mediate union of wounds. Pare and Paracelsus : Delacroix : Arcjeus : Progress of wound treatment in the sixtcentli century. Seventeenth century: Magatus: Wiseman: Colbatch : Progress in the seventeenth century. Eighteenth century and the early jiart of the nineteenth : Boerhaave : Col dc Villars : Heister : Bilguer : Benjamin Bell : Abcr- nethy : John Hunter's objections to the views of Bell and Abernethy : John Bell : opinion and practice of other surgeons : Conclusions : Von Kern . . 290

CONTENTS. CHAPTER XV.

HISTORY OF ANTISEPTC SURGERY (continued).

I'AOB

History of the various methods. Incubation : Gu3'^ot. Subcutaneous surgery, preliminary attempts : Stroraeyer : DielTcnbach : Jules Guerin : Langenbeck : Other authors. Occlusion : Jules Guerin : Chassaignac Eochard's remarks: Pansement ouate Alphonse Guerin, method and results Oilier. Substitution of various gases for air: Demarquay and Leconte. Open Method: I'Sartscher and Vezin: Burow: Humphre}-. Healing by scabbing: John Hunter: Xeudorfer : Bennion : Lister : Bouisson : Bonnet, kc. Irrigation and the water-bath : early history : Josse : Berard : Mayor: Amussat : Langenbeck: Valette 317

CHAPTER XVI.

HISTORY OF ANTISEPTIC SURGERY (conckuhd).

Use of antiseptics: Alcohol older WTiters Nelaton Hutchinson: Glyce- rine—Demarquay : Chlorine: Chloride of zinc: Iodine: Iodoform: Chlorate of Potash : Perchloride of iron, &c. : Coal tar Corne and De- raeaux Report of the commission : Coal tar saponine Lemaire his views on putrefaction : Carbolic acid Lemaire Lemaire"s position n regard to Aseptic Surgery Lister : Further phases in the historjr of this subject : Objections to Mr. Lister's claim as originator of the Aseptic method Simpson Neudorfer. Modifications of the method. Su.bstitutes for carbolic acid. Objections to the Aseptic method . . 347

CHAPTER XVII.

RESULTS OF ANTISEPTIC SURGERY.

Chief points for consideration. How far do the various methods prevent fermentations in wounds ? How to ascertain the true value of any individual method. The value of the various methods in guarding against infective disease: meaning of the term 'infective disease' Relations of Aseptic Surgery to infective disease. 3/r. Lufrr's remdtn iv fllaariow. The recent Glasgow .tfatiaficK. Mr. Lixter's resvlts in Edinlmrf/h ; re.snlts in sejftic and asej)tio ca^es 3/r. Sjfcnce's jwactice Mr. Slime's results Mr. Lister\'< results at Kinff's Cnlle/je Hospital : Volkmann Nmshauni Socin Saxtorph Esmareh. lluetcr Czeriiy Lucas- Cliamqnonnix-re Gross LHievant Panas Schede— Reyher Spencer Wells Keitli^Thornton. TliicrscVs results with salicylic acid. Thymol. The relations of other forms of Antiseptic Surgery to these diseases Treatment hy Antiseptics Beyher lAstcr Nvlaton JTutchinson. Occlusion Jules Gverin Alphonse Guerin. Treatment hy irrigation and mater hath Langcnheck Valette. Open

CONT'ENTS. xix

PAGE

Method Barischer and Vezin Bvrmv Kr'onlein. Results where no antiseptic measures were adopted Billroth Malyaigne Paul Holmes Erich&en. Eesults of cleanliness Mo Vail Bardenheuer . 365

CHAPTER XVIII.

RESULTS OF ANTISEPTIC SURGERY {continued).

General considerations. Wounds of, and operations on, healthj* joints. Method of treatment adopted in these cases. Definition of the term 'Aseptic course': Example. Wounds of healthy joints. Operations on healthy joints. Objections to the value of these cases : reply. In- cisions into joints affected with synovitis. Incisions into joints af- fected with pulpy degeneration of the synovial membrane a without suppuration, b with suppuration. A''oliimann's results : Max Schede : Paul Barth : Saxtorph : Piechaud : Nussbaum : Albert : Hueter : Letievant : Kraske : Eeyher: Bergmann. Comparison of Pieyher's results with those obtained during the Crimean war, and with Heint- zel's. Treatment bj' irrigation. Necessity for observing the minutest precautions as shown by Mr. Lister's case. Piesults of removing foreign bodies from joints without aseptic precautions : Larrej^ : Speuce : Paget 417

CHAPTER XIX.

RESULTS OF ANTISEPTIC SURGERY {continued).

Compound fractures. Differences between those produced accidentallj^ and those caused by the surgeon : treatment and after-progress of each class. Tables of accidental compound fractui-es treated by Mr. Lister: thigh; leg; liutner us ; forearm ; skull; summary of results. Tables of compound fractures produced intentionally bj' Mr. Lister ; femur ; leg ; clavicle ; humerus ; forearm ; lower jaw. General summary of Mr. Lister's results. Mr ^pence's results. Other operations on bones by Mr. Lister. MacEwen's osteotomies : Volkmann : Max Schede : Bardenheuer : MacCormac. Combined aseptic results: Results br- other methods . Volkmann and Fraenckel : Holmes : St. Thomas's IIosjDital. Rej'her's results in war. Open method: Kronlein. Septic methods 461

CHAPTER XX.

RESULTS OF ANTISEPTIC SURGERY {continued).

Abscesses connected with di-sease of the vortebne. Best situation for opening psoas abscesses : best time for opening them : after-treatment and after- progress. Table of Mr. Lister'.s results : general summary and remarks on these cases. Comparative statistics are wanting. Sir James Paget 's views . . . 'Al

XX CONTENTS.

CHAPTER XXI.

RESULTS OF ANTISEPTIC SURGERY (concluded).

PAGE

General consideration of the results. Results of the various methods in saving life. Results in avoiding infective disease. Cleanliness : defi- nition of the term : Mr. Savorj-'s definition and method : cleanliness has not abolished infective disease even in healthy hospitals : cleanli- ness is a complex method : infective disease may appear even in the best hygienic conditions. The source of infective disease. Conclu- sions as to the value of the various methods in preventing infective disease. Deaths from prolonged suppuration after chronic abscesses, compound fractures, &c. Operations on weak or diseased individuals are rendered possible by the aseptic method. Operations otherwise iinjustifiable,but nevertheless necessary for the recovery of the patient, may be safely done by the aseptic method. The patient may be made a more useful member of society: joint cases : tenotomy, &c. : com- pound fracture : dangers of operations of convenience. Local results of wounds treated aseptically : absence of pain, inflammation, &c. : experiments of Yeo and Ferrier : organisation of blood-clot, catgut, sloughs, &c. Histological details of the process : Tillmann's experi- ments. Temperature in aseptic cases : contrast with septic cases. Local and constitutional course of cases not treated aseptically. Objec- tions to aseptic surgery: carbolic acid poisoning: the surgeon is said to neglect the constitutional state of the patient: expense: trouble : necessity for the spray. Conclusion : great principle of wound treat- ment is Rest . 540

Index 603

LIST OF ILLUSTRATIONS.

1. .Schwann's method of admitting heated air to putrescible fluids . . 7

2. Schroeder and Dusch's apparatus for supplying filtered air . .13

3. Pasteur's flask with the bent neck 16

4. Door of Mr. Lister's hot box 18

5. Mr. Lister's hot box 18

6. Mr. Lister's large double-necked flasks 19

7. Method of filling these flasks 20

8. Mr. Lister's arrangement to protect fluids in liqueur glasses from dust 21

9. Mode of filling Mr. Lister's liqueur glasses ...... 21

10. Dr. Roberts's bulbs (copied from Roberts) , 23

11. Prof. Tyndall's pure chamber (copied from Tyndall) . . . .24

12. Dr. Roberts's experiments with grape juice (from Roberts) . . 33

13. Pa.steur's method of obtaining fresh blood (from Pasteur) . . .34

14. Beaker containing unboiled meat and a putrescible fluid . . .46

15. Hand spray producer 54

16. The ordinary steam spray producer . 54

17. Steam spray producer, showing the lamp at present in i;se . . . 55

18. Large steam spray producer with double nozzle for ovariotomy, kc. . 56

19. Trough for catgut 59

20. Lister's pocket catgut holder 59

21. Machine used in the Glasgow Royal Infirmary for manufacturing

gauze 63

22. Porcelain trough containing instruments .soaking in carbolic lotion , 70

23. General arrangement of surgeon, assistants, towels, spray, &c., in an

operation performed with complete aseptic precautions . . .71

24. To .show the arrangement of towels, &c., in a large operation . . 72 2'>aMcth()(\ of tving vessels in dense tissues ...... 75

xxii LIST OF ILLUSTRATIONS.

25/'.Anotlier method of tying vessels in dense tissues (from Esmarch) . 76

26. Ordinary oblique-ended drainage-tube ready for use . . . .77

27. Drainage-tube with masses of gauze in the loops of tliread . . 77

28. Incision for inguinal hernia, stitched, showing tlie position of the

drainage-tube at the outer angle of the wound . . . .78

20. Sinus forceps ^9

.30. Catgut drain ready for insertion 80

31. Operation for stretching the sciatic nerve 82

32. The same wound stitched 83

33. Method of preparing a horse-hair drain for re-introduction . . 84 3-1. Lead buttons for deep stitches 85

35. Wound after removal of mamma and axilliary glands, stitched . 86

36. Excision of the hip-joint 88

37. Dressing in a case of psoas abscess opened above Poupart's ligament 90

38. Method of changing a psoas abscess dressing 92

30. General arrangement of dressings on the neck . .... 97

40. To show the arrangement of the turns of bandage on the head, seen

from above 98

41 . Dres.sing applied in a case of abscess of tlie mamma (breast dressing

No. 1) 98

42. Breast dressing No. 2 98

43. Dressing after excision of the mamma 99

44. Dressings applied after excision of mamma and axillary glands, to

show the arrangement of the dressings and bandages . . . 100

45. Binder applied outside the dressing represented in tig. 44, so as to

keep the parts and dressing at rest ...... 101

46. Dressing in cases of operation on tlie axilla alone .... 102

47. Dressing in a case of psoas abscess opened above Poupart's ligament,

seen from the front 103

48. Psoas abscess dressing (fig. 47), seen from behind .... 104

49. Dressing in a case of lumbar abscess, seen from behind . . . 101

50. Dressing in a case of hip-joint abscess, with elastic api^lied . . 105

51. Deeper part of the hernia and scrotal dressings 106

52. Dressing in a case of operation for hernia, or on the scrotum on the

left side, showing the arrangement of the dressing and elastic bandage 106

53. Dressing in hernia cases or in operations on the scrotum, showing

the arrangement of the bandages in the perineum. (Seen from below) 107

54. Si^lint for excision of knee, read}' for application .... 108

LIST OF ILLUSTRATIONS. xxiii

nr,. PAGE

5. Splint applied in a case of excision of the knee ..... 108

56. Two forms of sharp spoon.s, a large round one and a .small oval one . 117

57. Esmarch'.s first dressing for the wounded in battle (from MacCormac) 121:

58. Schulze's method of demonstrating that organisms are derived from

the air and do not originate spontaneou.sly in liquids . . . 150

59. Pouchet's mode of repeating Schulze's experiment (from Pouchet) . 156

60. Another mode adopted by Pouchet for testing Schulze's views (from

Pouchet) 156

61. A simple mode of repeating Schulze's experiments (from Pouchet) . 161

62. Pasteur's mode of introducing dust into flask containing calcined air 165

63. Another mode of repeating Schulze's experiment (from Pouchet) . 169

64. Bacillus subtilis ; without spores; with spores in the rods; free

spores; x 600 (after Cohn) ........ 180

65. Deposit in rennet, consisting of a mass of micrococci and spores of

bacilli, X 600 (after Cohn) 180

66. Dr. Roberts's experiment with alkaline fluids ..... 192

67. Torula cerevisiaj (after Pasteur) 210

68. Pasteur's experiment on unboiled grape juice ..... 210

69. Bacillus subtilis, x 650 (after Cohn) 212

70. Pigment producing organisms ........ 213

71. Bacterium lactis in pairs and chains . . . . . . .216

72. Flask containing cultivating fluid inoculated from a wound . . 231

73. Thiersch's ichampagne bottle irrigator . 273

7-1. Arrangement for irrigation in the upper limb (after Esmarch) . . 274

75. Arrangement for irrigation in the lower limb (after Esmarch) . . 275

76. Apparatus for continuous immersion (after Esmarch) . . . 275

77. Temperature chart from a case of operation for fracture of the

patella. (No. 21, p. 434) 421

Temperature charts of Mr. Lister's cases of wounds and operations on joints (i.-xvii.) 438, 439

78. Temperature chart from a case of compound fracture in which the

attempt to eradicate the causes of fermentation was unsuccessful, and which therefore became a septic case. (No. 26, p. 472) . . 463

79. Temperature chart from a case of compound fracture which followed

anasopticcour.se. (Case 23, p. 472) 4f,4

Temperature charts of Mr. Lister's cases of compound fracture

(xviil.-xxx.) 482, 483

Temperature charts of IMr. Lister's cases of compound fracture

(xxxi.-L.) 500, ,501

Temperature charts of cases of psoas and lumbar abscess (li.- LXVli.) 534,535

xxiv LIST OF ILLUSTRATIONS.

FIG. I'AGE

80. Temperature cliart. from a case of MacEvven's operation for double

genu vulgum ........... 576

81. Temperature chart from a case of compound fracture, in which there

was great difficulty in retaining the fragments in position. (Case 27, p. 472)

82. Temperature chart from a case where the ankle-joint was incised in a

hajmophilious patient, and where hfemorrhage recurred several times. (Case 16, p. 430) 581

83. Temperature chart from the case of removal of loose cartilage from

the knee-joint, in which fermentation occurred. (Case 22, p. 434) 582

84. Temperature chart from a case of operation for recent fracture of the

patella. (Case 15, p. 430) 582

Temperature charts of septic cases 584

Temperature charts of aseptic cases 585

ANTISEPTIC SUEGEEY.

CHAPTER I.

THE PARTICULATE THEORY OF FERMENTATION. ON THE FERMENTATION OF BOILED SUBSTANCES.

Definition of putrefaction and fermentation Chemical fermentations Living ferments Various views on fermentation Lavoisier Fabroni Thenard Appert Gay-Lussac's experiments and conclusions Caignard-Latour Schwann, heated air inert Schulze Ure and Helmholtz, nascent oxygen inert Liebig's views Review of the subject Schroeder and Dusch, filtered air inert Schroeder, ozone inert Schroeder's final views Pas- teur's reseai'ches Lister Roberts Tyndall My own results, carbolised air inert Conclusions as to the cause of the fermentation of boiled sub- stances.

The term ' septic ' so much used in surgery at the present day is derived from the Greek word (X7]ittlkos, which means some- thing that causes putrefaction, the verb (ji!]itw signifying to cause to rot, to make putrid. An 'antiseptic' is therefore, according to this derivation, something w^hich acts against the causes of putrefaction, and ' Antiseptic Surgery ' is surgery directed not against its effects but against its caitses. In deal- ing, then, with the subject of antiseptic surgery, we must first enquire what is putrefoction, and how is it brought about ?

Putrefaction is now held to be a form of fermentation ac- companied by the development of offensive odours, and fermen- tation may be defined as ' a new arrangement of the elements of an organic compound (often with the assimilation of the ele- ments of water), and the consequent formation of new products.' (Fownes.)

Changes coming under the nbove definition of fermentation

B

2 THE PARTICULATE THEORY OF FERMENTATION.

have been long known as the result of what is termed Catalysis. Of this perhaps the best example is the change effected in Amygdalin by the action on it of Emulsin. As a result of the contact of these two bodies in presence of water, the amygdalin is broken up into various products, of which the chief are hydrocyanic acid and oil of bitter almonds. This decomposition of amygdalin is, however, not effected by combination with emulsin, for the latter remains unchanged, although its presence is necessary for the chemical action. Similar fiicts are known with regard to the Pepsin of the gastric juice, the Ptyalin of saliva, the pancreatic ferment, &c. But although these ferments undergo little or no change, yet nevertheless it has been clearly proved that they have not the jwwer of self-multiplication. Hence these ferments generally receive the name of ' chemical ' ferments.

There is, however, another class of ferments which possess this power of self-multiplication in a remarkable degree. An instance of this may be given in the alcoholic fermentation. Here a minute piece of yeast is introduced into grape juice, or into a sugary solution, and as a result fermentation soon sets in, and goes on slowly till the sugar is decomposed. If we compare this process with the former we see two marked points of difference ; in the first place, in the former the change is rapid and more or less instantaneous; in the latter it progresses slowly and steadily, and requires much more time for its com- pletion. In the former there is no increase in quantity of the ferment ; in the latter the increase is very marked, and when the fermentation has gone on for some time the minutest portion of the fermenting substance added to unfermented material of like composition produces in it a similar series of changes ; and this multiplication of the ferment goes on continuously whenever it is brought in contact with fresh material. As this power of multiplication is a property of living things, the term ' vital ' is usually applied to this class of ferments.

In one point the ' chemical ' ferment is allied to the ' vital ' ferment. It is not a substance as yet formed by the "chemist. It is the product of living cells ; and it is quite possible that the yeast plant may act in the same way as the salivary or

THE FERMENTATION OF BOILED SUBSTANCES. 3

peptic cells, viz. by excreting a ferment which produces the change in the fermentescible substance, this ferment in neither case possessing the power of self-multiplication. In the case of the salivary ferment the cells which produce it are an integral part of a complex organism, and cannot live apart from the body ; hence the ptyalin, introduced into starch, does not increase in amount. On the other hand, the yeast plant is an independent cell, and grows free in the fermenting fluid, and it is to the growth and multiplication of these living cells, and not to an increase in quantity of the chemical ferment as such, that the multiplication of the fermenting power is due.

In the putrefaction of discharges in wounds we have to deal with a ferment belonging to the same class as the alcoholic fer- ments— with a ferment capable of multiplication, which acts slowly and steadily, not suddenly. We must therefore enquire a little more fully into the nature of this class of ferments, into theii- origin and history, in order to obtain some principles to guide us in attempting to prevent their action.

In reviewing the history of this subject, the first research of any consequence which it is necessary for us to consider is that of Gay-Lussac* Previous to the publication of this paper at- tempts had been made by Lavoisier, Fabroni, and Thenard to give some explanation of the process of fermentation.

Lavoisier's work was in the main carried out with the view of ascertaining the changes which a fermenting liquid under- goes.^ He did not attempt to assign a definite cause for the process.

Fabroni,^ writing on the subject of the alcoholic fermentation, concluded that fermentation was a decomposition of one sub- stance by another, 'just as a carbonate is decomposed by an acid, or sugar by nitric acid. The substance which decomposes sugar is a vegeto-animal substance. It is contained in certain utricles in the grape. When the grape is crushed this material, which is of the nature of gluten, mixes with the sugar in the juice, and as soon as these two substances come into contact, effervescence or fermentation commences just as occurs in every

Annates de Cliinrie, Ixxvi. 1810. ^ J'JUtiindit de CMmic, i. 2nd ed. ^ Annalrs de Chimtr, xxxi. 1799.

4 THE PARTICULATE THEORY OF FERMENTATION.

other chemical process, as, for instance, when an acid and a carbonate are mixed in the same vessel.'

Some years later, but ignorant of Fabroni's views, Thenard published a research on alcoholic fermentation,' in which he showed that gluten had no power whatever of causing the fermentation of sugar. He observed that during the pro- cess of fermentation, a deposit occurred which had the power of inducing a similar change in a fresh saccharine liquid. This substance was apparently the same in a great variety of liquids of different chemical composition, and it presented characters similar to those of yeast. Thenard states that he was unable to determine whether this substance was formed in the course of the fermentation, or whether it was in solution at the com- mencement and became deposited as a result of the changes which occurred. He, however, inclines towards the latter view.

Gay-Lussac was led to make his investigations by studying the procedure of M. Appert for preserving vegetable and animal substances.^ Appert's method consisted in placing the materials to be preserved in bottles, very closely corked. These bottles were exposed to the temperature of boiling water for a longer or shorter period of time. They were then packed up and kept for use. There can be no doubt as to the efficiency of this method, for in Appert's work certificates are furnished by several scientific commissions, containing such names as Gay- Lussac, Bordel, &c.

Gay-Lussac noticed that, though the sul^stances so prepared could be preserved unaltered for an indefinite period so long as the vessels were kept thoroughly closed, yet, as soon as the vessels were opened, and more especially if the substances were decanted into other vessels, their contents underwent fermentative changes.

To ascertain why this occurred, he took a flask of grape-juice which had been preserved for a year unaltered, and which was ac- cordingly quite limpid. Having opened the flask he poured its contents into another vessel, which he closed very accurately and kept at the temperature of 15° to 30° C. Eight days later

' Atuudcs de ChhnU; xlvi. ISOiJ.

^ The Art of Preserving Animal and Vegctuhlc Suhstanees.

GAY-LVSSACS EXPERIMENTS. 5

the juice had lost its transparency, fermentation had become established, and it soon became an alcoholic fluid. A second vessel containing gi'ape-juice, prepared by Appert's method, was kept at the same temperatm-e and in the same place, but unopened. This remained pure. This latter flask, the neck of which had been drawn out and sealed, was now taken, and a deep notch having been made with a file, its neck was plunged into mercury and then broken off. A portion of the contents was then introduced into a bell-jar containing no oxygen, and a second portion into one containing a small quan- tity of that gas. The first remained without change for forty days, while the second underwent fermentation very rapidly. In the latter flask all the oxygen had disappeared, but much more carbonic acid in proportion had been produced. Gay- Lussac therefore concluded that, although oxygen is necessary to initiate the fermentation, yet it is not essential for its con- tinuance. The same results were obtained when currant-juice or freshly prepared gi'ape-juice were used. Gay-Lussac further found that, if this juice after being transferred from one vessel to another were again heated after secure corking, it could again be preserved for an indefinite time. He observed that during the boiling the fluid lost its transparency and a deposit took place. He came to similar conclusions as to the necessity of oxygen for the initiation of fermentative processes, in the case of the putrefaction of meats, &c., preserved according to Appert's method,

Gay-Lussac concludes from his experiments that oxygen is necessary for the commencement of the fermentation ; that this oxygen combines with some substance in the fermentescible fluid, thus producing the ferment, which can then act without further oxygen ; that the effect of the heat in Appert's method is to decompose any combination already formed, and to make the oxygen which is present unite to form some substance which is not a ferment ; that the product of this union with oxygen is the deposit which is seen to occur on heating these fluids. 1 [e however recognises that fermentation is still a mysterious process, since it occurs slowly and not immediately like other chemical actions.

Passing now over a period of some years, we come to the

G THE PARTICULATE THEORY OF FERMENTATION.

views of Caiguard-Latour, made known in papers presented to the French Academy dming the years 1835-37.' On examin- ing fermenting grape-juice, he found (as indeed had been im- perfectly observed before by Leuwenhoeck and Desmazieres) that it contained numerous globular bodies which he considered to be of vegetable nature, and which he found to possess the power of reproduction, partly by budding and partly, as he sup- posed, by contracting and liberating numerous spores. From several facts amongst others, from finding that in juices not undergoing alcoholic fermentation these bodies were absent, while they were always present where that fermentation oc- curred— he concluded that they were the cause of the fermenta- tion. He fm-ther found that the de})Osit of which Thenard spoke, and which he had stated to be the ferment, was composed entirely of these bodies.

Similar views were announced almost simultaheously by Schwann,'-* and to him rather than to Caignard-Latour must be given the credit of having furnished the first real proof of the view that these cells were the causes of the fermentation.

Schwann prepared infusions of meat, fruits, &c., somewhat after Appert's method, but, instead of leaving the vessels com- pletely sealed, he allowed air which had been previously heated to come in contact with the fluids. The following is his de- scription of the method which he ultimately adopted.

' Into a three-ounce vessel a small piece of meat was introduced, and then water was added so that the whole occupied about one- fourth of the capacity of the vessel ; the bottle was then closely corked, the cork being firmly fastened down by wire. This cork was traversed by two small glass tubes, one of which was at once bent downwards on its exit from the vessel, and its orifice dipped into a small beaker containing mercury covei-ed by a layer of oil. The other tube ran at first horizontally and then directly downwards for an inch and a half. There it had two narrow spiral turnings, then it again ran upwards, and finally horizontally, being di'awn out to a fine point at its termi- nation. The cork was covered with several layers of a solution of caoutchouc in linseed oil, rendered thinner by the addition of oil of turpentine. The fluid in the flask was now boiled, and the steam was made to issue from the two tubes till the mercury and oil became so

See Annales de CMmie ct de Ph unique, t. Ixviii. 2" seric, 1838. * Pofjgendorf's Annalen, xli. 1837.

SCHWANN'S EXPERIMENTS.

hot that they no longer condensed the steam. (In order that no organisms might develop in the water which remained between the oil and the mercury, a layer of corrosive sublimate was placed between them.) While the boiling was going on a spirit lamp was placed under the spirals of the second tube, and the heat was continued until the tube began to soften (see Fig. 1). Thedropaof water condensing in the cooler parts of the tubes were dispelled by another lamp. After boiling bad continued for a quarter of an hour it was stopped, and, during the cooling of the flask, air passed through the second glass tube into the vessel, being however j^reviously heated in the spiral part of that tube. After complete cooling of the flask the orifice of this tube was sealed and the portion of the tube between the spiral and the end, containing unheated air, was heated. That being done the spirit lamp was completely removed.'

Fig. 1. Schwann's mkthod.

Prepared in this way, the flask contained only boiled meat infusion and heated air. From time to time this air was renewed in the following manner : the spiral part of the tube having been heated almost to melting, the point was broken and fresh air forced slowly in, the old air bubbling out through the mercury. After a time the tube was again sealed with the same precautions as before.

By operating thus Schwann succeeded in preserving meat and other substances at a temperature of 63° to 77° F. without any putrefaction, and without the appearance of organisms in them ; while the same materials when exposed to ordinary air underwent putrefactive changes in a few days.

8 THE PARTICULATE THEORY OF FERMENTATION.

It was thus evident that there was a something present in the air, other than the gases of the air which had the power of bringing about fermentative changes in boiled liquids, and that this something could be destroyed by heat.

Some -further experiments which Schwann performed with reference to the alcoholic fermentation furnish additional evidence against the view that the gases of the air are the causes of putrefaction.

A solution of cane sugar having been mixed with yeast, four flasks were quite filled with the mixture and then corked. These flasks were placed in boihng water for an equal length of time (ten minutes each). They were then inverted over heated mercury, and air was introduced so as to displace one-third to one-fourth of the fluid. The flasks were afterwards corked under mercury and kept at a tempera- ture of 63° to 77° F. In two flasks the air thus introduced bad been previously heated, in the other two it had not been so treated. In four to six weeks the flasks which had received the unheated air burst, their contents having undergone alcoholic fermentation. The other two flasks remained unchanged for more than three months.

Schwann states that this latter experiment with heated air is generally, but not always, successful, and he explains this by the supposition that after the heating of the mercury, and in the processes of uncorking and corking, organic matter, which had not been previously heated, might very possibly mix with the mercury and enter the flasks. (This view has since been proved to be correct by Pasteur.)

It is but fair to refer here to the experiments on spontaneous generation published in 1836 by Franz Schulze. These will be described at a later period. They are, however, of interest here, because Schulze anticipated Schwann in the principle of admitting air previously acted on "in some way or other, in his case chemically, to Appert's preserves.

Schwann's experiments were repeated and confirmed by Ure in 1840 1 and by Helmholtz in 1843.^ The latter author, in order to test the oxygen view still further, prepared an infusion in the usual manner in a vessel into which platinum electrodes were fixed. After the infusion had remained unaltered for some

' Journal fiir pralttischc Chemic, xix. ^ Mailer's Archir. 1843.

LIEBICrS VIEWS. 9

time a current of electricity was sent through the liquid, decomposing the water into hydrogen and oxygen. But even this oxygen in its nascent, and therefore in its most active state, was unable to produce any fermentation in the fluid.

In the meantime Liebig had stepped forward as the oppo- nent of the views advanced by Caignard-Latour and by Schwann. He proposed a theory of a totally different nature.^ After pointing out that organic molecules have a tendency to alter their constitution, to break up and rearrange themselves, he approacVies the question of putrefaction and fermentation. With regard to the cause of these changes he writes as follows : ' Cette cause est la faculte que possede un corps en decomposi- tion ou en combinaison, c'est-a-dire, en action chimique, d'eveiller la meme action dans un autre corps qui se trouve en contact avec lui, ou de le rendre apte a subir I'alteration qu'il eprouve lui-meme.' He compares this sort of action to combustion, and cites several well-known instances of this kind, such as the de- composition of nitric acid by an alloy of platinum and silver, a change which does not take place with the platinum alone ; or the decomposition of peroxide of manganese by oxide of silver, &e., in water containing oxygen.

He includes under the term ' eremacausis,' the alterations which organic substances undergo at ordinary temperatures, and as the result of the action of oxygen. When oxygen is excluded, putrefaction occurs. Putrefaction is a combustion of one or more of the elements of the organic substances at the expense of their own oxygen. Where no foul smelling products result, the process is termed fermentation. Putrefac- tion occurs when the equilibrium of the attractions of a complex organic molecule is upset, and it results in a rearrangement of these elements. Non-nitrogenous organic substances do not imdergo this putrefaction spontaneously when they are pure. They must be brought in contact with some substance already undergoing change. This latter substance is therefore termed a ferment. This ferment is a nitrogenous substance under- going putrefaction and eremacausis, it converts the oxygen of the air into carbonic acid, &c. Its activity is destroyed by desiccation, by heat, alcohol, &c. It is the soluble portion of ' Annalex de Chimir ct de Physitpw, serie, Ixxi. 1831).

10 THE PARTICULATE THEORY OF FERMENTATION,

the ferment which is active, and this does not act by direct contact, but in consequence of a decomposition which it itself undergoes. The elements of the ferment take no part in the formation of the products which sugar furnishes when fer- mented, though at the same time the ferment is itself under- going destruction. (This latter statement is based on an ob- servation by Thenard, who found that 20 parts of fresh yeast, added to 100 parts of sugar left, after fermentation was com- plete, only '13*7 parts of an insoluble residue. This residue placed in a new portion of sugar became reduced to 10 parts. This last residue no longer exerted any action. Pasteur has since completely disproved the accru-acy of Thenard's results. On the contrary he iinds that yeast increases markedly during fermentation, and in his latest work Liebig admits this.)

The ferment is, therefore, according to Liebig, a body undergoing decomposition. If the ferment is too small in quantity for the sugar, when the decomposition of the former is complete the latter ceases to ferment (this statement has since been shown to be quite erroneous), and therefore a sufficient quantity must be present in order that its decomposition may not be completed till that of the sugar has ended. No special substance is, according to this view, required in order to act as a ferment, but merely one which shall be the constant exciter of action in the fermentescible substance. (This statement is also wrong, because putrefying fluids and tissues added to sugary solutions do not convert the sugar into alcohol. This was latterly admitted by Liebig, who was compelled to allow the existence of some relation between the yeast plant and the alcoholic fermentation, a connection which he, however, attributed to the effect propagated from the dead and dying, not from the living, cells.)

Liebig sums up as follows :

Organic compounds present two opposite and definite phenomena.

1. They give rise to bodies endowed with new properties, the elements of several molecules of a more simple compound uniting to form one molecule of a more com^ilex nature.

2. Some complex molecules of a high degree of complexity

LIEBIG'S VIEWS. 11

break up into one or more less complex molecules of a lower order, in consequence of the destruction of the equilibrium of the attractions of their elements. This equilibrium may be destroyed by heat, by contact with a body of different compo- sition, or by the action of a body which is itself undergoing change.

As an example of this Liebig takes the case of urine : ' In fresh urine,' he says, ' if oxygen be entirely excluded there occiu-s no alteration of the urea or of the hippuric acid con- tained in it, but if exposed to the air another substance present in the urine (probably the mucus) undergoes a change of form and composition (eremacausis), which is transferred or com- municated to the urea and the hippuric acid ; the urea is resolved into carbonic acid and ammonia; the hippuric acid disappears, and in its place is found benzoic acid,'

He continues : ' When we reflect that the power of exciting putrefaction belongs to bodies of the most different composition, that blood, flesh, cheese, saliva, infusion of malt, emulsion of almonds, &c., acquire this property as soon as, by the chemical action of oxygen, a disturbance in the equilibrium of the attraction of their elements has taken place, all doubt as to the true cause of these phenomena seems to disappear.' (We shall see later that in this Liebig is wrong, that meat, cheese, &c., cause putrefaction not from any inherent tendency to do so or from any state of decay, but because they introduce the necessary particles into the putrescible liquid.)

Liebig then goes on to say, with reference to the germ theory of putrefaction, that after the death of fungi and in- fusoria we observe the same putrefactive phenomena as after the death of a larger animal. These organisms, according to him, only appear at a late period of putrefaction, and therefore are not the cause of it, though no doubt by their vital actions they must hasten and modify the change.

And now let us pause in the history of this important sub- ject, aud methodise somewhat the views expressed. These may be divided into three sets. Firstly, we have that of Gay- Lussac, who attributes putrefactive and fermentative changes solely to the influence of oxygen in the flrst instance.

12 THE PARTICULATE THEORY OF FERMENTATION.

Then come the views of Caignard-Latour and Schwann, refeiTing these changes to the entrance into the fluids of solid particles from without, which may be destroyed by heat. These authors go further, and ascribe the whole fermentative process to the growth of the organisms which are found in the ferment- ing liquids.

And, lastly, we have the view of Liebig, who looks on oxy- gen as in so far favouring fermentation that it causes erema- causis, the molecules undergoing this change being now capable of setting up putrefactive and other fermentative changes. The latter changes are therefore due to the presence of some substance itself undergoing change, and to this substance the term ' ferment ' is applied. This ferment may be destroyed by heat.

It will be more convenient if for the present we class these views under two heads the oxygen theory (Gay-Lussac's) on the one hand, and the particulate theory (Schwann's) on the other. At a later period we shall determine whether Liebig's or Schwann's is the more tenable view.

I have already mentioned the researches of Schulze, Schwann, Ure, and Helmholtz as tending more or less to upset the views of Gay-Lussac.

The next research of importance on this subject is that by Schroeder and Dusch.' Their aim was to see \N]\eihex jiltraiion of the air would be sufficient to prevent the fermentation of boiled fluids. Their apparatus was the following :

A glass vessel containing the material to be tested (meat infvision, &c.,) was closed by a close-fitting cork, which was dipped into hot wax previous to its insertion. This cork had two holes in it wliich gave exit to two tubes bent outside to a right angle, these tubes being also firmly embedded in the cork ; one tube was for the purpose of con- ducting air to the vessel, and the other to suck air out of it.

The conducting tube was connected by means of a short piece of vulcanised caoutchouc with a glass tube ; the latter was again attached to a wider tube (1 inch in diameter and 20 inches long) by means of a similar cork to that in the bottle, and at the other end of this tube was a cork with a bit of tubing in it, called the open tube. The wide

' Annalen dcr Chcmic tind Pharmacic, 1854.

SCHROEDER AND DUSCH.

13

tube was loosely filled with cotton wool which had been pi-eviously heated for some time in a water bath.

The other tube the suction tube which in the interior of the flask reached almost to the level of the fluid, was connected by means of a vulcanised india-rubber tube with the upper tube of an ordinary gasometer, this latter tube being provi<led with a stop-cock. The gasometer was filled with water, and on opening the lower tube of this vessel the water flowed out and thus the gasometer acted as an aspirator. (See Fig. '1.)

Such was the apparatus employed. The fluid having been introduced into the flask, and all the connections having been

Fig. 2.— Scheoedee akd Dusch's appaeatus foe supplying filtered aie.

(Till; tulic to tlic left ought to rcacli almost to the level of the liquid.)

ascertained to be air-tight, the cock of the aspirator was shut and the substance to be tested was boiled, till all the tubes as far as the cotton wool had been thoroughly heated ; then, the joinings having been again examined, the aspirator was so arranged that water flowed out of it drop by dro}), and thus sucked air slowly through the flask.

Meat, boiled in water and ke2)t in a flask of this kind with constant change of air, was preserved for twenty-three days, and wlicji tested at the end of that time was found to lie quite un- altered, vvliile a similar infusion left exposed to ordinary air liad to be removed fioni the laboratory during the second week on

14 THE PARTICULATE THEORY OF FERMENTATION.

account of its intolerable stench. This experiment was repeated several times with similar results.

Schroeder and Dusch experimented in a similar manner with fresh sweet malt containing hops. After twenty-three days, the fluid being still unaltered, the cotton wool was removed, but the introduction of air now unfiltered was continued. The fluid was muddy and covered with fimgi, and had undergone fermentation in a week.

These observers were, however, unable to obtain like results with milk, or with meat heated without the addition of water. These substances invariably underwent putrefaction.

In a paper published five years later Schroeder returns to this subject.' Having found that white of egg mixed with water, if constantly shaken while boiling, could be preserved for an indefinite time, he tried whether ozone had any power in inducing fermentation. Dilute sulphuric acid was decomposed by electricity, and the ozone thus generated was conducted into a vessel containing pure white of egg. The latter was kept for thirty-eight days, and was at the end of that time unaltered.

Schroeder was still unable to succeed with milk or yolk of egg, although the latter, if previously heated in a closed vessel in an oil bath to 160° C. (310° F.) generally remained un- changed, and the milk sometimes also kept pm^e.

The special constituents of milk could be easily preserved. He tested casein prepared by precipitation with acetic acid and then washing with water. The whey also which remained after this precipitation could be preserved with ease. When this whey was boiled a deposit occurred, and this was readily kept pure ; and the whey which still remained did not ferment when preserved with the precautions mentioned.

Schroeder tried and succeeded with other materials, such as blood, urine, starch, &c.

The only substances which failed were milk, yolk of egg, meat heated without addition of water, and occasionally meat infusion.

As the result of these contradictory experiments he came to the conclusion that there were two ways in which fermenta- tion might be caused ; firstly, by some solid particle which ' Annalcii der Chcmic zoid PJiarviacie, cix. 1859.

SCHROEDER'S VIEWS. 15

can be arrested by cotton wool, and, secondly, by oxygen gas (in the case of milk, yolk of e^g., &c.).

Two years later there appeared another j)aper by Schroeder referring to those substances which he had previously failed to preserve, and in this research he has recoiu-se to the use of higher temperatures than formerly-'

Yolk of egg, after being heated for half an hour in a closed glass vessel, at a temperature of 130° C. (266° F.), was placed in a flask the neck of which was stuffed when hot with cotton wool, and was again boiled with a little water. This remained for seventy days unchanged.

He succeeded in a similar manner with meat and milk, and in the case of the latter he found that prolonged boiling at 100° C. was sufficient.

From these facts he gives up his formerly expressed view as to the spontaneous fermentation of organic substances under the influence of oxygen, and concludes that in these fluids spores were present which could resist a boiling temperature, the development of these spores being, according to him, the cause of the fermentation. He further considers that these spores were present originally in the milk, and were not intro- duced from the air, because he finds that milk which has not been Iwiled at all putrefies sooner than pure boiled milk exposed to the air.

It may be interesting to mention here that similar difficul- ties were experienced by Appert in his attempts to preserve milk. He succeeded by the following method : ' Condense the milk to two-thirds of its volume, strain it, then put it in the bottle, seal and boil in a water bath for two hours.' In order to prevent the cream from separating he found it well to add yolk of Qgg. This did not increase the difficulty in preserving it.

Still fmlher evidence disproving the gaseous theory is fur- nished by Pasteur.^ He repeated Schwann's exiDeriments and was successful with most fluids, but for a time he failed in the case of milk. He, however, succeeded when he boiled the milk under pressure at 110° C. (2.30° F.) for one or two minutes, heated air l)eing then allowed to come in contact with it ; and

' Aimalcti dvr Chemie nnd I'karmacie, cxvii. 1801.

- Annalcs dcg Sciences NaUircllcs, scrie iv. t. xvi. 18G1 : Zaolofjic

16 THE PARTICULATE THEORY OF FERMENTATION.

he also succeeded if he subjected the milk to prolonged boiling at 100° C. Such milk remains unaltered for an indefinite length of time, but it readily decomposes if unheated dust be introduced into it in the manner to be afterwards described.

The most striking of Pasteur's experiments is that of the flask with the bent neck. A flask containing, say, yeast water is heated so as to render its contents pure. Its neck is drawn out and bent, and then, after boiling, the lamp is simply with-

FiG. 3. Pasteur's flask with the bent neck.

(From Pasteur.)

drawn, the neck being neither heated, sealed, nor plugged (Fig. 3). Nevertheless the fluid does not undergo any change.

If, on the other hand, the neck of this flask be sealed during ebullition, a more or less perfect vacuum is thus pro- duced, and then, if the neck be broken after cooling, air rushes violently into the flask, carrying with it its dust. The result is that fermentative changes occur in the fluid. In the same way, if one of the flasks with open necks, the contents of which have remained for some time pure, has the neck broken off short, the fluid in its interior rapidly undergoes fermenta- tion ; or again, if the neck be not bent but be kept straight, so as to allow dust to fall in, fermentation rapidly occurs.

The explanation of these results is that in the case of the flask with the long neck the dust is caught in the curve, which in the first inrush of air is filled with water, which filters the air (Mr. Lister's view). Pasteur had supposed that part of the air dust entered the vessel instantly, but that the fluid and the walls of the flask were at that time so hot that any living particles present were immediately destroyed.

As will be seen further on. Pastern- also found that it was

TYNDALL. LISTER. 17

not necessary to filter the air of its dust, but that if the air were merely left undisturbed for some time till the dust settled, it might then be introduced into flasks without causing any development.

These experiments have been repeated by various observers with success, and Mr. Lister has at present in his possession a flask of this kind containing urine which is now thirteen years old, but which still remains unaltered and as limpid as on the day it was prepared.

In a lecture on Haze and Dust,^ Professor Tyndall showed that if no dust were present in a flask, a beam of condensed light passed through the vessel in a dark room would only be visible on each side of it, but would be invisible in its interior ; in other words, we see light only because there are particles in the air which render it visible. Were there no particles all would be darkness.

Such being the case, Tyndall found that when the air which was admitted to a flask had been previously heated, as in Schwann's experiment, the beam of light was not visible in the interior, showing that all or almost all the particles had been destroyed by heat, or, in other words, were in the main of an organic nature. By the same method Mr. Lister has found that in Pasteur's flasks with the long open necks, no floating dust is present after what was originally there has settled.

Another method of excluding dust was published in 1873 by Mr. Lister.^ It seemed probable that the occasional failures which occurred in the attempts to preserve boiled fluids arose from the fact that the steam did not destroy the septic energy of the dust in the necks of the flasks which had not been previously heated. Mr. Lister, therefore, in addition to the precautions as to boiling under cotton-wool caps, &c., subjected his flasks to a high temperature previous to the introduction of the fluid. This is done by keeping them, after the cotton cap has been applied, in an iron box, which is kept at a high temperature for two hours.

This box is of a square form, with one of its sides movable so as

' Nature, Jan. 27, 1870.

' Microseojncal Journal iox October 1873; see also Tratix. of Path. Society of London, vol. xxvii. 1878.

C

18 THE PARTICULATE THEORY OF FERMEXTATIOK

to form a door. ' This door has its circumferential part in tbe form of a groove capable of being packed with a considerable mass of cotton wool (Fig. 4, f). This door can be secured by means of nuts against the

edge of the box ; and the cotton wool, having the narrow rim of metal thus firmly pressed against it, serves as an effectual filter of the air that passes in during cooling. But then it is essen- tial that the heat be so equally distri- buted as to avoid heating any portion of the cotton to such a degree as to destroy its physical properties. This uniformity of heat is provided foi- by having three shelves of sheet iron inter- posed between the large Bunsen's burner and the bottom of the box, no as to prevent the heat from acting directly upon it, while at the

Fig. 4. Door of Lister's box.

Mr.

Fig. 5.— Mr. Lister's hot box.

same time the box is covered over with a cover of sheet iron (Fig. 5, k), which reaches nearly to the ground, and, while it checks radiation, compels the heated air to ti-avel over the whole exterior of the box

MR. LISTER'S EXPERIMENTS.

19

and escape by holes at the top of the cover, whence it is conducted into a chimney by a tube (l). By these two means combined, the shelves below and the cover round about, we get a uniform browning of the cotton. Into such a box the requisite number of vessels are introduced (Fig. 5). An aperture in the top of the box well packed with cotton wool transmits a thermometer (m), to show us when the temperature of 300° F. has been reached, and when this, or any other higher degree short of 350"- F., has been continued for two hours, the gas is turned off and cooling is allowed to take place ; and when the apparatus is quite cool, the covered glasses may be removed with confi- dence that they are perfectly free from living organisms.'

In this manner Mr. Lister purifies his flasks. The larger flasks have two necks, a large vertical one and a lateral one, which is a bent spout, large at its commencement and com- paratively narrow at its shorter terminal part beyond the bend (Fig. 6, o). The large size of the first part prevents it from acting as a siphon, and the result is that when the liqrdd is poured from such a flask and the vessel is afterwards restored to the erect position, the end of the nozzle remains filled with a drop of the liquid, and this guards the orifice so that regurgitation of air can never take place thiough the nozzle. This drop of fluid being sucked away by means of a carbolised rag, a pure cotton cap is tied over the orifice, and the flask is kept for future use. This flask, purified by heat and with each orifice covered with pure cotton caps, is used for the experiments (see Fig. 7). The fluid to be tested is introduced into it by means of a siphon, consisting of two glass tubes (s and T)connected by a tube of india-rubber (u), with a stop-cock (v) in the course of the india-rubber tubing. The siphon is first completely filled with water, the tenqjerature of which should be higher than that of the air, so that there is no dissolved air given off to form bubbles. Place one leg of the siphon in the vessel contain- ing the fluid to be used (w), then turn the tap and permit a sufficient amount of fluid to flow out to ensure that all the water has escaped from the siphon ; then turn off the stop-cock, wash the outside of

c 2

Fig. 6.— Mr. Lister's large double-necked flasks.

20 THE PARTICULATE THEOBY OF FERMENTATION.

the tube (t) with carbolic lotion, wrap a mass of carbolised rag (y) around its lower extremity, and apply this to the mouth of the flask (x) as soon as the cottou cap is removed, push the tube steadily down to the bottom of the flask through the carbolised rag, turn the stop-cock, and let the required amount of fluid flow into the flask (Fig. 7). When this has taken place the tap is again turned off", the

Fig. 7. Method op filling the flasks.

siphon is withdrawn through the antiseptic rag, and a fresh cap of carbolised cotton (the cotton is carbolised by being soaked in a solu- tion of one part of crystallised cai-bolic acid in one hundred parts of anhydrous ether and allowed to dry) is tied over the mouth of the flask when the rag is withdrawn. The fluid is now heated for the desired length of time, and then abandoned under the protection of the caps.

In this way Mr. Lister has found that he can preserve turnip infusion, hay infusion, urine, fresh milk, &c., for any length of time without any alteration taking place. To pre- serve milk, the flask containing it is immersed in boiling water for half an hour or more.

MR. LISTER'S EXPERIMENTS.

21

Fig. 8.

But this is not all, for these fluids can be transfen-ed to smaller vessels without undergoing any fermentation after this transfen-ence. This is done as follows : a liqueur glass (a) is covered by a glass cap (b) (watch glass), and the whole by a glass shade (c), the liqueur glass and the shade standing on a glass plate (see Fig. 8). This an-ange- ment is introduced into the hot box and thoroughly purified. Thus we have a pm-e glass filled with pure air, and the problem is to transfer the fluid from the flask to the glass without con- tamination in the process. To

do this, the cotton cap is removed from the nozzle of the flask (Fig. 7, z) and the end of this is instantly slipped into an opening in the centre of half an india-rubber ball (Fig. 9, r) previously steeped in a strong watery solution of carbolic acid. The outer glass shade is then removed, and the watch glass being lifted, the india-rubber cap is instantly applied in its place (see Fig. 9). The required quantity of fluid is then poured into the glass, and the cap and shade immediately reapplied. A fresh cotton cap is now tied over the nozzle of the flask. In this manner any number of glasses may be charged, and these are found to remain as piue and unaltered as the fluid in the original flask.

And now observe what such experi- ments teach. In the first place, into the original flask, when cooling, air enters, but this air having passed through a cotton-wool plug is incapable of causing putrefaction. Then in the

decanting of this liquid from the flask, fresh air must enter through the large mouth of the flask, but as this passes through a filter of cotton wool it is in like manner incapable of causing fermentation. Further the liqueur glasses are full of air, which lias either been previously heated, or which has been filtered

Fig. 9.

22 THE PARTICULATE THEORY OF FERMENTATION.

through tlie cotton wool around the door of the hot box. The fluid when poured from the flask into the glass mixes freely with this air, but no change is set up. And, lastly, the loosely- fitting glass cap and shade allow a free interchange of air, but are so placed as to make sure that the air dejDosits its dust outside the glass, thus corresponding in action to Pasteur's flasks with the bent necks. In spite of all these opportunities of admixture with the gases of the air, all sorts of fluids remain unaltered, while, on the other hand, the same liquids exposed freely to unfiltered air rapidly undergo fermentative changes.

These experiments are of themselves an absolute proof that the gases of the air alone are unable to cause fermentative changes in organic substances.

In 1874 Dr. Eoberts ' demonstrated again that fresh milk and other substances could be prevented from putrefying if kept in a flask with a cotton-wool plug after having been pre- viously boiled.

His method was as follows : An ordinary delivery pipette, having on it an oblong bulb capable of containing 30-50 cc, was sealed at one end, and the materials to be experimented on were then introduced into the bulb until it was two-thirds full (Fig. 10, a). The inside of the neck of the bulb was next wiped dry, and a plug of cotton wool was inserted about its middle. Lastly, the neck was drawn out above the plug and sealed in the flame (Fig. 10, b).

When the bulb Avas thus charged and sealed it was weighted with a leaden collar, and submerged in tbe upright position (so as to pre- vent the wetting of the cotton-wool plug) in a can full of water. The can was placed over a soiirce of heat and boiled for the re- quired time. The bulb was then withdrawn and, when quite cold, its neck was filed off above the cotton-wool plug (Fig. 10, c). Finally it was set aside in the upright position and maintained at a suitable temperatvire.

By exposure to the heat of boiling water for from twenty to forty minutes Koberts was able to preserve those substances with which Schroeder and other observers had foiled, viz., milk, pieces of meat, and egg albumin.

In 1876 experiments were published by Professor TyndalP

' PMlosojjhieal Ti'ansactiom, 1 874. " Philomphical Transactiotu, 187C.

DR. ROBERTS' EXPERIMENTS.

23

which afford still fmlher evidence on this subject. I have al- ready mentioned the method by which he demonstrated the presence or absence of particles in suspension by passing a powerful beam of light through the air to be examined. He found that ' in order to render air optically pure it was only necessary to leave it to itself for a sufBcient time in a closed chamber or in a suitably-closed vessel. The floating matter gradually attaches itself to the top and sides, or sinks to the bottom, leaving behind it air possessing no scattering power. Sent through such air the most concentrated beam fails to render its track visible.'

Fig. 10.— Dn. Roberts' btilbs (copied from Egberts).

His method as described by himself is as follows : ' A chamber or case was constructed with a glass front, its top, bottom, back and sides being of wood. At the back is a little door which opens and closes on hinges, while into the sides are in.serted two panes of glass facing each other. The walls of this case are smeared with glycerine in order to make the dust adhere. The top is perforated in the middle by a hole 2 inches in diameter, closed air-tight by a sheet of india-rubber. This sheet is pierced in the middle by a pin, and through the pinhole is passed the shank of a long pipette ending above in a small funnel. A circular tin collar 2 inches deep surrounds the pipette, the space between both being packed with cotton wool mois-

24 THE PARTICULATE THEORY OF FERMENTATION.

tenecl with glycerine. Thus the pipette, in moving up and down, is not only firmly clasped by the india-rubbei', but it also passes through a stuffing box of sticky cotton wool. The width of the aperture closed by the india-rubber secures the free lateral play of the lower end of the pipette. Into two other small apertures in the top of the cupboard are inserted, air-tight, the open ends of two narrow tubes intended to connect the interior space with the atmosphere. The tubes are bent several times up and down so as to intercept and

retain the particles cari'ied by such feeble currents as changes of temperature might cause to set in between the inner and the outer air (see Fig. 11).

' The bottom of the box is pierced with holes, in which are fixed, air-tight, twelve test tubes, intended to contain the liquid to be exposed to the action of the motel ess air.'

The case so prepared is closed and allowed to stand for three or four days, till it is found by the beam of light that all the dust has settled. Then, the pipette being dipped into the test tubes, the fluid to be experimented on is introduced into each in succession. They are then boiled for five minutes in a brine bath. During the cooling, plugs of cotton wool are introduced into the small external convoluted tubes, but these plugs are afterwards withdi'awn. The apparatus is then kept at a suitable temperature and at perfect rest. At the same time a part of the same infusion boiled for the same length of time is placed outside the box in free contact with the air.

In this way Tyndall has been able to preserve for an inde- finite time, boiled urine, mutton infusion, beef infusion, haddock infusion, turnip infusion, hay infusion, infusion of sole, liver infusion, infusion of hare, rabbit, pheasant, grouse, codfish, turbot, herring, mullet, fowl and kidney; while flasks contain- ing the same infusions, left exposed to the air after boiling for the same length of time, invariably putrefied in a few days.

Fig. n.— Prof. Tyndall's pure

CHAMBER (COPIED FROM TyNDALL)

TYNDALL. 25

This experiment, though resembling in many respects Pasteur's experiment with the flasks with long bent necks, differs from it materially. In Pasteur's ex]3eriment the whole of the interior of the vessel is acted on by the heat, and thus when the boiling is ended there is no part of the flask, except the neck, which contains any particles capable of causing fermentation. In this case, however, the steam from the tubes, passing into a larger chamber, is not able to destroy the vitality of the dust lining the walls of that chamber, and therefore the infusion is here not only in contact with ordinary air which has not been acted on by heat nor filtered of its dust, but the septic dust itself is present in the same vessel though not in actual contact with the fluids. Tyndall found that as soon as ordinary labora- tory air, laden with dust, was admitted, putrefaction commenced.

Tyndall has further shown that the gases arising from ymtrefying substances, however foul smelling, cannot produce decomposition in other fermentescible liquids, although this readily occurs when ordinary dust is admitted.

Thus, * on the 30th of November a quantity of animal refuse, embracing beef, fish, rabbit, have, was placed in two large test tubes, opening into a protecting chamber containing six tubes. On December 13th, when the refuse was in a state of noisome putrefaction, infusion of whiting, turnip, beef, and mutton were placed in the other four tubes ; they were then boiled and abandoned to the action of the foul sewer gases emitted by their two putrid companions. On December 25th these tubes were still unchanged. On the same day the end of the pipette was dipped into one of the putrid tubes and then inserted into the turnip, aiid on the 27th a similar speck was transferred to the whiting. These rapidly underwent decomposition, while the remaining two tubes remained unaltered.'

By operating in the manner described by Mr. Lister I have succeeded equally well in preserving fresh milk, meat, cucumber or turnip infusion for any length of time. As I shall have to refer at a later period to experiments in which extensive use is made of the ease with which these fluids can be preserved though retaining great readiness to undergo fermentation, I need not say more at present.

Not only is air which has been filtered incapable of caus- ing fermentation in a boiled liquid, but air which has been

26 THE FAIiTICULATE THEORY OF FERMENTATION.

acted on by carbolic acid is also without effect. I may mention a few facts made out by myself in support of this statement.

In the small room in which most of my experiments were done it was almost impossible for me to transfer fluids fi"om one flask to another, by Mr. Lister's method, without contamination and subsequent fermentation, but if I performed the same manipulations in a spray of about 1 to 30 carbolic acid and water I could transfer all sorts of fluids with ease from one flask to another without any risk, even though done in the most leisurely manner. In doing this I have used Mr. Lister's double-necked flasks without the jirotection of the india-rubber cap. I have also in a few instances simply poured the fluid from one single- necked flask to another, and when this was done in a carbolic acid spray without other precaution, the fluid remained pure.

That milk once rendered barren by boiling can be readily preserved for any lengtli of time, thougli i-etaining its capability for undergoing fermentation, is shown by the following experiment.

On January 30th milk was prepared by boiling for twenty minutes in a flask purified by boiling distilled water in it under a cotton cap, the flnsk being afterwards dried by heat.

On the same afternoon three purified tubes with glass caps and shades (just like Mr. Lister's liqueur glasses) were half filled with this milk under the spray.

February 6. The caps were removed under the spray, and a heated needle being introduced, jwrtions of the fluid were taken from each tube for microscopical examination. All the milks were found to present the normal appearance of fresh milk externally and micro- scopically.

February 1 1 . Examined as before. No change.

February 19. No change.

March 3. Still fluid and unchanged in appearance. Two of the tubes were now tested by the addition of a drop of fluid from a tube containing milk which had been left open, and which had putrefled. In three days the milk in these two flasks had separated into two layers, and had lost its normal characters.

April 11.- The milk in the third test tube still remains un- changed.

I might multiply instances to show that milk and other fermentescible fluids can be kept in this way for months at a

MY OWN EXPERIMENTS. 27

suitable temperature, without undergoing any change. This is not due to any effect of the carbolic acid on the milk, because milk so preserved rapidly undergoes fermentation when exposed to the air. Indeed the minute quantity of the solution which comes in contact with it can have no effect whatever, as is shown by the following experiment performed in 1877.

February 1. Five pure tes^t tubes were taken and into each was introduced 100 minims of boiled milk, along with a certain number of minims of watery solution of carbolic acid, 1-20.

To No. I. were added 2 mins., making a proportion of 1-1000. II. 5 1-400.

III. 10 1-200.

IV. 20 1-120.

V. .50 1-60.

They were then shaken up and left exposed to the air for twenty- four hours, and afterwards covered with very loosely- fitting caps, which were removed at intervals during the following day.

February 6. The milks wei'e beginning to alter in appearance and to separate into layers. This was the case even in No. V. April 19. They were all much advanced in decomposition.

Thus we see that decanting can be safely done in a spray of carbolic acid, the fluid still remaining as putrescible as ever ; while, on the other hand, experience had taught me- that in the particular room to which I have referred, it was very difficult to decant successfully without the spray.

The following experiment which I performed some time ago directly proves the efficacy of the spray :

Two flasks containing pure milk were opened in my room, and left open for ten minutes. In both bacteria developed. As soon as these flasks were removed two other flasks similarly charged were put in the same place in a fine cloud of carbolic spray. They were opened and left open for ten minutes. Both of these remained pure, though when inoculated at a later period organisms rapidly developed in them. When they were removed the spray was stojiped, and two fresh flasks were placed in the same position, opened and left open for ten minutes. One of the latter lemained pure ; in the other organisms appeared. (As will be later seen, the presence of organisms is synonymous with the presence of fermentation, and their absence with the absence of such changes.)

28 THE PARTICULATE THEORY OF FERMENTATION.

Another experiment proves to demonstration the efficacy of the spray in destroying the putrefactive agents in the air :

Four flasks provided with cotton caps were puiified according to Mr. Lister's method. Into two of these, pure encumber infusion was introduced in the manner ah-eady described. These two flasks were placed for four days in an incubator, kept at the temperature of 98° F. At the end of this time the fluid was unchanged in both. About half of the liquid in one of the flasks was then poured into one of the empty previously purified flasks, in a cloud of carbolic spray, and the caps reapplied. These were then placed in the incubator and they remained permanently unchanged, and without the development of organisms. The same process was gone through with the two flasks without the use of a spi^ay. In both of these organisms developed and putrefactive changes occurred.

In this experiment, when the fluid was poured from one vessel to the other it passed through the air, and air also entered into the first flask to take the place of the liquid. When this air had not been acted on by carbolic acid, organisms developed and fermentation took place, but where the air had previously passed through the spray it failed to cause any further change. (1 do not of course mean to imply that the former will be a constant result, for in ordinary air there are but few organisms present, and probably many flasks would escape. This experiment refers to the air of the room in which it was performed, that air being loaded with causes of fermentation.)

A very striking proof of the value of the carbolic acid spray which occm'red to me lately may be mentioned. The flasks which I at that time used were purified by heating them to a temperature of about 600° V. in a box like that described by Mr. Lister. The flasks were in the first instance heated without any covering, the cotton caps were then applied under the spray, and the flask with its cap reintroduced into the box, where it was thoroughly dried in order to drive off any carbolic acid which might be adhering to it. As the temperature to which the apparatus was in the first instance raised chars cotton wool, I used asbestos to filter the air as it passed into the interior of the box during cooling. For a while this answered quite well, but after a time portions of the asbestos became detached, and holes were thus formed through Avhich air could

(JONCL USIONS. 29

enter without being filtered, and as a result on several occasions I found that all the flasks so prepared were impure. This was obviated simply by directing the spray against the door of the box as soon as the lamp which heats it was extinguished. The box was thus surrounded by spray; the air passing into it first passed through this spray, and, as a result, since I did this, I never failed in any instance in obtaining pure flasks.^ From these researches we learn that the gases of the air, whether oxygen, nascent oxygen, ozone, nitrogen, carbonic acid, emanations from fermenting substances, &c., are powerless to cause fermentation in boiled fluids or tissues. Further, that it is sufficient, in order to prevent this occurrence, that the air be either previously heated, or filtered through cotton wool, or acted on by chemical substances, such as sulphuric acid or carbolic acid, or merely allowed to remain at rest so as to permit the dust to settle outside the substance tested. It is therefore evident that the causes of putrefaction in boiled substances are solid particles present in the atmosphere and on surrounding objects, which may be deprived of their fermentative properties in various ways. When we come to consider the further questions of spontaneous generation and the relation of organisms to fermentative changes, we shall find much additional evidence confirming this view.

' The exact merits of the carbolic spray as a means of purifying the atmo- sphere will be discussed later. What I wish to point out here is, that in ordinary air, in circumstances where we know that particles capable of causing fermentation are present, carbolic acid is able to render these particles inert.

30 THE PARTICULATE THEORY OF FERMENTATION.

CHAPTER II.

THE PARTICULATE THEORY OF FERMENTATION (continvrd). ON THE FERMENTATION OF UNBOILED SUBSTANCES.

Grape juice Gaji-Lnssac Van der Broech Pasteii/i' liohcrts; blood Van der Brocch Pasteur Burdoii-Sanderson Lister 3Iy awn results ; un- boiled ui-ine Vaih der Broecli, Pasteur Lister My own results Roberts Cazeneure and Livon ; milk Hojfpe-Seyler RoleHs Lister My own experiments; egg albumen Van der Broecli Gay on Roierts 3Ty own exjJenments ; vegetable tissues Roberts ; animal tissues Billroth Tiegel Bur don- Sanderson My own experiments Chiene and Ewart Meissner General review of the facts Behaviour of similar fluids and tissues in the living body Principles of aseptic surgery.

While it cannot be doubted that the causes of the fermenta- tion of boiled fluids and tissues are particles which reach them from the air and from surrounding objects, is this equally the case with the unboiled ? Experiments with these substances are apt to yield very contradictory results, for it is a matter of extreme difficulty to prevent their contamination after their removal from the living body. How this has been managed and with what results we must now enquire.

I. Orape Juice.

Gay-Lussac in the research mentioned before attempted to ascertain whether unboiled grape juice remained unaltered when oxygen gas was excluded. He took a bell jar and introduced into it small grapes, still intact. The jar was now reversed over mercury, and was filled five times with hydrogen gas in order to wash out all the oxygen. The grapes were then crushed by means of an instrument introduced through the mercury, and the juice thus obtained was kept at a temperature of 15° to 20° C. Fifteen days later, no fermentation having taken place, a

THE FERMENTATION OF UNBOILED SUBSTANCES. 31

small quantity of oxygen was introduced, and immediately fermentation commenced.

From these experiments he concludes that the oxygen introduced caused the fermentation. But here there are two main fallacies. In the first place, the skins of the grape were left mixed with the grape juice, no sufficient means being taken to destroy any solid particles adhering to them ; and then also the oxygen introduced might have carried in the necessary particles. There can indeed be no doubt, from Pasteur's sub- sequent investigations, that the Torula cerevisise the cause of the alcoholic fermentation was present on the skins of the grapes ; and Pasteur has further shown that oxygen is absolutely necessary for the development of the old cells of the Torula, though the young cells may go on developing without the presence of free oxygen. The explanation of Gay-Lussac's experiment is, therefore, that the old Torula cells present could not develop without oxygen, but that when a small quantity of oxygen was introduced, they developed, and fermentation occurred.

The next attempt to preserve grape juice of which I can find any record was made by Van der Broeck, and narrated to the ' Provincial Gresellschaft fiir Kunst und Wissenschaft,' Utrecht, January 1858. His method was the following' :

Small beakers were filled with mercury, and then heated in a sand bath till the boiling point of the mercury was almost reached. Fi-om time to time they were placed under the receiver of an air-pump, and at the same time shaken in order to detach any bubbles of gas adher- ing to the side of the flask. This process of heating and exhausting was continued till all the air was removed from the bottom or sides of the glass. These glasses were then inverted in a basin containing previously heated mercury, and were firmly fixed in this position. Ripe and uninjured gi'apes were now passed into the mercury and brought under the orifice of the flask, a portion of the skin of the gi-ape was clipped out by a heated knife, and by gentle pressure some of the juice was made to ascend m the vessel, the rest of the gi-ape being removed. When a sufiicient quantity of juice had been thus introduced the vessels were placed in a room of which the tempei'a- ture was 2.5° to 28° C, and giupe juice thus obtained could l)e kept for months or years without undergoing any change.

' See Annalcn der Chcinie unci Pharniacir, cxv. 18G0.

32 THE PARTICULATE THEORY OF FERMENTATION.

In this experiment not only was all air excluded, but the dust adhering to the walls of the vessel and in the mercury was subjected to strong heat, and its fermentative power destroyed. The juice of the grape, in ascending through the mercury, did not come in contact with unheated dust, nor did it touch the skin of the grape.

Into some of the flasks containing pure grape juice obtained in this way, pure and fresh oxygen was introduced from a retort containing chlorate of potash and oxide of copper. (The nozzle of the flask was heated previously to its immersion in the mercury, and the oxygen was allowed to stream out for a time sufficient to wash out all the dust.) In none of these flasks was there a trace of fermentation. Into others, atmo- spheric air, passed through a mass of cotton wool, was intro- duced in the same manner, but without producing any effect.

Into these vessels containing oxygen, yeast was introduced in minute quantity, and fermentation at once commenced. Into others containing only grape juice, young cells which had never been exposed to free oxygen were introduced by a method which is fully described in his research, and these also caused fermentation ; thus proving that oxygen is not necessary even for the commencement of the change, if only the yeast cells be young (three or four days old).

By these experiments it was absolutely demonstrated 1 That oxygen is not the cause of the fermentation of unboiled gra})e juice ; and 2. That the juice itself contains no ferment.

That grape juice contains no ferment was further shown by Pasteur,' who introduced unboiled juice into his flasks with bent necks, containing pure boiled juice. No fermentation occurred, though, as he says, if a single Torula cell had been added, the whole mass would have fermented.

Dr. Roberts - likewise succeeded with grape juice.

Test tubes were drawn out at their lower ends to capillary points and sealed in the flame; the upper ends were plugged with cotton wool ; they were then passed and repassed through the flame of a spirit lamp until they were quite hot, as shown by the commencing charring of the cotton. (Fig. 12.)

' Eleven sterilised tubes, six empty and Ave containing water, were

' Etudes sur la BVcre. ^ PhM. Transactions, 1874:.

PRESERVATION OF GRAPE JUICE AND BLOOI). 33

grape urface

charged with grape juice in the following manner : A fresh

was firmly seized with the fiiiger and thumb, and a spot on its s

was pi-essed for a few seconds against the flame

of a spirit lamp so as to destroy any adhering

germs. The point of the sterilised tube, also

heated in the flame and quickly snipped off" by an

assistant, was then thrust into the grape at the

heated spot. Compression was now made on the

gi-ape until a sufiicient quantity of the turbid

juice was forced into the tube. The tube was

then withdi-awn, and its point sealed in the

flame. The eleven tubes thus charged remained

permanently unchanged, and when examined, at

various periods from five to eight weeks, the taste

and reaction of their contents were undistin-

guishable from that of the fresh grape juice.'

II.— Blood.

Blood is one of the substances which eobeets).

have been frequently referred to as having an inherent tendency to decompose, but several experiments have now demonstrated that this is not the case.

The first observer who succeeded in preserving blood was Van der Broeck.

Van der Broeck procteded as follows: Having prepared his beakers filled with mercury as formerly described, he introduced one end of a previously heated copper tube into the carotid artery of a dog. To the other end of this a caoutchouc tvibe was connected, while the free end of the lattei- dipped into the mercury and the blood passed along it into the purified beakers. (This caoutchouc tube had been purified by the jjassage of steam through it for some time, and by placing a plug of cotton wool in each end while it was cooling.) The vessels were then kept at a temperature of 25° to 30'^ C. for weeks without the contained blood undergoing any change.

Into some of these flasks oxygen or filtered air was intro- duced, but still there was no putrefaction. The minutest por- tion of putrescent or even non-put re scent but unheated substance at once set up fermentation.

In 1863, Pasteur ' stated that he had obtained blood from

' Comptcs llcnduv, Ivi. 738. ])

34 THE PARTICULATE THEORY OF FERMENTATION.

healthy iinimals by means preventing contamination with un- heated atmospheric dust, and that this blood had remained free from change. In a later publication ^ he describes the method pursued.

' For this I made use of a flask connected by means of a caoutchouc tube with a brass tube and stop-cock. The two parts of the tube are about twelve centimetres in leugth ; that which is free is filed down like the extremity of a cauula. In order to cleanse this vessel from all living dust the free extremity of the brass tube was connected 'with a platinum tube .strongly heated, a small

Fig. 13 (FROM Pasteur).

quantity of water having been previously introduced into the flask. This water is then boiled, and the flask allowed to cool, the air which enters during cooling being previously heated. It is well to boil the water in the flask under pressure, to effect which the free extremity of the platinum tube is connected with a glass tube bent at right angles, which dips into a deep vessel filled with mercury. After boiling for some time under pressure, this tube is detached, and boiling is continued at the ordinary pi-essure ; then the flask is allowed to cool and to become filled with heated air. When the flask is cold the cock is shut and the platinum tube detached. Till it is required it is well to hold the orifice of the brass tube down, in order to prevent dust from falling into it. Before being used this portion is heated carefully in the flame of a spiiit lamp.

' A vein or artery of a dog is now opened, the end of the brass tube introduced, and secured in the blood-vessel by a ligature ; the cock is then turned on. Blood flows into the flask, and when enough has been ol>tained the cock is shut and the flask placed in a suitaljle tempei'a-- ture.'

As a result this blood does not putrefy, and its odour re- mains quite fresh. There is not even an active absorption of

' Etudes xvr la JJihr, 187G.

BLOOD: BURDON-S ANDERSON, ROBERTS, LISTER. 36

oxygen, for after several weeks only 2 or 3 per cent, of that gas was found to have disappeared in a vessel sealed imme- diately after the blood had been introduced.

Dr. Burdon-Sanderson also found that blood taken from rabbits with suitable precautions, and put into purified flasks covered with cotton wool, remained free from change.

Dr. Eoberts,^ having purified his tubes in the way described, and having thoroughly cleansed his finger, punctured it, and sucked up about two drops into each tube. Of ten tubes pre- pared in this way, six remained unaltered. This experiment is of little value, partly on account of the imperfect method of experimentation, and partly on account of the small amount of blood obtained.

Mr. Lister ^ took blood from the jugular vein of an ox in the following manner :

A large glass tube was fixed in the lai'ge oiifice of one of his double-necked flasks, the interval between the flask and the tube being filled with tightly-packed cottou wool. Over the outer end of this glass tube a cotton cap was applied, and there was a cotton cap as usual over the orifice of the spout. The fiask thus arranged was heated in the hot box. The jugidar vein of an ox having been exposed antiseptically, was divided, the cotton cap removed fi'om the end of the tube, and the end of the vein slipped over the orifice of the tube. Blood thus flowed through a pure tube into a pure flask. When enough had been obtained the vein was removed and a pure cotton cap immediately aj^plied in its stead. Before coagulation had occurred, various liqueur glasses, arranged as formerly described, wei'e charged from the large flask.

Blood so obtained remained unaltered in the liqueur glasses and in the flask, though kejit for six weeks.

Mr. Lister also found that not only blood, but blood and water a much more putrescible mixture remained unaltered. (The water was introduced into a large pure flask, and boiled so as to purify it. A portion of blood clot from one of the liqueur glasses was then spooned into the flask, careful precautions being taken against the entrance of living dust.)

In some experiments, performed in a manner to be shortly

' Quarterly Journal of Micraisropiful Sriciicr, xi. J871.

- Loc. cit, '■' Mirriixropical Jour mil, 1878.

1) 2

36 THE I'ARTICULATE THEORY OF FERMENTATION.

described, I have found that blood, removed from the healthy living body and placed in calcined flasks or in flasks containing infusion of cucumber, maybe preserved for an indefinite length of time without alteration.

Hence blood has no inherent tendency to undergo fermen- tative changes, nor can oxygen alone induce such alterations.

III. Urine.

Healthy mine was first preserved without alteration by Van der Broeck. The flasks in which it was received were prepared in the manner before described. An animal (dog or sheep) was killed, the abdomen was immediately cut open, and the ureters and m-ethra having been rapidly tied, the bladder was removed and immersed in the mercury. A heated needle was then introduced, and the bladder was torn, the urine then ascending into the glass. This urine remained pure even after the addition of oxygen or filtered air.

In the same paper in which Pastern- mentions that he has succeeded in preserving blood he states that he has also obtained pure urine. The method is described in his ' Etudes sui* la Biere.' The flask with its nozzle and stop-cock are prepared as in the case of the blood ; then the free extremity of the brass tube is introduced into the urethra. Urine being passed, the stop-cock is turned, and the urine flows into the flask. Urine thus obtained undergoes no fermentation. ' Elle depose des cristaux en petite quantite, mais sans se troubler ni se putrefier d'aucune facon.'

In 1871 Mr. Lister succeeded in obtaining and preserving unboiled urine.' The method he employs is to wash the meatus urinarius and the glans penis with 1-40 carbolic lotion. A prepared flask is then taken, the cotton cap is removed, the glans immediately applied over the orifice, and urine passed into the flask. A fresh cotton cap is then applied. This urine may, like other fluids, be decanted into liqueur glasses. This experiment was apparently constantly successful, no alter- ation occurring in the urine in the flasks or in the glasses.

' Transactions nj the Itvijal Society of Edinhuryh, 1875.

URINE: ROBERTS, CAZENEUVE AM> LI FOX. 37

I may here state that I have often repeated this experiment with the view of obtaining pm-e nnboiled urine for other experi- ments, and always with success. I have, however, used the spray, and have thus avoided the necessity of applying the glans penis to the orifice of the flask. The glans having been purified, urine is simply passed in a spray of carbolic acid into a pure flask. This urine passed through the air, but that air, having been acted on by carbolic acid, was inert.

Dr. Roberts has also obtained similar results by passing urine into a pure test-tube, and afterwards charging tubes of the form previously described, by breaking oft the capillary end below, and letting the urine flow up. Of eight tubes so obtained, the urine remained unaltered in seven, while in one it putrefied.

Cazeneuve and Livon ^ succeeded in preserving urine in the urinary bladder without the occurrence of any alteration in it.

A ligature was placed around the prepuce of a dog for five hours, in order to have a considerable amount of urine in the bladder. An incision being made into the abdominal cavity at the end of that time, the ureters and the urethra were ligatured, and the bladder was cut out. The bladder was then suspended in the air at a temperatm-e of about 25° C. The wall of the bladder soon dries, and though liquid slowly transudes, that liquid evaporates immediately, and thus the bladder wall cannot putrefy. Urine may be kept thus for several days without undergoing any change, although if the bladder be opened it becomes ammoniacal in twenty-four hours. I shall return to these experiments at a later period.

Thus healthy unboiled urine has no inherent tendency to putrefy, but follows the same law in this respect as boiled urine.

IV.— Milk.

In 1859 Hoppe-Seyler attempted to preserve milk pure in the following manner: ^

A small funnel was carefully fastened over the teat of a goat. To the lower end cf this was fastened a piece of caoutchouc tubing, the

' Rcrue Menmclle, 1877, p. 733. ^ Vircliow's Archiv. xvii. (1859).

38 THE PARTICULATE THEORY OF FERMENTATION.

other end of which was attached to a glass tube below. This glass tube passed down to the bottom of a glass test tube, the u])per vim of which was provided with a piece of caoutchouc tubing open above. None of the tubes were heated nor in any way purified. The milk was now withdrawn in a continuous stream, so as to flow for a long time over the edge of the caoutchouc tube till it was quite free from bubbles of air. The test tiibe was then lowered, and then, while the milk was still flowing, the caoutchouc tube was firmly tied around a thick glass rod.

Milk obtained in this manner, and kept at the ordinary temperature, coagvdated in three days. Hoppe-Seyler therefore concluded that milk when shed contains a ferment.

This experiment proves that oxygen is not necessary for the occurrence of fermentation in milk ; in other words, it is not the cause of such changes, and therefore, as the tubes were not purified, the cause must either be in the milk itself or be some- thing adhering to the tubes. As I have just stated, Hoppe- Seyler concluded that the cause was inherent in the milk.

Which of these is the true agent is decided by the following experiments performed by Dr. Eoberts : ^

* A glass tube was drawn out at each end to a narrow orifice. The lesser portion of this was tightly wrapped round with cotton wool and inserted as a plug into a large test tube containing water to the depth of one inch. A cap of cotton wool was also tied over the narrow orifice. The water in the test tube was then briskly boiled, and the boiling was continued almost to diyness. When the apparatus was cold I took it into the cowhouse, and seizing a teat, I pulled ofi" qvuckly the cotton- wool cap and pushed the narrow point into the duct of the teat. Holding it firmly in this position I milked into the test tube until sufiicient milk had been obtained. I then drew away the test tube from the little tulie, pressing in the cotton wool around it as I did so, until the latter was entirely withdrawn from the test tube.

' From the test tube I charged ten empty pure tubes ' (in the manner descril)ed under urine), 'and resealed their capillary orifices : of these ten tubes three remained unchanged, the milk remaining perfectly normal as regards taste, reaction, kc. The other tubes curdled or putrefied in ten days.'

' Loc. cit.

MILK: LISTER, MY OWN EXPERIMENTS. 39

The method described here is imperfect, but the fact that three tubes remained unaltered absolutely demonstrates that the cause of the fermentation is nothing inherent in the milk itself, but something which it acquires after it leaves the body that something being particulate, not gaseous.

Mr. Lister ' describes several series of experiments performed with the same aim. In one of these he succeeded in preserving the milk unaltered.

A numbei' of little tubes were covered with glass caps and shades, and purified in the usual manner. After a rainy day he washed the udder of a cow and the hands of the milkman with water. A wide glass tube connected with an elastic tube was then placed under the nipple (the glass tube had been heated and the elastic tube boiled). This -was filled with milk, and then each little tube in suc- cession had a small quantity mtroduced by relaxing the elastic tube.

Of twenty-four tubes so prepared and charged two remained permanently pure. The results in the other tubes equally demon- strated that the cause of the fermentation of milk is not inherent in the milk, for the milk in each underwent a different change. These experiments will be more fully considered at a later period.

While in the Shetland Islands in the summer of 1880 I performed a series of experiments, which consisted in obtaining the milk under the protection of a spray of carbolic acid. A number of flasks with cotton caps and long necks were heated before leaving London. The udder of the cow and the hands of the milkmaid being washed with carbolic lotion (1-20), the flasks were uncorked and filled with milk under the spray. In doing so the mouth of the flask was held as close as possible to the teat. The cow was restive and would not allow me to do the milking, and therefore the experiment was performed by the milkmaid. When the restiveness of the cow, the inex- perience of the milkmaid at antiseptic work, and the dark and draughty cowhouse are taken into account, it will not be sur- l)rising that the milk in a considerable number of the flasks f(;rmented; but nevertheless evidence was got, of tlio same kind as that obtained by Dr. Roberts and Mr. Lister, sufficient

' Micrusccjncal Jourmil, 1878.

40 THE PARriCULATE THEORY OF FERMENTATION.

to disprove the existence of a ferment in the milk when with- drawn from the body.

In order to transfer these flasks to London I had intended to draw ont and seal their necks, but I found this impossible, and therefore I soaked pieces of cork in carbolic lotion, inserted them into the mouth of the flask, and covered them with tar a very inefficient method. During the voyage the milk was much shaken, and some of the corks proved inefficient, as shown by the leakage of the milk.

The following are the experiments, with their results :

First Experiment.

August 5, 1880. The udder and teats of the cow and the hands of the milkmaid having been Avashed with 1-20 carbolic lotion, and a small spray being directed as well as possible over the part, eight purified long-necked flasks were filled with milk, the milk being drawn directly into each flask, which were held as near the teats as possible. Eash flask was re-covered with its cotton cap, and they were then placed in the upright position in a warm room.

Augtist 8. The milk in these flasks seems unaltered. There is a little cream on the top in each.

August 10. Ditto.

August 24. Four of the flasks have undergone change, the change varying in nature in each flask. The other four are perfectly fluid and present the appearance of pure milk.

To-day the corks were inserted.

Se2:)temher 21 (twenty-three days after the transport to London). Only two flasks now remain pure, the other six having undergone alterations of various kinds.

October 27. Examined. The milk in two flasks is perfectly normal.

The result of the first experiment was, that after nineteen days four of the milks had undergone alterations of various kinds, while four remained apparently pure. On October 27 i.e. after two months and twenty-two days two milks were still perfectly right, in spite of a sea voyage and great disturbance.

MILK: MY OWN EXPERIMENTS. 41

Second Experiment.

(«) August 10. Two flask?^ were filled after washing the udder of the cow and the milkmaid's hands with carbolic acid (1-20). No spray used.

August 24. The milk in one of these flasks has undergone altera- tions \ the milk in the other Ls perfectly pure.

September 21. Both milks have coagulated and are undergoing changes.

(b) August 10. After the spray employed in experiment (c) had been stopped, two flasks were filled without it.

Augiist 24. I am doubtful whether these are pure or not ; I think they are not.

September 21. Changes have occurred in both.

(c) August 10. Seven flasks were filled under the spray as usual. August 24. Three of these milks have altered ; four are still

apparently pure.

September 21. Three still remain apparently pure : four have undergone change.

October 27. Examined. Three still pure.

On December 24 I opened one of these flasks, and found a slightly suety smell but a perfectly sweet taste, and the milk presented the appearance of normal milk. I examined it microscopically no organisms. I have stained some specimens of this milk (Plate V. Fig. 33), and it will be seen that no organisms whatever are present, and this in unboiled milk kept for moi'e than five months.

The result here is that three out of seven of the flasks filled under the sjjray have remained permanently pure, while all of those filled without the spray have ultimately undergone fermentative changes.

Third Experiment.

(a) August 1 6. One flask filled without spray and without previous application of carbolic acid to the hands or teats.

Aiigust 24. This milk has coagulated.

{b) Aiigust 16. One flask filled without the spraj' and without washing the teats with carbolic acid. The hands of the milkmaid, were, however, purified.

August 24. This milk has undergone fermentation, having separated into two layere the upper clear, the lower thick but not coagulated.

42 THE PARTICULATE THEORY OF FERMENTATION.

(c) August 16. Two flasks were filled without the spray, but after washing both the teats and the hands with carbolic lotion.

AiKjust 24. One of these is doubtful, the other apparently iin- altered.

Septeiniber 21. Fermentative changes are occurring in both.

{d) August 16. Six flasks filled under the spray as usual.

Aug^ist 24. All these are appai-ently unchanged.

September 21. Four have undergone some fermentative changes. One is doubtful. One is still pure. Thi-ee of the corks have not fitted perfectly.

October 27. Examined. One still pure.

The whole result is, that of twenty-one flasks filled under the spray, six remained permanently unaltered, and that after having been exposed in a manner which sufficiently explained the occurrence of femientation in some of the others.

Up till August 24th no less than fourteen of these milks had remained apparently unchanged, while similar specimens taken without any precautions had undergone alteration,

I have still in my possession (June 1881) four of these six flasks, and the milk in these still remains perfectly pure and free from fermentative changes.

From all the facts narrated I think it is absolutely certain that milk has no inherent tendency to undergo fermentation of any kind, and that the cause of the fermentation is not the gases of the air, but solid particles which the milk meets with after it is drawn from the cow.

V. Egg Albttmen.

The difficulty experienced by Schroeder in preserving boiled white and yolk of eggs will be remembered.

Van der Broeck introduced an egg into the merciuy ar- ranged as formerly described, broke the shell with a heated iron rod, stirred up the contents with a similar rod, and then allowed them to ascend into the glass. This egg albumen remained pure, even after subsequent addition of oxygen or of filtered air.

Gay on ' found that some eggs may be preserved unaltered, while others undergo change. He supposes that in the latter

' C'onijjtvg Itendiix, Ixxvi. Ixxvii.

EGG ALBUMEN: ROBERTS. 43

case the causes of putrefaction entered as the egg passed through the oviduct. Such an idea is, however, hardly tenable.

Eoberts has shown by experiments similar to those pre- viously described that egg albumen has no inherent tendency to undergo fermentation.

He proceeded in the following manner : Eight sterilised tubes were prepared containing pure water. ' A fresh egg was fixed in a convenient support, and a small piece of the shell was chipped off, care being taken to leave the subjacent membrane uninjured ; then a sterilised bulb was taken, and the capillary portion immersed for a few seconds in boiling water, in order to destroy any adherent septic particles. The sealed end was then rapidly snipped off and the capillaiy portion plunged into the interior of the egg. About 2 gm. of the albumen were then sucked up by the mouth into the bulb. When this was accomplished the bulb was quickly withdrawn and its capil- lary end sealed in the flame.'

Six of these eight tubes remained unaltered for seven months.

Of a second series of seven tubes similarly charged and kept for two months, five remained unaltered. That is, of fifteen tubes filled, eleven remained pure.

I may refer to an experiment which I did for another purpose, accepting as true the view that egg albumen had no inherent tendency to undergo fermentation, aud which proves the truth of that view.

On July 7th, 1880, 1 took four purified beakers and four fresh eggs. These eggs were washed with carbolic lotion (1-20), and were then Ijroken, one into each lieaker, under the spray.

One of these beakers was covered with its cotton cap, and placed in an incubator kept at the temperature of 98° F.

On July 20th no change whatever had occurred. The other flasks were used at once for various experiments. Into one a special form of organism was introduced, and here only this one form of organism developed, with the production only of a special kind of fermentation.

Hence egg albumen has no inherent tendency to undergo fermentative changes.

44 THE PAliriCULATE THEORY OF FERMENTATION.

VI. Vegetable Tissues.

Dr. Eobei'ts' has also experimented on the solid tissues of the turnip, potato, orange, and tomato, with similar success.

The following is his method for turnip :

' A stei-ilised tube containing- water was nickecl with a file near the base of the capillary part, where the tube had a diameter of about two millimetres, A fresh oblong turnip was then fractui-ed aci-oss, and the tube, snipped off at the nicked jjoint, was quickly thrust into the substance of the turnip. A naiTow cylind-er of turnip about an inch long w'as thus foi-ced into the column of water in the tube. The tube was then detached, and its end sealed with melted sealing-wax.' Of

14 tubes thus chai-ged with turnip 10 were successful;

7 potatoes 4

8 orange 8 3 ,, ,, tomato 3 ,,

Ferments which induce changes after death are therefore not present in living vegetable tissues.

VII. Animal Tissues.

Some years ago experiments were made by Billroth ' and Tiegel^with the view of ascertaining whether the living tissues did or did not contain the causes of putrefaction. Having killed an animal, they opened its body rapidly, and removed with heated implements various portions of tissue such as liver, spleen, kidney, &c., and immediately dropped this into heated paraffin. They supposed that by this means any dust which fell on the tissue in its transit from the body to the flask would be destroyed by the hot paraffin, while this heat would not penetrate into and act on the interior of the tissue. At the same time the organs would be protected from air or dust by the paraffin.

They found that many portions of the body preserved in this way, notably the liver and spleen, underwent putrefaction rapidly, and they therefore concluded that the causes of this putrefaction were present in the living blood and tissues.

' CuceohacteHa sejHica. * Virchow's ArcJiir. Ix.

ANIMAL TISSUES: MY OWN EXPERIMENTS, 45

These experiments were repeated by Dr. Burdon-Sauderson, who obtained similar results and adopted the same views.

If, however, we look at the method, we shall find several objections to it. Thus, heated paraffin must be looked on as dry heat ; it does not moisten solid particles in contact with it. Now it has been shown that dust, if kept dry, may be heated even to 300° F. without losing its power of causing fermenta- tion. Further, paraffin solidifies at about 136° F., or even lower, and therefore paraffin, merely at its melting point, is not likely to be hot enough to destroy all septic particles. Further, during the cooling of the paraffin heavy particles of dust may fall into it and sink on to the tissue. Then, also, on the sides and bottom of the vessel is coarser dust, which likewise may not be destroyed.

But, again, paraffin is very apt to crack, and after cooling small cracks may occur which admit moistm-e and dust. To obviate this risk the paraffin has been covered with oil ; but even here the oil becomes laden with dust and passes down through the cracks.

And, lastly, the knife, before dividing the tissue, compresses the vessels and forces the blood out of them, and thus, when these vessels are cut, air is sucked in, and this air carries its dust with it quite out of reach of the heat of the paraffin.

In December 1877 I commenced a series of experiments on this subject, and these have been continued at intervals since that time.

The first experiment was an imitation of those of Billroth and Tiegel (only it was performed antiseptically), and yielded conflicting results. Thus the liver and kidney putrefied, while the spleen, muscle, and mesentery remained unaltered.

This being the case, I determined to abandon this method entirely, and to see if some definite conclusion might not be arrived at in some other way. The following is a description of the method I have employed :

A number of beakers, each provided with a cotton cap, were puri- fied by heat, somewhat after Mr. Lister's method, and into each vessel about one-fourth of its volume of pure turnip iut'usioii was introduced from one of the double-necked Masks (Fig 6, p. 1*J). This was done under the spray, and the cotton caps were then reapplied. These beakeis

40 THE rARTICULATE THEORY OF FERMENTATION.

were placed in an incubator, and kept at a temperature of 98° F. for three or four days. At the end of that time the turnip infusion was clear and unaltered, and the flasks were therefore considered ready for use.

On January 6tli, 1878, four beakers having been thus jirepared, and six beakers containing melted pai-affin being also at hand, a healthy rabbit was iised for the following experiment.

The skin and hair of its abdomen having been thoroughly washed with 1-20 carbolic lotion, the animal was killed by a blow on the back of its neck, and the tibdominal cavity was rapidly opened, under a fine spray of carbolic acid, with purified and heated instruments. Portions

of its organs and tissues were rapidly cut out and intro- duced into the beakers, which were opened in the spray.

Into the four vessels containing the pure turnip infusion portions of liver, spleen, kidney, and muscle respectively were intro- duced, and the caps having been reapplied while the flasks were still in the spray, they were then placed in an incubator (see Fig. 14).

Into the six flasks con- taining melted pai-affin por- tions of liver, kidney, spleen, muscle, mesentery, and vena cava, with its blood, were dropped also undei- the spray. The parafl[in was left to solidify, and the vessels were then placed in the incubator.

All those portions of organs introduced into the turnip infusion remained ])ermanently puie and free from })utrefaction.'

Of the paraffin beakers, two (muscle and vena cava) remained without change ; while the other four (liver, spleen, kidney, and mesentery) putrefied.

In this experiment we have in the first case a series of

' On December 24, 1880, I killed a rabbit and preserved its organs in the way described here. Fig. :-54, Plate A^, is drawn from a specimen taken from the beaker containing the spleen, and stained. It will be seen that no organ- isms whatever arc present.

ANIMAL TISSUES: MY OWN EXPERIMENTS. 47

beakers heated so as to destroy the activity of the dust adhering to them, and that this was effectually done was proved by the fact that the turnip infusion introduced into them underwent no change, although, as has been amply shown in the fore- going experiments, had ordinary unheated dust been jjresent, this infusion would have undergone fermentation.

Further, the portions of the tissue are transferred from the body to the beaker without the possibility of acquiring living dust, for, as we have seen before, a spray of carbolic acid in an ordinary atmosphere is able to destroy the fermenting power of the dust. Such being the case, if the tissue, taken with all pre- cautions undergo putrefaction, it is possible that the causes of this fermentation were present in it while in the living body the degi'ee of probability depending of course in great measure on the known skill of the experimenter. But if no change occm-s, it is proof positive that there were no causes of change present in the body. In other words, as these unboiled tissues remained unaltered, it is quite certain that they have no inhei'ent tendency to undergo fermentation even when freely exposed to air.

I used the turnip infusion partly because I wished to know whether the beakers had been thoroughly purified, and partly in order to keep the tissues moist, for I had found in a former experiment that they dried too rapidly in the open-mouthed vessel if no fluid were present. Since that time I have used cucumber fluid, as being more putrescible.

Further, by the use of tliese infusions the conditions favoui- ing fermentation are greater, for we have here a boiled highly putrescible infusion of turnip, and an unboiled, if possible still more putrescible, infusion of meat, as well as the meat itself. It wei'e hardly possible to provide more favourable conditions for fermentation. Nevertheless no change occurred.

I may here point out the light thrown by these experiments on the cause of the want of success in the paraffln experiments. In the first attempt which I made with tlie paraffln any of the sup])osed causes of failure might have l)een in 0])erati()n, but in the experiment just narrat(;d the entrance of aii- laden will) septic dust into the blood-vessels is excluded because the opera- tion was done in a spray of carbolic acid. Therefore the failure in

48 THE rARTICULATE THEORY OF FERMENTATION.

the four vessels must have been due to dust in the paraffin, or to cracking of this after solidification.

But, it may be said, the absence of putrefaction in the beakers was due to the action of the carbolic acid on the tissue. This, however, is not the case, for the following reasons :

In a preliminary experiment I touched the outside of the flask (which was of course covered with impure dust) with one of the portions of the tissue, and afterwards introduced this piece into the flask, and in it putrefaction occurred rapidly. Again, the fact that four paraffin flasks went wrong (the organs being there also subjected to the action of the spray) shows that this had no influence. Again, when the gall-bladder is wounded fermentation often occurs. This latter fact is illus- trated by the following experiment :

A medium-sized rabbit was killed by a blow on the nape of the neck. The abdomen bad been washed beforeliand with 1-20 carbolic acid lotion, and was now rapidly opened under the spray. Into seven beakers containing pure cucumber infusion, two pieces of liver, one piece of kidney, one piece of spleen, one of muscle, and one of mesentery were introduced. In cutting out the liver the gall-bladder was injured.

Four weeks later, five beakers were unaltered, the two which had fermented being those containing the pieces of liver, which indeed had undergone fermentation within twenty-four hours.

I have since met with sevei-al similar instances.

Further, if putrid matter be injected into the jugular vein of the animal a few minutes before death, all the tissues re- moved and preserved in the manner described undergo putre- faction.

I have repeated these experiments many times with like results,' and I therefore conclude that the tissues of the healthy

' On two occasions I have found that the apparently healthy living tissues, preserved by the method before described, underwent fermentation and organisms developed in them. In one case the kidney alone of all the organs taken, and in another both kidney and liver, miderwent fermentation with development of organisms, and as I was very careful in performing the expe- riments, I do not think that this could have occurred from any error in experi- mentation, and therefore I conclude that the causes of fermentation (micro- organisms, as we shall afterwards see) were present in the healthy circulating

GENERAL CONCLUSIONS. 49

living body, like the fluids, contain no ferment capable of causing putrefaction after death, and remain pure in flasks so long as the dust of the atmosphere is excluded. (In some instances the heart with its contained blood was also removed, and remained, like the other tissues, unaltered. Rabbits and cats were the animals used for the experiments.)

Somewhat similar experiments Avere published in 1878 by Chiene and Ewart, and they yielded similar results.'

Quite recently,^ Rosenbach mentioned experiments on this subject performed by Meissner. Meissner was able to preserve the internal organs of cats and rabbits in contact with boiled water and pure air, for two to three years, without the occur- rence of any putrefactive change. He was also successful in preserving the blood of mammalia, human urine, and g'oat's milk. The experiments were done with strict aseptic j^recau- tions, and led him to conclusions similar to the above.

Such, then, are the chief facts at present known with regard to boiled and unboiled fluids and tissues. We shall add much to them, and to the support which they give to the views here expressed, when we come to consider more minutely what is the nature of the particles which cause putrefaction.

On reviewing the mass of evidence before us we have it dis- tinctly shown that boiled fluids and tissues have no inherent tendency to undergo fermentative changes ; that oxygen, whether pure, nascent, or mixed with nitrogen in the proportions present in air, cannot cause fermentation, if only the air be previously passed through such a liquid as sulphuric acid, be heated strongly, be Altered through cotton wool, be made to enter very slowly into the flask containing the fluid or allowed to deposit its dust by gravitation, or be previously acted on by carbolic acid.

blfiod. That an orgniiif^jn may be present in an active state in tlic circulating blood need not be a matter of surprise, and need not therefore lead us to the conclusion that they are always or even generally there, especially as one single organism would be sufficient to account for the result in each of these instances. It is indeed surjirising that organisms which must now and then enter the blood arc so rapidly and surely destroyed.

' Journal of Aiuitonnj and I'Jn/Riolofjy.

Uvidschc ZcitH'-hrift fiir C/nrurf/ie, xiii. .'544.

E

50 THE PARTICULATE THEORY OF FERMENTATION.

Thus the material in the air which causes putrefaction is not a gas, for that would be continuous, and would not be re- movable by filtration or by rest ; but it is something discon- tinuous, something heavier than air, something particulate. These particles may be deprived of their power of causing fermentation by the action of chemical substances, such as sulphm'ic and carbolic acids, and also by being subjected to a high temperatm'e. As they are completely destroyed by heat (as shown by Tyndall), they are probably of an organic nature.

And it is not that by boiling these fluids an inherent tendency to ferment has been destroyed, for, as we have seen, they possess no such inherent tendency. For not only do unboiled fluids and tissues outside the body fail to putrefy when protected carefully from dust they also undergo no change, as indeed necessarily follows from the foregoing, when confined in natural or artificial cavities in the living body. Who is not acquainted with the behaviour of blood when ex- travasated into the tissues or cavities of the living body so long as it is not exposed to the outer world ? We all know what a large amount of effused blood may be present about the ends of a fractured bone without decomposition occurring in it, and the same is the case in the hemorrhages into joints in hemophilia, hemorrhages within the skull, &c. And we also know what frequently happens if we cut into any of these extravasations and admit dust-laden air into them. The blood which we found odourless, and it may be clotted, may become in a few hours a foul- smelling liquid ; it has, in fact, putrefied, just as it may do when kept in a flask without exclusion of dust. And just as in the case of blood, so with other fluids. Hy- drocele and serous effusions remain unaltered so long as they are kept from the dust. Examine the pus from a chronic abscess, and even though that abscess be connected with carious bone, it will be found to be odourless and bland, and if carefully received into pure flasks, will, just as in the case of blood, remain odourless and apparently unchanged for an indefinite length of time. (I shall give later on the explanation of the cases where the pus of acute abscesses, when let out, is found to have a foul smell, as is sometimes the case in acute necrosis.)

CONCLUSIONS. 51

And not only is this the case with fluids, it is also the case with tissues in the living body. In a fractm-e many portions of the tissue are cut off from their vascular supply, or killed by the violence causing the injury, and yet they do not decompose ; they are not separated as sloughs they disappear by absorption. Yet if the same injury be not subcutaneous and the injured parts be exposed to ordinary air, they putrefy, and come away in a few days as sloughs.

So in infarcts in internal organs, the tissue in the region of the infarct dies, but does not putrefy does not slough ; while when death of the integuments occurs, putrefaction and slough- ing follow, for here the dead tissue is exposed to the dust of the atmosphere.

Similarly, in the case of wounds, when a piece of skin is cut away and an open sore is left, the blood and serum which col- lect in that sore ferment, in all probability putrefy, because the air admitted to them was not heated air, not filtered air, was air which had not been acted on by suitable chemical sub- stances.

The causes of fermentation are therefore solid particles, pro- bably of an organic nature, which are present in varying quan- tities in the surrounding air, and which are deposited as dust on all surrounding objects.

It is thus evident that in order to prevent putrefaction it is only necessary to prevent the access of these particles, or, if this cannot be done, to destroy their fermenting power in some way or other before they reach the wounds as, for instance, by the use of carbolic acid.

It is on this principle that Aseptic Su7'gery,^- as introduced by Mr. Lister, is based.

' The term ' aseptic ' is the best to indicate this form of antiseptic surgery, because, as we siiall see, there are many different forms of treatment which come under the term 'antiseptic,' while this is the only one which can truly bear the name 'aseptic' In other words, there are many methods by which the occurrence of putrefaction is more or less interfered with, but they all act on a more or less imperfect principle, with the exception of that introduced by Mr. Lister, which, founded on a true principle, attains the ideal of results viz. a complete absence of putrefaclion— an asepsis. His methcd, then, is best designated by the term expressing its result Aseptic.

E 2

52 ASEPTIC SURGERY— MATERIALS EMPLOYED.

CHAPTER in.

ASEPTIC SURGERY MATERIALS EMrLOYED.

Problems to be solved in order to keep a wound aseptic : Carbolic acid CarhoUc lotions Pure carholic acid SoUttioitin metliylated sjnrit carbolic oil Carbolic acid and glycerine: Sj^ray producers: Catgut Carholiscd catf/ut Mr. Lister's carholiscd chromic catgut Dr. MacEwen's chromic catgut— Ca-tguttrough and pocltet caxe: Carbolised silk : Protective: Carbolic gauze Composition 3Iethod of preparation Von Bruns'' gauze: Mac- intosh : Sponges : Boracic acid Boracic lotion Boracic lint Boracic ointm-ent: Salicylic a-cid— Salicylic acid cream Salicylic ointment : Chlo- ride of zinc : Iodoform : Carbolised cotton wool.

Aseptic surgery is based on the piinciple first enunciated by Mr. Lister, and indicated in the preceding pages ; viz. the exclusion of active ferments from the discharges of wounds.

Theoretically, this is the ideal form of antiseptic surgery, for here, supposing that the attempt is successful, the causes of putrefaction do not enter the wound in a state capable of pro- ducing fermentation, and therefore decomposition of the dis- charges, or of dead portions of tissue, &c., cannot 2:)0ssibly occur.

The problem which Mr. Lister sought to solve may be shortly stated as follows :

On all objects in the external world septic dust is present on the skin of the patient, on the hands of the surgeon and his assistants, on all instruments, in water, in the air, &c. ; and when a wound is made any introduction of this dust must be carefidly avoided. Then after the wound has been made, care must be taken to prevent its entrance during the after-treatment. Some sort of dressing must be provided which shall prevent its passage in an active state, and at each change of this dressing the problem is the same as at the time of infliction of the wound. Such being the question

CARBOLIC ACID. 63

at issue, I must now proceed to the modes in which it has been answered.

I shall first enumerate the substances employed in aseptic surgery.

Carbolic Acid is the antiseptic employed to destroy the particles in the air and on surrounding objects which give rise to putrefaction. It is obtained in the solid state and of ex- treme purity from Bowdler and Bickerdike, Church, Lancashire, who give it the name of Absolute Phenol. It is used in various forms.

The Cai'bolic Lotions used are of two strengths 1 in 20 and 1 in 40 ; one part of crystallised carbolic acid dissolved in 20 or 40 parts of water respectively. The solution is kept in a stoppered bottle in order to avoid evaporation of the acid. It ought to be quite clear ; when it is not so, and more especially when globules of oily matter are present, it is impure, the oily particles consisting of cresylic acid. It is a mistake to add alcohol or glycerine to aid the solubility of the acid, because these substances hold the acid more tenaciously than water, and it is thus not so potent for producing an instantaneous effect.

Undiluted Liquid Carbolic Acid may in some cases be required. This is obtained by liquefying the crystals by the addition of a few drops of water. This is chiefly used for injecting naevi, varicose veins, vtc.

A solution of carbolic acid in methylated spirit or in recti- fied spii-it, in the proportion of 1-5, is used for the purpose of purifying wounds inflicted some twenty-four or thirty-six hours before coming under treatment.

Carbolic Oil is employed in various proportions, generally 1 in 5, 1 in 10, and 1 in 20, consisting of carbolic acid mixed with olive oil in the foregoing proportions.

Carbolic oil 1-5 is but rarely used, tliough it is occasionally applied as a dressing to foul wounds, for the purpose of purify- ing them. It is chiefly known as the solution in which catgut is permanently preserved.

Carbolic oil 1-10 is used as a dressing for wounds in the neighbourhood of the anus, penis, &c.

Carbolic oil 1-20 is used for oiling catheters or other in-

64

ASEPTIC SUROERY^MATERIALS EMPLOYED.

struments before introducing them into tlie bladder. Carbolic acid of this strength does not seem to be too irritating for the

Fig. 15.— Hand spray producer.

mucous membrane of the urethra, while it apparently secures against the introduction into the bladder of matters which are capable of causing putrefaction.

There are various objections to these oily dressings. The chief are, that the carbolic acid is very rapidly washed out by the dis- charge, and that they are very dirty, and soon spoil india-rubber tissues.

The latter disadvantage is got rid of by the use of carbolic acid and glycerine in the proportions of 1-5 and 1-10. This is now employed as a dressing in the cir- cumstances in which the oil has been generally used.

A sjjray of carbolic acid is generally employed in order to purify the atmosphere. This is obtained by driving a rapid

Fig. 16.— The ordinary steam spray producer.

CARBOLIC ACID SPRAY.

55

current of air or steam through a horizontal tube so as to pass over the orifice of a more or less vertical one. In this way a vacuum is produced in the vertical tube, and the fluid at its lower end rises, and is expelled from the orifice in the form of spray. We have two forms of spray : one in which air is

Fig. 17,

Steam spray producer, showing the lamp at present

IN USE.

It consists of a small flamo, which plays on a plate of metal attached to a hollow central tiibe containing a wick, and perforated by holes at the top. The heat is communicated to tlie wick —the spirit volatilises, and Inirns as it escapes from the top of the tube. The hole in the plate allows the flame of tlje snjall wick to pass up and li^■ht the spirit vapour, which jiasscs out through the holes at the top of the central tube. The cap, which is jjlacfd over the lamp when not in use, and the boiler and vessel for the carbolic acid, are indicated by dotted lines.

driven over the vertical tube hand or foot sprays ; and the other in which steam is employed steam sprays. The hand or foot sprays produce a somewhat coarse spray, and the force required is such as soon to exhaust the individual employed. They are therefore very uncertain implements, and have now entirely given place to the steam spray.-;, where there is a steady current as long as the water in the boiler lasts. When the hand s])rays are emi)loypd 1-40 solution is placed in the bottle.

50

ASEPTIC SURGERY— MATERIALS EMPLOYED.

In the steam spray the 1-20 solution is used because the steam, mixing with the solution, reduces its strength to 1-30 or 1-35. I need not describe here the steam spray apparatus, more especially as it can be easily obtained, of Mr. Lister's pattern, from David Marr, 27 Little Queen Street, Holborn. These sprays consist of the following parts : A boiler which contains water, and which is heated by a spirit lamp placed beneath it. The steam issues through a tube placed at an angle to another more upright one, through which the carbolic acid lotion 1-20,

which is placed in the glass retort, is sucked up. This 1-20 lotion, mixing with the steam, makes a solution of 1-30 to 1-35. The carbolic acid solution passes through a sponge at the bottom of the upright tube, which filters it, and thus prevents the minute orifice of the tube from be- coming choked up by coarse particles. These sprays are of various sizes, and the largest ones have two nozzles, which may be vised singly, or to- gether where the field of operation is large as in ovariotomy.

The catgut used for tying the vessels is prepared in the following manner : Ordinary catgut as obtained from the shops, when introduced into blood-serum, soon swells up and becomes weak. At the same time it is very slippery, and a knot will not hold ; and when placed in the tissues it very rapidly becomes absorbed. With the view of obviating these defects it is prepared by placing it in a solution of carbolic acid in oil (1-5) with a very small quantity of Avater (10 per cent.) diffused through the oil. As the water ultimately falls to the bottom, a few pebbles are placed on the bottom of the vessel, on which the catgut rests. It does not then come in contact with the water. As a result of keeping it in this solution, the catgut first becomes supple and soft, but afterwards harder and firmer, and is then al)le to resist the action of the fluids and

Fig. 18.— Large steam spray riio-

DUCER WITH DOUBLE NOZ/LE FOR OVARIOTOMY, ETC,

CATGUT. 67

tissues for a considerable time. It is kept in this fluid for six or eight months, and is then transferred to the ordinary 1-5 oily solution. The longer it is kept in this solution the better it becomes. The rationale of this method will be found in ^Mr. Lister's paper in the ' Lancet ' of Feb. 5, 1881.

Quite recently ^ jNL-. Lister has published a new method of pre- paring catgut, by means of which a stronger article is obtained, and one not absorbed nearly so soon as the old kind. It also possesses an advantage over the old kind, in that it disappears by erosion of the surface, and does not become infiltrated with cells, as is the case with the ordinary forms. It thus remains as a firm constricting band, till it is completely replaced by new tissue. I cannot do better than quote JVIr. Lister's description of the method by which this gut is prepared : ' I dissolve one part of chromic acid in 4,000 parts of distilled water, and add to the solution 200 parts of pure carbolic acid, or absolute phenol. In other words, I use a 1-20 watery solution of carbolic acid only that the carbolic acid is dissolved, not in pure water, but in an exceedingly dilute solution of chromic acid. But, minute as is the quantity of the chromic acid, it exerts, when in conjunction with carbolic acid, a most power- ful effect upon the gut. The first effect of the addition of the carbolic acid to the chromic solution is to change its pale yellow to a rich golden tint. But if the liquid is allowed to stand without the introduction of the catgut, it changes in the course of a few hours to a dingy reddish-brown, in consequence of some mutual reaction of the two acids ; and a considerable amount of reddish grey j)recipitate is formed. If, however, catgut about equal in weight to the carbolic acid is added as soon as the ingredients are mixed, the liquid retains its bright- ness, and the only change observed is the gradual diminution of the depth of the yellow colour; the precipitate, which I pre- sume still occurs, taking place into the substance of the catgut. As soon, therefore, as the preparing liquid has been made, cat- gut equal in weight to the phenol is introduced into it. If you have too large a ]»roportion of catgut, it will-not be suffi- ciently ])repared; if you have too small a (juantity, it may run the risk of being over-prepared. At the end of forty-eiglit

' Lancet, Feb. 5, 1881.

58 ASEPTIC SURGERY— MATERIALS EMPLOYED.

hours the chromic element of the liquid has nearly spent itself, and precipitation is complete. The catgut is then taken out of the solution and dried, and when dry placed in 1-5 carbolic oil : it is then fit for use. . . . The preparing liquid causes a certain amount of softening of the catgut, and if it is intro- duced in loose hanks, this will tend to produce a little uncoil- ing of the twisted cord, and a still greater degree of uncoiling will take place during drying. It is of very great importance that this should not occur, because it involves weakening of the thread, and that in different degi'ees in different parts ; and this may lead to the gut giving way when you subject it to a strain. The catgut then should be prepared on the stretch, both when it is put to soak and when it is put to dry.

' I need not enter into the mode in which this can be done by the manufacturer. I may only say this, that the surgeon who wishes to prepare it himself may do it in different ways. For instance, he may take two large test-tubes, one a little larger than the other, and he may wind the catgut on the smaller tube, fixing one end by sealing-wax, winding it round, and then bringing it up again, and fixing the other end with sealing-wax at a higher level than the liquid will reach, putting sufficient liquid into the larger test-tube, and introducing the smaller test-tube with the catgut wound round it, with a little shot to keep it down in the liquid. After forty-eight hours, he takes out the smaller test-tube, and leaves it till the catgut is completely dry. I merely mention this as an illustration, and also as furnishing a hint to some surgeons in private practice who may desire to prepare the catgut themselves ; or a couple of gallipots, one larger than the other, will do just as well. But, as I have said, the principal uncoiling takes place during drying ; and for all ordinary purposes a sufficiently good article is got by putting the catgut loose into the liquid, and making it dry on the stretch by tying the ends of each hank to two fixed points in a room.' Erosion of this catgut does not begin till about a fortnight after its introduction into the tissues.

Dr. MacEwen has lately brought forward a somewhat different method of preparing catgut.' ' These ligatures are prepared by making, first, a watery solution of cliromic acid, one

' Britisli Medical Journal, Jan. 2'.), 1881.

CATGUT.

59

to five ; then one part of this solution is added to twenty of glycerine. This forms a dark greenish compound, in which the hanks of catgut are inserted and retained for seven or eight months, the bottle containing them being occasionally shaken. At the end of this time the catgut acquires a semi-translucency, and has a dark colour like preserved ginger. It is then ready

Fig. 19. Trough for catgut.

for use, and is stored in a solution of carbolic acid and glycerine (one to ten).' Ligatures so prepared begin to soften on an average about the fourteenth day, and are more or less com- pletely absorbed the twentieth day.

A very convenient method of keeping catgut for use in hospital is to wind it round reels, say three, each holding a different thickness of gut, which are suspended in a vessel

X._^

V ^

^ ^'

-^^^^

Fig. 20. Lister's pocket catgut holder.

A, HoMcr complete. B, The reel on which the catgiit is wound.

containing carbolic oil 1-5 (see Fig. 19). The lid of the box is perforated with holes through which the ends of the catgut pass. In this way the gut may be taken directly from the oily solution without any trouble.

In order to have a supply of gut always at hand, jNIr. T.,ister has devised the catgut holder shown in the accompanying figure (P^'ig. 20). The gut is wound on a reel which is carried in a German silver case. There is no necessity to fill tin's case with

60 ASEPTIC SURGERY— MATERIALS EMPLOYED.

carbolic oil, as is done by some surgeons. Sometimes the case is combined with a caustic holder at the other end.

Carbolised Silk is often used for sutures, and is prepared as follows : Nine parts of beeswax and one part of carbolic acid are melted together. Silk thread of various sizes is steeped for some minutes in this mixture, till it is thoroughly impreg- nated with it. As the thread is taken out, it is drawn through a cloth in order to remove the superfluous wax. The wax holds the carbolic acid, makes the thread more useful, and fills up to some extent its interstices, thus preventing it from becoming soaked with fluids. The carbolised silk thus prepared is kept permanently in stoppered bottles, or wrapped in carbolic gauze. It must- not be steeped for any length of time in the lotion before being used, because the threads become opened out. If the thread be properly kept, the interior is aseptic or even anti- septic, and passing the thread through the fingers moistened with carbolic lotion, or a momentary immersion in 1-20 car- bolic solution, is sufficient to destroy any septic dust adhering to its exterior.

In order to protect healing wounds from the irritation of carbolic acid a special material is employed termed the Protec- tive. This consists of oiled silk coated with copal varnish. When this is dry a mixture of one part of dextrine, two parts of powdered starch, and sixteen parts of cold watery solution of carbolic acid (1-20) is brushed over the surface. The rationale of this method of preparation is the following : Oiled silk alone is better for the purpose of a protective than gutta-percha tissue, because carbolic acid does not so readily pass through it. It does, however, do so, and therefore copal varnish, which is almost absolutely impermeable to carbolic acid, is added. As, however, the fluid collects on this as on a duck's back, leaving intervals between each drop on which dust may fall and escape the action of the acid, the dextrine solution is added, and the result is, that when moistened the whole surface of the protec- tive remains imiformly wet. The use of the carbolic acid in the dextrine solution is not to add any carbolic acid to the pro- tective, but because it is better than water for enabling the dextrine to adhere to the varnished oiled silk. For the same reason the ])owdered starch is added. The original carbolic

CARBOLIC GAUZE. 61

acid flies off very quickly from the protective, leaving a material containing no antiseptic in its substance.

Garholic Gauze is the material generally employed as a dressing to guard against the entrance of causes of fermentation into a wound after an operation. The gauze used is ordinary fine unbleached tarlatan washed and dried. There are various methods of impregnating this gauze with carbolic acid. I will give Mr. Lister's description of a simple method, w^hich can be used in any hospital, and which was recently employed during the Russo-Turkish war for making fresh gauze in camps. ^ The mixture employed for charging the gauze was originally one part of carbolic acid, five parts of resin, and seven parts of paraffin. Lately the formula has been changed to one part of crystallised carbolic acid, four parts of common resin, and four parts of paraffin. These materials, mixed together, are added to an equal weight of unprepared gauze. ' In order to charge the gauze, the paraffin and resin are first melted together in a w^ater bath, after which the acid is added, and blended by stirring. The object now is to diffuse this melted mixture equally through the cotton cloth, and for this purpose two things are requisite, viz. that the cotton be at a higher tem})erature than the melting point of the mixture, and that it be subjected to moderate pressure after receiving it. The cotton cloth, a yard wide, is cut into six-yard lengths, and these having l^een folded so as to be half a yard square, are placed in a dry hot chamber, formed of two tin boxes placed one within the other, with an interval to receive water, which is kept boiling by fire or gas beneath, the upper edges of the boxes being connected and provided with an exit pipe for the steam. There is also a glass tube arranged as a gauge of the amount of the water, and the chamber has a properly fitting lid The bottom of the chamber is strengthened with an iron plate, to enable it to bear the weight used for compressing the gauze when charged. There is a piece of wood about two inches thick nearly fitting the chamber, covered with sheet lead, so as to make it about as heavy as a man can lift by means of two handles in the upper fjurface. The weight is lieatcd along with the cotton, and is puf, ^rst into the cl;:imber so as to leave ' See Lancet, Marcli 13, 1875.

(i2 ASEPTIC SURGERY— MATERIALS EMPLOYED.

the cotton loose for the penetration of the heat, which occupies two or three hours. The cotton when heated is taken out of the chamber along with the weight, and placed in a wooden box to protect it from the cold. (It would be better to have a second hot chamber for this purpose, since in cold weather the cotton is apt to be too much cooled in spite of the protection of the wooden box.) The heated gauze is then at once charged with the melted mixture of carbolic acid, resin, and paraffin, in quantity equal to the weight of the cotton fabric (or slightly less), and in order to diffuse the liquid as equally as possible, it is sprinkled over the gauze by means of a syringe, with a number of minute perforations in its extremity, the body of the syringe and the piston-rod having each a wooden handle to pro- tect the hands of the workman from the heat. The syringe is constructed to hold half the quantity of the mixture required for charging one piece of cloth. One folded piece being placed at the bottom of the hot chamber, its upper half is raised and turned aside, and one syringeful is sprinkled over the lower half. The upper half is then put back into position, and another syringeful thrown on. The same process is repeated with all the other pieces of gauze, after which the weight is put into the chamber to compress the charged cotton, and the lid applied. An hour or two are then allowed to elapse, to permit the com- plete diffusion of the liquid, when the material is fit for use. The apparatus above described can be made by a common tin- man for about lOL' Fig. 21 shows the apparatus employed in the Griasgow Infirmary.

As the muslin is the dearest item in the gauze Mr. Lister has suggested that the dressings should be washed and the gauze recharged. The larger dressings are therefore kept and sent back to the manufacturer, who washes and recharges them. This recharged gauze can then be used as loose gauze in future dressings.

In this gauze the carbolic acid is the only active agent ; the resin is used to hold the acid i.e. to prevent it from being washed out too soon by the discharge while the paraffin is employed to lessen the adhesiveness of the resin. The gauze

' See ' Practical Papers on the JIaterials of the Antiseptic Method of Treatment.' I'y George lieatson. Glastjow Medical Journal, March 1880.

CARBOLIC GAUZE.

63

ought to be kept in a tin box, closing tightly to prevent evaporation of the carbolic acid. It is used either in the form of loose gauze or folded dressings and bandages.

A great many different ways of preparing gauze have been published, but none are so good as that just described.

Von Bruns has lately recommended a gauze containing castor-oil instead of paraffin.

His formula is

Carbolic, acid Resin Castoi--oil Spirit

1 part 4 parts 8 20

Fig. 21. Machine used in the Glasgow royal infikjiary for manufacturing gauze.

A is tlie receptacle for the antiseptic mLxture of carbolic acid, resin, and paraffin ; E is the tin case in whicli the muslin is heated, impregnated with the mixture, and submitted to pressure. IJ is a pipe whicli conveys steam for heating the apparatus, and E E are stopcocks for turning on or shutting off the steam in connection with either A or B. (From Dr. Beatson's ' Practical Papers on Antiseptic Surgery.')

The resin is first dissolved in the spirit, then the carbolic acid and castor-oil are added. The gauze is simply soaked in this, and then hung up to allow the spirit to evaporate. The objection to this gauze is that the castor-oil interferes with the affinity of resin for carbolic acid, and thus the carbolic acid will be sooner washed out, «ind the gauze thereby rendered less trustworthy.

In order to prevent the discharge from soaking directly through the dressing macintosh cloth is used. This is cotton cloth with a thin layer of india-rubber spread on one

64 ASEPTIC SURGERY—MATERIALS EMRLOYED.

side. It is placed outside the gauze dressing. As a rule one layer of the gauze comes outside it, partly in order to keep it in position, and partly also, in case any hole should exist in the macintosh, to have a little antiseptic material outside. Care is taken that the side on which the india-rubber is spread goes next the wound, for if the other side be placed inwards it absorbs discharge, and, not being itself antiseptic, it becomes in reality a piece of impure cotton in the interior of the dressing, and may thus communicate putrefaction inwards. The macin- tosh itself also gets spoilt when so used. The dressing con- sists of a piece of gauze of sufficient size folded in eight layers, beneath the outer layer of which the mackintosh cloth is placed.

Sponges are washed after an operation, and are then kept soaking till required in a jar containing carbolic acid 1-20. During an operation they are washed in 1-40 carbolic acid lotion.

These sponges often become filled with fibrin, and thus rendered more or less useless. It is very difficult to remove this fibrin by washing. Mr. Lister, therefore, after an operation places the sponges in a tank containing water. Putrefaction of the fibrin occurs, and after some days the sponges can be easily cleansed. They are then placed till required in the 1—20 carbolic solution.

When the wound becomes quite superficial, various prepar- ations of BoKACic Acid may be employed with advantage.

Boracic lotion is a cold saturated solution of boracic acid (BgOgSHgO) in water. This acid is soluble in 25 to 30 parts of cold water, and in very much larger proportion when the water is boiling. It is convenient to tinge this solution with litmus in order to distinguish it from the carbolic lotions.

Boracic lint is ordinary surgical lint soaked in a hot saturated solution of boracic acid and then hung up to dry. About half its weight consists of crystals of the acid. This is also stained with litmus.

Boracic ointment is employed in certain cases. Two strengths are commonly used, called full strength and half strength ; the former being applied to wounds where cavities exist, the latter to superficial wounds which one wishes to heal

SALICYLIC ACID. 65

rapidly. The following is the original formula for the full strength ointment :

Boracic acid crystals ..... 1 part

White wax ....... 1

Paraffin ........ 2 parts

Almond-oil ....... 2-

First mix the wax and paraffin by heating them together, then add the oil ; mix the crystals with this in a warm mortar, and continue the process of mixing till the liquid solidifies. Spread on thin cotton cloth.

The half strength contains half the quantity of boracic acid.

A much softer and more manageable boracic ointment is now made with vaseline. The following is the best formula :

Make a basis of 2 parts of paraffin to 1 part of vaseline. Take of this o parts

boracic acid, 1 part. Mix.

Salicylic acid cr'eam is used for applying around a wound when a dressing is to be left on for some days. It prevents irritation by the discharge. It formerly consisted of salicylic acid crystals mixed with 1-20 carboh'c acid lotion in sufficient quantity to form a creamy fluid. This is apt to separate into two layers, and therefore it is better to make a cream by mixing salicylic acid with glycerine so as to form a paste. This latter cream remains of uniform consistence, and is easily applied. For this purpose Mr. Lister uses glycerine and carbolic acid 1-10.

The' formula for salicylic oinhnent is

Of the same l^ase as is used for boracic acid . 29 parts Salicylic acid ....... 1 part.

For the purpose of purifying sinuses, putrid ulcers, &c., a solution of chloride of zinc is used of the strength of 40 grs. to the oz. of water. This is either apjdied on lint to the whole surface of a wound, or it is injected by means of a syringe and catheter into all the deep parts of the wound, care being taken to provide free exit for the fluid injected. If the exit of the solution is obstructed, it may pass into the tissues and cause gangrene.

lodofoivi is now applied to the surface of ulcers, and

F

66 ASEPTIC SURGERY— MATERIALS EMPLOYED.

answers the same purpose as the chloride of zinc solution, while it causes no pain.

Carholised cotton ivool is used in some cases of gangrene. It is obtained by soaking pure cotton wool in a 1 per cent, solution of carbolic acid in ether. The cotton is then dried and used immediately.

DESCRIPTION OF AN ASEPTIC OPERATION.

CHAPTER IV.

ASEPTIC SURGERY (continvcd).

Example of an aseptic operation : Purification of the skin Fingers Instru- ments : Spray Precautions Probable errors, and mode of remedying them : Guard : Ligature of arteries : Drainage of wounds India-rubber tubes Catgut drains Horse hair Decalcified bone tubes (Neuber's and MacEwen's) : Sutures ; Button stitches Stitches of relaxation Stitches of coaptation Aseptic strapping Protective : Deep dressing : Loose gauze : Gauze dressing : Elastic bandage. Changing the dressings Time— Method. Treatment op ulcers : Purification of the sore : Boracic dressing : Boracic and salicylic ointment : Boracic poultice.

Having described the materials employed in aseptic sm-gery, we must now consider how they may best be employed. Take as an example of an operation the removal of a fatty tumonr.

The patient having been brought under the influence of chloroform or other amesthetic, the skin over the tumour, and for some distance in the vicinity, is thoroughly pmified from any active dust by washing it well with a solution of carbolic acid 1-20. The surgeon and his assistants also wash their hands in 1-40 carbolic lotion, while the instruments are put to soak in 1-20. A towel is arranged close to the tumour, gene- rally on the part of the table between the operator and the patient, which towel has been well soaked in 1-20 carbolic lotion, and is meant as an antiseptic basis on which instruments may be laid during the course of the operation without any fear of their contamination. This towel is so arranged as to be within the cloud of spray. A spray being now made to play over the i)art from a convenient distance, the surgeon makes his incisions, removes the tumour, ties the vessels with catgut, introduces a suitable drain, stitches up the wound, and a])i)lies a piece of protective but little larger than the wound the pro- tective being of course dipped in the 1-40 carbolic solution.

p2

68 ASEFTIC SURGERY.

Outside this is applied a piece of wet gauze, consisting of several layers of loose gauze which has been soaking for some time in the 1-40 carbolic solution. This wet gauze and pro- tective are called the deep dressing. The wet gauze must overlap the protective in all directions. Then any remaining hollow is filled up with loose gauze, and outside the whole a gauze dressing is fixed. This dressing consists of a piece of carbolic gauze of suitable size, folded in eight layers, and having the macintosh placed beneath the outermost layer, with the india-rubber side inwards. The dressing is fixed by means of a bandage, and when this is accomplished the spray may be stopped. Then around the edge of the dressing an elastic bandage is applied so as to keep the edge constantly in contact with the body, and to allow no interval to occur between the dressing and the skin during the movements of the patient. The elastic is carefully fixed to the edge of the dressing by means of safety pins.

In the after progress of the case the dressing is changed according to the amount of discharge, though in no instance is it left longer than eight days.

Such is, very briefly, a sketch of the ordinary method of performing operations aseptically. I shall now consider each step in detail, and point out the most frequent sources of failure in carrying out the method ; for it must always be borne in mind that the whole operation, as far as regards the avoidance of putrefaction, requires as much care as if it were an experiment performed in a laboratory on putrescible fluid con- tained in glass vessels.

The first thing, then, is to purify the skin in the neigh- bourhood of the seat of operation. This is necessary, because the skin is covered with dust. The natural grease of the skin is not easily removed by simple washing, and it protects the septic particles present beneath it and in the hair or sebaceous follicles. This purification of the skin is carried out by washing it well with 1-20 carbolic lotion, the antiseptic being allowed to act for some little time. It is well, having first washed the neigh- bourhood thoroughly, to apply over the seat of operation a large rag or towel soaked in 1-20 solution, and to allow this to remain on the part for some minutes. Where the epidermis

PURIFICATION OF THE SKIN. 69

is thick, or where there is any putrid matter present, it is best to apply this towel about half-au-hour before the operation. It is not necessary to wash the skin with soap and water, or with alcohol or ether, as is often done in Germany. The carbolic acid has a wonderful power of penetrating grease or epidermis ; and if time be given for it to act it is unnecessary to wash off the grease beforehand. If the wound is to be in the neigh- bourhood of hair, as in the axilla or near the pubis, the part must be shaved, and then well soaked with the carbolic lotion.

The errors in the purification of the part may be that the skin is not purified at all, or that it is washed with water ; or, as I have seen, the operator simply allows a carbolic spray to play over it for a minute or two, and is satisfied with this ; or he merely rubs the siuface with his wet finger. This purifica- tion must, however, be done thoroughly, for every hair follicle and gland duct may contain causes of putrefaction. Carbolic oil is used by some instead of the watery solution to purify the skin. This is a great mistake, for oil has a much greater affinity for carbolic acid than water has, and therefore the carbolic acid in the oily solution does not act with the same rapidity as the watery solution. Thus 1-20 or even 1-10 car- bolic oil is not nearly so useful for producing an instantaneous effect as 1-20 carbolic lotion.

At the same time the operator and his assistants purify their hands. This must also be done thoroughly, and the folds of skin about the nail more especially must be well cleansed with the lotion. In an important operation, as in an o})eration on a joint, it is well to use 1-20 carbolic lotion for this purpose, so as to avoid any chance of a lurking particle ; but in ordinary operations 1-40 is quite sufficient. This purification of the hands is only too apt to be a sham, no care being taken about the nails and folds of skin. The 1-20 is not used in all cases, because 1-40 is really sufficient, and the stronger solution is apt to benumb the hand.

The instruments are purified by immersion in 1-20 carbolic lotion before theojjeration. A tin or jxHcelain trough filled with the 1-20 solution is employed for tliis purpose, the instruments being placed in it souk; time liefore an operation (l*'ig. 22). The instruments are not merely dipped ; they must remain in

70

ASEPTIC SURGERY.

the lotion for some time, because the carbolic acid requires a little time to act on the grease or dirt on them. For the same reason the teeth of toothed instruments ought to be cleaned thoroughly, and forceps locking by catches ought to be widely opened, so as to allow the solution to come in contact with all parts. The whole instrument must be immersed, for if only the point be purified it may happen that the impure handle is in- advertently brought into contact with the wound during the course of the operation.

The errors most likely to occur are either that during the course of the operation an instrument not previously in the tray is used without any attempt at purification, or that the instru- ment is imperfectly purified or only part of it cleansed. I have seen the danger of partial purification more than once exem-

FlG. 22. I'DRCELAIN TROUGH CONTAINING INSTRUMENTS SOAKING IN CARBOLIC LOTION.

plified. Thus I have seen the blade of a knife alone purified, and the surgeon in the middle of the operation use the unclean handle to separate the tissues. Other errors in the manipu- lation of instruments will be referred to presently.

The spray is very important in many cases, for it provides an atmosphere in which instruments, &c., may be kept without danger of contamination. In order to have a wide and large antiseptic area in which to work, the spray ought not to be too near, about six or eight feet or more being a suitable distance for a good spray. Care must be taken that the spray is not blown off the part by draughts or by people moving about. The spray is most necessary in opening abscesses or in stitching up wounds, for, to take the latter case, as the wound is not syringed

SPRAY

71

out after the stitches are inserted, septic air may be inclosed in the cavity of the wound, and may give rise to putrefaction if

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the spray has not been playing over the wound while the stitches were being introduced.

During the course of an operation any instrument which has been once purified, if kept in the spray, even though covered' with blood, remains piu*e, and may be introduced into the

ASEPTIC SURGERY.

wound without hesitation. The same is the case with the hands of the operator or assistants ; and therefore the dresser, in handing instruments to the surgeon, if)iust hand them into the spray (Fig. 23). If in the course of the operation the surgeon reaches his hand or an instrument out of the spray for any reason whatever, it must be repurified before being put into the wound. For this purpose there is generally a

Fig. 2i.— To show the arrangement of towels, etc., in a large

OPERATION.

a a a Are tliree towels which have been soaked in 1-20 rarholic lotion, so that inatruments, &c. may be placed on them without fear of contamination. Tlm^ a small sponse will be seen on the upper one. d is tlie dish containing 1-40 carbolic lotion wliioli alwavs stands before the oiicrator, and in the line of tlie spray. In this he places the instruments which are not being used, and in it lie rcpurifies his hands or instruments if they have been removed from tlie elonil of spray. In tliis particular instance we have a lar^e wound to deal with— one so large that a single spray, unless of large volume, may not cover it completely. Hence a piece of gnai-d soaked in carbolic lotion Is thrown over the front of the wound while the surgeon is attending to the axillary part, or rice versd.

basin of 1-40 carbolic lotion placed close to the operator in the line of the spray, in which fingers, instruments, &c., may be re-purified by momentary dipping. When instruments are laid down out of the spray, or, in the spray, on a blanket, they must be repurified before being used again. To provide a basis on which instruments may be laid, the carbolised towel is arranged before the operator as formerly described, and the blankets in the neighbourhood are generally also covered up

SPRAY, 73

with wet towels, so as to avoid the chance of the instruments being laid on the blankets (see Fig. 24). Should the operator, during the course of an operation, wipe his hands in a dry towel, or touch any unpurified substance, he must remember to wash his hands in 1-40 carbolic lotion before re-introducing them into the wound.

These precautions seem on the one hand self-evident, while on the other they seem so burdensome to remember that they are often neglected by self-sufficient surgeons. And yet it is by the neglect of these, rather than by error in any other part of the Listerian method, that mistakes arise and failures occur. Many people think that the spray is the essential part of the treatment, and neglect the precautions as to constant purification of instruments, &c., and when their cases go wrong they say that the principle is incorrect. And yet one thoroughly acquainted with the Listerian method will readily detect the loopholes, and the general loophole is the omission of some of the precautions with regard to purification of fingers, instruments, &c. Thus I have seen a surgeon with considerable experience in aseptic treatment, during the com-se of a difficult operation wipe his hands with a dry towel and immediately introduce them, covered with the dust from the towel, into the wound. The patient died of septic poisoning. Now many surgeons might have said, ' I used the spray ; 1 used all precautions ; my instruments were soaking ; my hands were purified ; ' for- getting this one little incident. When the point was men- tioned, however, the mistake was at once seen. People are too apt to trust to the spray as sufficient, and to speak of aseptic or Jjisterian surgery as treatment by the spray. This is a great and often fatal mistake. Of all the precautions required by Mr. Lister, that of purifying the air by means of a carbolic acid spray is the least necessary, for there are but few septic particles present in the atmosphere, and even though some of them fall on to a wound they may be rendered inert by washing the wound with carbolic lotion. It must always be remembered that Mr. Lister carried out aseptic treatment for years with great success without any spray ; and if at the present time he were compelled for any reason to give up some one precaution, he would at once throw aside the spray, as that one which is least

74 ASEPTIC SURGERY.

necessary, and which could be the most readily dispensed with. At the same time, the spray is an immense convenience in many cases, more especially in abscesses, empyemata, in stitching up wounds, &c. ; and it saves the necessity of applying a great deal of carbolic acid to wounds by irrigating them, with the con- sequent irritation and risk of carbolic acid poisoning.

To return to the errors which may arise in this part of the treatment. It may be that the spray is too near, and that thus the cloud is so narrow that the surgeon is constantly getting his hands or his instruments out of it, and forgetting to re- purify them. There are other disadvantages when the spray is too near. Thus it is very wetting, and the hands of the surgeon and the wound are unnecessarily irritated by the carbolic acid. If too near, the opaque spray also obscures the field of vision. On the other hand, where the spray is visible, it may be sufficiently trusted. Other sources of error are that instru- ments may be used which have never been purified, which have been only imperfectly purified, which have after their use lain about outside the spray or on blankets, &c. ; or it may be that the carbolic acid gets exhausted in the spray bottle, or that for some other reason the spray does not act properly.

What is to be done should any of these accidents occur ? Suppose that an impure instrument or finger be introduced into the wound, that wound must be at once thoroughly washed out with 1-40 carbolic lotion. This is a bad thing for the wound, because it irritates it, and may prevent lijealing by first intention ; or it may, by causing a much larger quantity of dis- charge than usual, so saturate the gauze dressing as to render it unable to prevent the spread of putrefaction inwards. There- fore it is better to use the spray, and to take all the precautions before mentioned. Should the spray stop, the wound must be washed out just as in the former case, and then, till the spray can be set agoing again, the wound is covered with a piece of rag soaked in carbolic lotion.

This piece of rag, called the guard, ought to be always present in the basin by the side of the surgeon, and when there is any indication that the spray is failing, or should it be advis- able to stop the spray for any reason, this is thrown over the wound for the time being. Should any time elapse before the

METHOD OF TYING VESSELS. 75

spray is again ready for use, this guard must be repeatedly moistened with carbolic acid lotion 1-40.

Where the wound is very large it may be protected during the operation either by having two sprays, or by covering up the part of the wound which is not being operated upon by a guard (see Fig. 24).

The arteries are ligatured with catgut. This catgut is generally employed of three different sizes. The largest is used only for large vessels or for stitches; the medium for medium-sized vessels, or for vessels in inflamed or dense tissues where considerable force is required to constrict the vessel, or for stitches ; the small or fine catgut is that ordinarily employed

^-^

Fig. 25a. Method op tying vessels in dense tissues.

(After MacCormac.)

for the smaller vessels. The vessel having been securely tied, the catgut is cut short and gives no more trouble. It is well to tie all the visible bleeding points, because a little oozing of blood may give trouble afterwards from tension. If the vessel be situated in dense tissue, so that a ligature cannot be applied around it, a needle carrying a double catgut thread should be passed througli the tissue and tied on each side of the vessel (see Figs. 25a and 2oh). The catgut should be taken direct from the trough containing carbolic oil, and should not be wetted in the lotion. Where the bleeding is from a tear in a large vein, and where it would be dangerous to ligature the

76

ASEPTIC SURGERY

vessel, I have seen the following method adopted by Mr. Lij^ter: In removing some cancerous glands from the axilla, a small vein was torn away from the axillary vein at their junction, making practically a longitudinal rent in the axillary vein. Taking a fine curved needle and the finest catgut, he stitched up the rent by the glover's suture. The patient recovered without the slightest bad symptom. There was no pain in the wound, nor swelling of the arm, &c. In another case, where the longitudinal sinus was injured in trephining the skull, the w^ound was plugged with catgut, and the patient recovered without any untoward symptom.

The drainage of an aseptic wound is the point next in im- portance to keeping the wound aseptic. For if the blood and

serum which collect in the in- terior of the wound within the first twenty-four or forty- eight hours do not get free exit, they give rise to tension, and tension gives rise to inflammation, and the latter, if allowed to go on long enough, to suppm'ation ; and thus the rapid healing of the TYING VESSELS IN DENSE TISSUES, wouud is prevented, though the (From Esmarch.) paticut is uot as a rulc subjcctcd

to any danger to life. To avoid these consequences Mr. Lister has paid very special attention to the drainage of wounds. There are two main ways in which this may be done— drainage through tubes, or drainage by capillarity. The former is the most universally applicable and the most certainly successful.

Drainage by means of tubes is that first used by Mr. Lister, and, as just stated, is the form of drainage which is most uni- versally applicable. The tubes generally employed are the india-rubber tubes introduced by Chassaignac, though of late the kind of rubber has been altered, that now used being red rubber, which contains no free sulphur. By the use of these red rubber tubes disagreeable smells and blackening of the X^rotective, which often occurred when the black tubes contain- ing free sulphur were employed, are avoided. These tubes have round holes cut in them at short intervals, the diameter of each

Fig. 25&. Another method of

DRAINAGE-TUBES.

77

hole being about one-third of the circumference of the tube. At the outer end the tubes are cut flush with the surface of the skin straight across if the tube goes directly downwards, or with varying degrees of obliquity according to the direction

Fig. 26. -Ordinary oblique-ended drainage-tube ready for use.

which the tube takes (Fig. 26). The tube must not project be- yond the surface, for if it does, its orifice gets compressed by the dressing, and the exit of fluid is prevented. To keep the drain- age tube from slipping in, two threads of carbolised silk are

Fig. 27.— Duainage-tubk with masses of gauze in the loops of

thread.

fastened into it at its orifice, and tied in a knot. This knot, held between the dressing and the skin, retnins the tube in ])08ition. In souk; cases, however as for cxiimple, in ompyeuia the tube niiglit sli]) in in s})ite of these thrends, and th(n-('f()re it is well to fill u|» (he ]oo])S witli strips of gauze soaked in the

78

ASEPTIC SURGERY.

carbolic lotion (Fig. 27). These absolutely prevent the tubes from slipping in. These tubes are always kept in a large vessel containing 1-20 carbolic acid solution, and are thus always ready for use. When a tube is altogether removed from a wound it is not thrown away, but is washed and put into the bottle with the other tubes, and used for another case. These tubes vary in size according to the size of the wound and the amount of discharge expected, and are arranged so as to drain the parts of the wound which form cavities or from which the greatest amount of discharge will come It is not necessary that their orifices be dependent, though it is of course better that they should be so. It is not essential, however, because the fluid, as it forms, wells out, and, not being putrid, that w^hich lies at the bottom of the drainage-tube does not cause irritation. In cases where the most dependent opening would be near sources of putrefaction, it is well to have the drainage-tube in another part of the wound, even though it be not so de- pendent. Thus in inguinal hernia the tube would no doubt be in the most depen- dent part if its orifice were close to the pubis, but as that would be much too near sources of putrefaction, such as the vagina and penis, the orifice of the tube ought to be at the outer angle of the wound (see Fig. 28). In a large wound it is well to have more than one tube; and it is better to have two smallish tubes in any case, rather than HERNIA, STITCHED, SHOWING THE OHC large ouB, bccausc ou the POSITION OF THE DRAINAGE-TUBE day after the operation one of

OUTER ANGLE OF THE ^|^ggg ^^j^^g ^^^ ^^ rCmOVCd

altogether ; whereas if a large one were pulled out in order to insert a smaller, there would be the gi-eatest difficulty in introducing either. No tube which one wishes to put back again should be removed till the third

Fig. 28.— Incision for inguinal

AT THE WOUND.

BRAIXAGE. 70

day, on account of the difficulty of returning it. By that time, however, it Hes in a channel in the blood clot or Ijonph, and slips back easily. Fig. 29 represents forceps introduced by Mr. Lister, and called ' sinus forceps,' which are of the greatest service in inserting drainage tubes. Generally on the third day half the tube is cut off, and it is reduced in length at subsequent dressings till it becomes no longer necessary. No exact rules can be given for shortening or leaving out the tube. This must simply be a matter of experience, guided by the amount of discharge and the tendency to accumulation or otherwise. Should tension occur, a larger and longer tube ought to be at once introduced.

A point which has always seemed to me of great importance in connection with the use of these tubes, and one which has apparently been overlooked, is the following. A tube is taken

Fig. 29.— Sikus forceps.

out of carbolic lotion at some distance from the spray, is earned through the air, and then directly introduced into the wound. I can hardly believe that when a large tube is taken out of the lotion there would be sufficient vapour of carbolic aoid in it to destroy any septic dust which might get into its interior, for a considerable mass of air must take the place of the fluid, and this amount of hospital air may often, as I have found by experiment, contain causes of putrefaction. Of course when passing through the spray this air may be displaced or purified, and also when introduced into the wound a consider- able amount of it would be forced out ; while at the same time there is a good deal of carbolic acid present, and purification in one way or another would probably occur. And further the purifying power of healthy living tissues, which will be after- wards demonstrated, must be taken into account. But in the case of a cavity, pm'ification in any of these ways may

80 ASEPTIC SURGERY.

not happen, and putrefaction may result. In a ease of incision into the knee-joint, which will be afterwards alluded to, in which fermentation and inflammation occurred, this seemed to me the most probable explanation. My suggestion there- fore is always to take the tubes out of the lotion in the spray, and then the air which enters them will be air previously acted on by the spray.

Drainage by capillarity was introduced by Mr. John Chiene, who was also the first to enunciate the principle of absorbable drains. For this purpose he uses catgut, and generally the

Fig. 30.— Catgut drain ready foe insertion.

finest threads. A skein of catgut, containing say twenty threads, is tied at its middle by a single thread of the same gut. One end of this thread is passed through a needle (Fig. 30), and by means of this the centre of the skein is stitched to the deepest part of the wound (Fig. 31). The skein is now broken up into bundles of five or six threads each. One bundle comes out at each angle of the incision, and the other bundles at inter- vals between the stitches (Fig. 32). More than one skein may be required in a large wound. This catgut becomes absorbed, and never requires to be removed. In five or six days the ends which hang out' drop off, and little granulating sores are formed which heal in a few days. In this method the serum escapes by capillarity, and by distributing the threads

DEAINAGE BY CAPILLARITY. 81

over various parts of the wound the true principle of drainage is carried out ; for, as pointed out by Mr. Chiene, in draining a field one does not have one large drain going from one end of the field to another ; on the contrary, the field is traversed by numerous small drains. And so in Chiene's method of draining v^rounds we have a number of small drains traversing the wound in several directions. In this method there is no trouble about pulling out the drain, and no necessity for changing the dressing simply to remove a tube ; the drain disappears of itself. It is well to leave the ends of the catgut outside the wound as long as possible, so as to get a siphon action, and care must be taken not to break up the bunches of catgut outside the wound, for the capillary action occurs in the intervals between the threads when they are closely ajjposed.

The objections urged against this method are, firstly, that in lai'ge wounds it is not sufficient, and that the catgut becomes a pulpy mass, and when in large quantity takes a long time to organise. Not only may it be insufficient at first, but it may become absorbed too soon before, indeed, a drain of some kind can be dispensed with.

Now these objections rest in great part on the fact that the drain is often improperly employed. If, for instance, it be not stitched to the deepest part of the wound, the catgut may slip and the deeper parts may not be drained ; and again, if a large bundle of it be used, coming out at one part of the wound only, it does become a pulpy mass, and takes a long time to organise. But this is not the method recommended by Mr. Chiene, for he says that only five or six threads ought to be brought out at each place. There is, however, no doubt that in some cases it is absorbed too quickly, and this was the real objection to the use of this method when we had only the catgut prepared by the old method, though even with it, if the gut was well prepared and old, the drainage was often very satisfactory. This difficulty will probably be overcome by the use of the chromic catgut recently introduced ; the only fear, indeed, will now be that the drain may last too long. Mr. Lister, however, thinks that if only the finest gut be used, according to Mr. Chiene's directions, the probability is that it

G

82 ASEPTIC SURGERY.

will be absorbed with sufficient rapidity. Of course, if neces- sary, the ends of the drain can be cut off, when it has served its purpose, below the level of the skin, and then, even though the internal part be not all absorbed, the wound can heal completely.

Catgut can only drain fluids such as blood or serum ; it cannot drain pus. It is, however, unsuitable in cases of chronic abscess, where we have only a serous discharge, because the catgut is absorbed long before a drain can be dispensed with.

Fig. ni.— Operation for stretching the sciatic nerve.

Catfrut drain stitolicd to the deepest part of the wound, beneath the gluteus maximus, and lirukon up into four separate bunclics.

If the wound is very large it is well to introduce tubes as well as catgut drains at first. The tubes may be removed in twenty-four hours.

Instead of catgut, horse-hair has been a good deal used. This is simply laid into the wound in the situation where it seems most required. It is diminished by degrees, threads being taken out at various intervals of time. It has an advan- tage over catgut in draining joints, for no part of the drain

DRAINAGE BY CATGUT AND HORSEHAIR.

83

remains in the interior of the joint, while portions of catgut do. Further, it is not absorbable.

But it has the same disadvantages as the drainage tubes, and it is not readily retained in the deeper parts of the wound. It is preferred by Mr. Lister to the catgut, but there can be no doubt that the catgut, when used strictly according to Mr. Chiene's directions, and of good quality, is a very efficient method of drainas^e.

It is easy to re-introduce a horse-hair drain if necessary by proceeding in the following manner : A sufficient quantity

Fig. 32.— The same wound stitched.

The h'jnclips of rntpiit cnminp out at intprvals between t)ie stitclies. (Tlie woiintl lias teen exapperated, and the thnails of ratjzut separated, in order to sliow the nietliod more clearly. 'I'lie thnads of catpiit onpht to lie in close apiiositioii, for it is tin: iiitervnls between the threads which act as raiiillary drains'.

being taken, the bundle is bent at its middle over a probe, and tied close to the probe by carbolised silk (Fig. 33). In this w^ay, the ])robe being withdrawn, a blunt compact end is oblained, which may be introduced into the wound with ease.

Of lute the princi])le of absorbable drains has been applied by Dr. Neuber of Kiel ' in his absorl)al)le drainag(! tubes.

' Ein AnihepHgchcr Daucm-rhand narh fir'dndlichrr Jilutstillnii;/. Von LangenhccJt'x Archiv, Bd. xxiv. Heft. 2.

a 9.

84 ASEPTIC SURGERY.

These are tubes drilled in long bones, and then decalcified and carbolised. Holes are afterwards cut in the sides, and they are used like ordinary india-rubber tubes. These tubes are said to answer very well, though they are sometimes absorbed too soon, and sometimes last too long. They sometimes get soft and collapse about the third or fourth day, and thus, though not absorbed, become useless as a drain.

Dr. INIacEwen ^ has lately somewhat modified Neuber's tubes. He uses chicken-bones, which are already hollow, and decalcifies them. ' The method of preparation is as folloAvs : The tibia? and femora are scraped and steeped in hydrochloric acid and water (1 to 5) until they are soft. Their articular extremities are then snipped off with a pair of scissors ; the cndosteum is

Fig. 33. Method of preparing a horse-hair drain for re-introduction.

raised at one end and pushed through to the other extremity, along with its contents. They are then re-introduced into a fresh solution of the same strength until they are rendered a little more pliable and softer than Avhat is ultimately required (as they afterwards harden a little by steeping in the carbolised solution). When thus prepared they are placed in a solution of carbolic acid in glycerine 1-10. They may be used at the end of a fortnight from the time of introduction into the glycerine solution. Holes may be drilled in them with a punch, or clipped out with scissors.' These tubes are threaded with horse-hair before being introduced into the tissues. This hair helps to maintain the calibre of the tube during the first few days, and also itself acts by capillarity.

' British Medical Journal, Feb. 5, 1881.

BUTTON STITCHES.

85

The average duration of j\IacE\ven's tubes in the tissues was something over eight days. If, however, a tube is likely to be required for a longer time, it can be obtained by steeping the decalcified tubes in a chromicised instead of a carbolised solution. These resist the action of the tissues for two or three weeks.

The accurate stitching of the edges of the wound is another feature in aseptic surgery. In operating aseptically the same care need not be taken to remove as little skin as possible as is necessary in wounds treated by other methods where swelling and inflammation of the edges are expected. One may take away a wide sweep of skin, such as would seem to render hopeless any attempt to bring the edges of the wound into apposition ; and yet if the edges can only be apposed, and if

A c

Fig. 34. Lead buttons for deep stitches.

A, The present form, describerl in tlie text. B, Form of button deviscrl by Dr. Ogilvie Will (seen in section). C, The old form, where the wire was fastened by passing it beneatli the button.

the wound remains aseptic, union by first intention may be expected along the whole line.

Button stitches are employed to relax the edges of the wound, and thus to leave the cutaneous margins free from the irritation which must occur if they are tightly drawn together. These consist of flat pieces of lead cut of an oval form and of various sizes, perforated in the centre by a hole through which silver wire is passed, and provided Avith two lateral wings round which the wire is twisted (Fig. 34). (There are various forms of button suture, but all act on the same principle.) These are a[)})lied some distance on each side of the edge of the wound, and connected by strong silver wire drawn tight enough to permit the edges of the wound to come pretty easily together. The number used varies according to the amount of tension.

8(>

ASEPTIC SURGERY.

In order to bring the edges of the wound into actual contact, two sets of stitches are employed : silver wire stitches, which take a good hold of the tissues and are placed at regular inter- vals, termed stitches of relaxation ; and in the intervals between these, in order to have the cutaneous margins accurately applied to each other, numerous stitches of coaptation, consisting of carbolised silk, horse-hair, or catgut are inserted (Fig. 35). The speedy healing which occurs when the edges of the wound are accurately brought in contact, while they are at the same time, by the button stitches and the stitches of relaxation,

Fig. 35. Wound after removal oi'^ mamma and axillary glands,

STITCHED.

To show tlie tliree kinds of stitches. Tlip button .stitchrs will lie at onee recognised ; the tliick stitches, of which three arc represented, are the stitches of relaxation ; and the remainder are tlie stitches of coaptation.

freed from any tension, rewards the surgeon for the time spent in inserting a large number of these stitches of coapta- tion.

In taking out these stitches it is best to follow a reverse order to that of insertion. The first to be removed are the stitches of coaptation, while the stitches of relaxation are pro- bably cut on the same day. Do not be in a hurry to remove the stitches where there was much tension in bringing the edges of the wound together. A week or ten days is time enough.

Should the wound gape, strapping may be employed, even under an antiseptic dressing. To render the stra])ping aseptic, it is immersed in warm carbolic lotion (one part of 1-20 and an equal part of boiling water) before being applied. This both

BEESSINGS. 87

renders it aseptic and also takes the place of the hot- water can for heating the strapping.

Having proceeded thus far in the aseptic operation having tied the vessels, aiTanged the drainage, and brought the edges of the skin well together— we must now apply a dressing which shall prevent the occurrence of putrefaction till the case is again seen.

In applying a dressing we must in the first place be careful to make it as little irritating as possible to the young epithelium along the Hne of incision. The dressing employed is the car- bolic gauze ; and, to prevent the irritation of the healing edge of the wound by the carbolic acid, a piece of protective is inter- posed between the gauze and the wound. This protective is cut a little larger than the wound, and it is well to cover the buttons with a little bit also, in order to prevent the threads of the gauze from becoming entangled in them. This protective need not extend over the orifice of the drainage tube, as its essential object is to protect the healing part from the irritation of the carbolic acid. The protective is also of use in preventing the dressing from sticking to the Avound, and in preventing the formation of scabs, and the consequent possible retention of the discharge.

An eiTor which is frequently made is to put on too large a piece of protective. There is nothing antiseptic in its substance, and it protects the discharge beneath it from the action of the carbolic acid. Therefore if at any part it projects beyond or comes close to the edge of the dressing, it allows the causes of putre- faction to spread inwards beneath it, and prevents the carbolic acid from acting on this putrefying discharge. It is therefore a very good rule, having covered the woimd with sufficient pro- tective, to look on this protective as a wound, and to be as careful in having the gauze dressing overlap it in all du-ections as if it itself were the wounded surface. Where there is very little space for overlapping, as in inguinal hernia, no protective ought to be applied. It is better to have somewhat slower healing than to have putrefaction spre-ad into the wound. As men- tioned before, this protective is di))i)ed in carbolic lotion 1-40 befoi'e being applied.

Outside the protective a piece of gauze wet in the carbolic

88 ASEPTIC SUliGEliT.

lotion 1—40 is applied so as to overlap the protective in all directions. The reason for this is that dry gauze is apt to receive dust on its surface before being used, while at the ordinary temperature of the atmosphere but little carbolic acid is given off from the gauze, certainly not enough to destroy immediately the activity of the septic particles in the dust. But if the piece of gauze applied next to the protective be moistened in the 1— iO solution, this dust is at once deprived of septic energy, and we apply over the wound a layer of pure and powerfully antiseptic material.

Fig. 36.— Excision of the hip-joint.

Wound stitclied ; ])rotective anil deep di-essing applied.

The piece of wet gauze and the protective go by the name of the deep dressing. This deep dressing may in some cases, and more especially where catgut stitches and catgut drains are used, be left for several days undisturbed. In this way the wound is not irritated by the application of carbolic acid to it every time the dressing is changed. If the deep dressing be thus left on, it must be remembered that the deep piece of gauze loses all its carbolic acid very soon, and that therefore it must be treated as a wound ^.e., in renewing the dressing this deep part must be overlapped in all directions by a piece of wet gauze, and that again by a dressing of suitable size.

DEEP DRESSING. ^9

In some cases it may be desirable to fix down the deep dressing with a piece of gauze bandage. If it be intended to leave on this deep dressing for some time it is well, before applying it, to rub the neighbourhood of the wound with the salicylic cream mentioned before. It sometimes happens that when a dressing is left on for many days together, the discharge becomes somewhat irritating, and the skin around the wound becomes excoriated. This is generally entirely prevented by the use of salicylic cream.

Having arranged the deep dressing in a suitable manner, any hollows which exist in the neighbourhood of the wound are filled up with carbolic gauze, and special masses of this material are placed where the greatest amount of discharge is expected. Outside this a large gauze dressing, made as before described, is applied. The size of this dressing varies accord- ing to the amount of discharge expected, but in all cases it must extend well beyond the deep dressing in all directions. Some special examples will be mentioned presently.

This dressing is fixed on with a suitable bandage. The gauze bandage is preferable to an ordinary bandage under certain circumstances. It is especially convenient in bandaging a stump next the skin to prevent retraction of the flaps, and also for fixing down the deep dressing. It also increases the amount of antiseptic material outside the macintosh if there happens to be a hole in it. But for ordinary use in fixing on dressings very light and cheap bandages may be made from the ordinary thin muslin which is used as a guard. They do not stick to the skin as the gauze bandage is apt to do.

The dressing is pinned round its edge to the bandage. Care must be taken not to put pins through the macintosh at any part except at its edge. Pinholes through the centre of the macintosh simply defeat its object by permitting the discharge to come directly through the dressing. The object of the macintosh is to make the discharge travel through a large extent of the gauze, and thus the same result is obtained as if a mass of gauze were applied over the wound, of the same thickness as the distance from the centre of the macintosh to its edge. If therefore there be a pinhole near the centre of the macintosh, the object of the latter is seriously interfered

90

ASEPTIC SURGERY

with. Accordingly, it is always the duty of the i)ersoii who makes the dressings to examine the macintosh with the view of detecting any holes in it.

If the dressing is to be used as soon as it is made up, it is well to sponge the surface of the macintosh with 1-20 carbolic lotion before inserting it. The same piece of macintosh may be used for a whole case, or for more than one so long, in fact, as it does not become worn into holes. Two pieces of macin- tosh are generally provided for each case, and a dressing is always made immediately after the case has been dressed, and is ready for application at any time.

Fio. 37.— Dressing in a case of psoas abscess opened above Poupakt's ligament.

To show tlie an-angement of tlie elastic bandage along the margins of the dressing.

It might happen that, in the movements of the patient, the edge of the dressing might become separated from the skin, and air pass into the space thus formed. To prevent this, the German surgeons as a rule pack in salicylic jute or wo