The medical history of the eighteenth century affords but a meagre result, notwithstanding the brilliant talents and indefatigable⁶ industry of the famous men who devoted⁷ their energies to the healing art. Their great aim was to create systems of medicine which should be philosophical⁸ and complete.

 

It is not only in what is strictly⁹ the art of healing that the members of the medical profession have ever been amongst the greatest benefactors¹⁰ of the world, but in what are known as the accessory sciences many of the most distinguished¹¹, enlightened, and self-sacrificing of the heroes of science have been affiliated¹² to the profession of medicine. Not only the heroes, but the martyrs¹³ of medicine, crowd the scientific calendar. The seventeenth and eighteenth centuries were fertile in the efforts to apply the results of discoveries in the physical sciences to the relief of human suffering. If these efforts were but partially¹⁴ successful, so far as medicine—considered apart from surgery—was concerned, it was not in consequence of less industry in that department, but because speculation¹⁵ and theorising about the causes of disease monopolised the attention which, if devoted to observation of facts, would have been fertile in result. Schools, Systems, and Sects¹⁷ were the chief product of the medical activity of the eighteenth century. Although not perhaps of much direct benefit to medicine, indirectly¹⁸ the study of the sciences accessory to it must have been of considerable benefit as an educational factor in the training of the intellect of physicians.

 

The Great Schools of Medical Theory.

 

Whewell, in his History of Scientific Ideas,990 classifies the successive biological hypotheses under the heads: (1) The Mystical School;419 (2) The Iatro-Chemical School; (3) The Iatro-Mathematical School; (4) The Vital-Fluid School; (5) The Psychical¹⁹ School.

 

The Mystical School found its most distinguished representative in Paracelsus; it derived²⁰ its doctrine²¹ of the Macrocosm and the Microcosm from the Neoplatonists, and was largely imbued²² with alchemy and magic, the doctrines²³ of the Cabala and the fanciful interpretations²⁴ of the Bible. Later Paracelsists, Rosicrucians, and other speculators of the same character, such as Sir Kenelm Digby, brought the Mystical School of Medicine down to the seventeenth century. Our modern Theosophists are striving to restore much of the mystical teaching of Paracelsus and his followers²⁶. Again we meet the “astral bodies,” “the elementary spirits,” the cabalistic interpretations of the Bible, and the astrological absurdities²⁷ of a pre-scientific period.

 

The Iatro-Chemical School really arose from Paracelsus, who amongst many absurdities held much important truth. Sprengel indicates Libavius of Saxony as the person who first cultivated chemistry apart from theosophy, and he names Angelus Sala as his successor. Lemery, in the middle of the seventeenth century, began to reform pharmaceutical²⁸ chemistry. After Paracelsus chemistry became an indispensable study to every physician. Our word tartar, the scale which forms on the teeth, is of Paracelsian origin. He taught that the basis of all diseases was a thickening of the juices and the formation of earthy matter, which he called Tartarus, because it burns like the fire of hell. After Paracelsus we have Van Helmont, a true chemical discoverer who sought in chemistry a theory of disease of which his doctrine of fermentation in the body holds an important place. Next we have Sylvius, with his doctrine of the opposition³⁰ of acid and alkali. Digestion³¹ he considered a process of fermentation or effervescence of the acid of the saliva³² and pancreatic juice with the alkali of the gall³³. When either the acid or the alkali predominated, disease was supposed to follow. The human body was regarded as a laboratory, the stomach as a sort of test tube. Boyle made objections to the doctrines of this school, and Herman Conring taught that the proper place of chemistry was not in physiology³⁴ and pathology, but in pharmacy³⁵.

 

Viridet of Geneva endeavoured to prove that the fluids of the body are either acid or alkaline by experiment. Raimond Vieussens declared that he had discovered an acid in the blood and a ferment²⁹ in the stomach. Hecquet opposed him, and said that digestion was not a process of fermentation, but of trituration. Pitcairn in England, Bohn and Hoffman in Germany, and Boerhaave in Holland opposed the iatro-chemists, and proved by observation that digestion is not fermentation, and that the acid and alkali theories of disease supported by Sylvius were420 false. By the influence and authority of these eminent³⁷ physicians, the reign³⁸ of the chemical school of physiology was overturned. The great fault of the iatro-chemists was their neglect of the effect of the solids of the animal body; they assimilated the work of the physician, as Whewell says, to that of the vintner or the brewer³⁹.

 

The Iatro-Mathematical or Mechanical School attacked, defeated, and superseded⁴⁰ the iatro-chemists. According to this sect¹⁶, the human body is a mere⁴¹ machine. Whewell explains that the Mechanical Physiologists came into existence in consequence of the splendid results obtained by the schools of Galileo and Newton. It was not so much the exposure of the weaknesses of the chemical physiology as the effects produced upon the world by the explanation of so many of the phenomena⁴² of the external universe by the men who had revolutionized astronomy by their discoveries; it was naturally hoped that that which served to explain the great world of matter might also elucidate⁴³ the little world of man. Whewell divides the school into two parts—the Italian and the Cartesio-Newtonian sect. The Italian calculated and analysed the properties of the animal body which are undoubtedly⁴⁴ purely⁴⁵ mechanical, the Cartesio-Newtonians went much further than this and introduced many baseless hypotheses. The Italians occupied themselves with such calculations as the force of muscles and the hydraulics of the animal fluid. Borelli was the first great investigator⁴⁷ on these lines; his work De Motu Animalium (Rome, 1680), treats of the forces and action of the bones and muscles. John and Daniel Bernouelli and Henry Pemberton pursued the same line of research. The principles of hydrostatics were brought to bear on the questions of the blood pressure and the breath. Keill endeavoured to estimate the velocity⁴⁸ of the blood. The other school occupied itself with the corpuscular hypothesis in physiology. The organs were considered as a species of sieves⁴⁹. Both Newton and Descartes sought to explain physiology on a theory of round particles passing through cylindrical⁵⁰ tubes, pyramidal ones through pores of a triangular⁵¹ shape, cubical through square openings. The diameter and curves of the different vessels⁵² formed subjects of calculations, and Bellini, Donzellini, and Guglielmini in Italy, Perrault and Dodart in France, Cole, Keill, and Jurin in England, devoted themselves to their study.991

 

The investigation⁵³ of the size and shape of the particles of the fluids, and the diameter and form of the invisible vessels, formed a large part of the physiology of the beginning of the eighteenth century. Cheyne thought that fevers of the acute sort arise from glandular⁵⁴ obstruction;421 and Mead⁵⁵, the royal physician and friend of Newton, explained the action of poisons on mechanical principles. The error of this school, as Whewell explains, lay in considering the animal frame as a lifeless compound of canals, cords and levers; the physicians, to its adherents⁵⁶, were merely hydraulic⁴⁶ engineers. Some iatro-mathematicians⁵⁸ were, in fact, at the same time teachers both of engineering and medicine.992

 

The Vital-Fluid School. The mechanical explanation of the motions of the animal body may satisfy some observers up to a certain point; there, however, they must confess their theory fails them. How does motion originate in the living frame? Friedrich Hoffman, of Halle (b. 1660), assumed a principle, material, yet of a higher kind than the adherents of the mechanical sect were inclined to recognise. This principle is exceedingly subtle, and is endued⁵⁹ with great energy. It is the ether diffused⁶⁰ through all nature, and which has its seat in the brain of animals and acts upon the body through the nerves. This vital fluid operates by laws which at one time were explained on the principles of a higher mechanics, of which we know little, and at another on metaphysical grounds, of which we know less. Naturally the discoveries connected with electricity imported a new element into these speculations⁶¹. The vital principle was then held to be a modification⁶² of the electric fluid. John Hunter discerned it in the blood. Cuvier believed the vital fluid to be nervous. The objections to the doctrine of a vital fluid “as one uniform material agent pervading⁶³ the organic frame,” are many. If the vital principle be the same in every part of the body, how does it happen that the secretions⁶⁴ are all so different? How does the blood under the same influence furnish all the different fluids produced by the glands⁶⁶? How is it the liver secretes⁶⁷ bile, the kidneys their peculiar⁶⁸ fluid, the lachrymal gland³⁶ the tears? The hypothesis of a vital fluid really explains nothing.

 

The Psychical School held the doctrine of an immaterial vital principle. This is at least as old as Aristotle,993 who attributes the cause of motion to the soul. According to that philosopher the soul has different parts: the nutritive or vegetative, the sensitive, and the rational. Stahl, the great discoverer in chemistry, opposed the physiological⁶⁹ theories of Hoffman, and declared that there is something in living bodies which cannot be accounted for by mechanics or chemistry. “All motion,” according to him, “is a spiritual act.” Nutrition and secretion⁶⁵ belong to the operations of the soul; but he overlooked the fact that these are not peculiar to animals, but are characteristics of vegetables, which have no soul. Cheyne and Mead, Pater422field and Whytt in England inclined to Stahl’s views. Boissier de Sauvages defended them in France. Hoffman and afterwards Haller opposed them, the latter inventing the theory of Irritability⁷⁰.

 

Boerhaave (1668-1738), professor of medicine at Leyden, was a man of varied⁷¹ and profound erudition, conversant⁷² with the teaching of the ancient philosophers and the Greek and Arabian physicians; he was in addition fully⁷³ conversant with all the discoveries connected with the healing art down to his own time. Beyond this he was a natural philosopher, chemist, botanist⁷⁴, and anatomist, and an indefatigable experimentalist. In teaching medicine he simplified its study as much as possible by rejecting the absurd and useless speculations which encumbered⁷⁵ it, and putting in their place the facts which he believed his own experience and observation had enabled him to ascertain⁷⁶. He published his system of medicine in two volumes, one entitled the Instructions or Theory and the other the Aphorisms⁷⁷ or Practice of Medicine. “These short treatises⁷⁸,” says Dr. Thomson,994 “which gave to medicine a more systematic⁸⁰ form than it had previously⁸¹ exhibited, are remarkable⁸² for brevity, perspicuity⁸³, and elegance⁸⁴ of style, for great condensation⁸⁵ of ideas, and for the number of important facts which they contain relative to the healthy and diseased states of the human economy.” The genius of Boerhaave raised the medical school of Leyden to the highest distinction. Princes in all countries sent him pupils; Peter the Great took lessons in medicine from him, and so great was his reputation that when a Chinese mandarin⁸⁶ directed a letter to him, “To the illustrious Boerhaave, physician in Europe,” it was duly delivered. He held the study of Mind to form an important part of physiology. He taught that the change produced upon the extremity⁸⁷ of the sentient⁸⁸ nerve must be transmitted by the nerve to the brain before sensation can be produced. He considered the nerves to be hollow undulatory canals. He also held that each of the senses has its distinct seat in the common sensory⁸⁹ or brain. His lectures on the mental faculties⁹⁰ are full of varied and curious information. Considering the human body as a combination of various machines arranged in one harmonious⁹¹ whole, he endeavoured to explain its phenomena in health and disease on the principles of natural philosophy and chemistry to the almost entire exclusion⁹² of vital forces, which, however, he did not reject. He denied that all medical phenomena are to be explained upon mechanical principles. He lamented⁹³ that “physiological subjects are usually handled either by mathematicians unskilful in anatomy, or by anatomists who are not versed⁹⁵ in mathematics.” Yet his system of physiology embraced423 but a poor conception of the mystery of life. He says, “Let anatomy faithfully describe the parts and structure of the body; let the mechanician apply his particular science to the solids; let hydrostatics explain the laws of fluids in general, and hydraulics their actions, as they move through given canals; and lastly, let the chemist add to all these whatever his art, when fairly and carefully applied⁹⁶, has been able to discover; and then, if I am not mistaken, we shall have a complete account of medical physiology.”

 

It is to Boerhaave that we owe the peculiar chemical idea of affinity⁹⁷, that mutual⁹⁸ virtue⁹⁹ by which one chemical substance loves, unites with, and holds the other (amat, unit, retinet). He called it love. “We are here to imagine, not mechanical action, not violent impulse, not antipathy¹⁰⁰, but love, at least if love be the desire of uniting.” It is to Boerhaave, therefore, we are indebted for a view of chemical affinity which enables us to comprehend all chemical changes.995

 

The idea of affinity as marriage naturally leads to analysis as divorce. Thus affinity, imperfectly understood before the time of Boerhaave, made analysis possible. One of the first to express this conviction was Dr. Mayow, who published his Medico-Physical Tracts¹⁰¹ in 1674. He shows how an acid and an alkali lose their properties by combination, a new substance being formed not at all resembling either of the ingredients. He explains that, “although these salts thus mixed appear to be destroyed, it is still possible for them to be separated from each other, with their power still entire.”996

 

George Ernest Stahl (1660-1734), chemist, was professor of medicine at Halle (1694) and physician to the King of Prussia (1716). He opposed materialism¹⁰², and substituted “animism,” explaining the symptoms of disease as efforts of the soul to get rid of morbid¹⁰³ influences. Stahl’s “anima” corresponds to Sydenham’s “nature” in a measure, and has some relationship to the Archeus of Paracelsus and Van Helmont. Stahl was the author of the “phlogiston” theory in chemistry, which in its time has had important influence on medicine. Phlogiston was a substance which he supposed to exist in all combustible¹⁰⁴ matters, and the escape of this principle from any compound was held to account for the phenomenon of fire. According to Stahl, diseases arise from the direct action of noxious¹⁰⁵ powers upon the body; and from the reaction of the system itself endeavouring to oppose and counteract¹⁰⁶ the effects of the noxious powers, and so preserve and repair itself.997 He did not consider diseases, therefore, pernicious in them424selves, though he admitted that they might become so from mistakes made by the soul in the choice, or proportion of the motions excited to remove them, or the time when these efforts are made. Death, according to this theory, is due to the indolence of the soul, leading it to desist from its vital motions, and refusing to continue longer the struggle against the derangements of the body.998 Here we have the “expectant treatment” so much in vogue¹⁰⁷ with many medical men. “Trusting to the constant attention and wisdom of nature,” they administered inert¹⁰⁸ medicines as placebos¹⁰⁹, while they left to nature the cure of the disease. But they neglected the use of invaluable¹¹⁰ remedies such as opium¹¹¹ and Peruvian bark, for which error it must be admitted they atoned¹¹² by discountenancing bleeding, vomiting¹¹³, etc.999 Stahl’s remedies were chiefly of the class known as “Antiphlogistic,” or antefebrile.

 

De Sauvages (1706-1767), the French physicist¹¹⁴, was a disciple¹¹⁵ of Stahl, and adopted his theory of soul as the cause of the mechanical action of the body. He invented a system of classifying diseases under the title of Nosologia Methodica, founded on the principles of natural history.

 

Friedrich Hoffman (1660-1742) was a fellow-student with Stahl at Jena. He was the author of a system of medicine in some respects original. He distinguished in the human economy three principal agents: Nature, or the Organic Body; the Sentient Soul; and the Rational Soul; corresponding to the classification of the Scripture¹¹⁶ of body, soul, and spirit—a classification which originated doubtless in Indian philosophy. Hoffman did not admit with Stahl that the organic functions of the human body depend on the agency of an intelligent soul or any immaterial agent whatsoever¹¹⁷, but are merely mechanical and chemical properties of the elements which compose our bodies. The functions most essential to life he considered to be the circulatory, secretory¹¹⁸, and excretory motions, and these seemed to him to depend upon the dilating¹¹⁹ and contracting powers of the muscular fibres of the vascular¹²⁰ system. These powers then he held to be the cause of the organic functions which depend on the animal spirits, an ethereal fluid contained in the nerves and the blood.1000

 

Hoffman first made known the virtues¹²¹ of the Seidlitz waters; he also invented a nostrum¹²² which was popular for a long time, and called425 “Hoffman’s Anodyne¹²³ Liquor.”

 

Physicians.

 

Archibald Pitcairn, M.D. (1652-1713), was a famous physician of Edinburgh. In 1692 he occupied a professor’s chair at Leyden with great distinction. Among his pupils were Mead and Boerhaave, who both attributed much of their skill to his tuition. On his return to Edinburgh he greatly interested himself in improving the teaching of anatomy. He begged the Town Council to permit the dissection¹²⁴ of the bodies of paupers¹²⁵; and though the chief surgeons of the place did all they could to oppose his efforts, they were successful, and Pitcairn had the credit of laying the foundation of the great Edinburgh school of medicine. He insisted on the strict adherence¹²⁶ to Bacon’s method of attending to facts of experience and observation. “Nothing,” he said, “more hinders physic from being improved than the curiosity of searching into the natural causes of the effects of medicines. The business of men is to know the virtues of medicines; but to inquire whence they have that power is a superfluous¹²⁷ amusement, since nature lies concealed¹²⁹. A physician ought therefore to apply himself to discover by experience the effects of medicines and diseases, and reduce his observations into maxims¹³¹, and not needlessly fatigue¹³² himself by inquiring into their causes, which are neither possible nor necessary to be known. If all physicians would act thus, we should not see physic divided into so many sects.” In his Dissertations¹³³ (1701) he discusses the application of geometry to physic, the circulation of the blood, the cure of fevers by purgation, and the effects of acids and alkalis in medicine. A learned and skilful⁹⁴ physician, an accomplished¹³⁴ mathematician⁵⁷, and a thorough classical scholar, he was not discreet¹³⁵ in his political utterances¹³⁶. His library was purchased by Peter the Great of Russia.

 

John Radcliffe, M.D. (1650-1714), was famous for “his magnificent regard for the advancement¹³⁷ of learning and science.” The Radcliffe infirmary and observatory¹³⁸ at Oxford¹³⁹ were built from funds bequeathed by him.

 

Sir Hans Sloane, M.D. (1660-1753), was a physician whose noble museum and library were the foundation of the British Museum.

 

Sir Richard Blackmore, M.D. (1650-1729), wrote on inoculation for small-pox, on consumption, gout, rheumatism¹⁴⁰, scrofula, diabetes¹⁴¹, jaundice, etc.

 

Walter Needham, M.D. (died 1691), made important investigations¹⁴² in the anatomy of the f?tus, and the changes of the pregnant uterus.

 

Clopton Havers, M.D. (died 1702), was the author of a standard426 work on the bones, certain canals of which were called after him Haversian canals.

 

James Douglas, M.D. (1675-1742), was an excellent anatomist, who was one of the first to demonstrate from anatomy that the high operation for stone might be safely performed. He was a skilful accoucheur, an accomplished botanist, and a man of letters. Pope mentions him in the Dunciad, and in a note describes him as a physician of great learning and no less taste. He wrote several works, the most famous of which is Myographi? Comparat? Specimen¹⁴³; or a comparative description of all the muscles in a man and in a quadruped; added is an account of the muscles peculiar to a woman. London, 1707.

 

William Cullen, M.D. (1710-1790), was the first professor in Great Britain to deliver his lectures in the English language.1001 He was appointed lecturer on chemistry at Glasgow University in 1746, and in 1751 was chosen regius professor of medicine. In 1756 he became professor of chemistry in the University of Edinburgh; in 1760 he was made lecturer on materia medica. Dr. Cullen earned great distinction as a lecturer on medicine; he opposed the teaching of Boerhaave and the principles of the humoral pathology, founding his own teaching on that of Hoffman. His system was to a great extent based on the new physiological doctrine of irritability as taught by Haller.

 

He attached great importance to nervous action in the induction¹⁴⁴ of disease, considering even gout as a neurosis.

 

His First Lines of the Practice of Physic was long exceedingly popular, but his fame as a medical writer rests on his Nosology, or Classification of Diseases. In all his labours Dr. Cullen aimed at the practical rather than the theoretical. “My business is not,” he remarks,1002 “so much to explain how this and that happens, as to examine what is truly matter of fact.” “My anxiety is not so much to find out how it happens as to find out what happens.” Cullen invented no ingenious hypothesis, rather he new-modelled the whole practice of medicine; “he defined and arranged diseases with an unrivalled accuracy, and reduced their treatment to a simplicity¹⁴⁵ formerly¹⁴⁶ unknown.”1003

 

James Gregory, M.D. (1758-1822), exercised the greatest influence on the progress of medicine in England. As the successor of Cullen, and as the author of the famous Conspectus Medicin? Theoretic?, the name of Gregory, borne by many ornaments¹⁴⁷ of British science, became still more distinguished.

 

Sir Gilbert Blane, M.D. (born 1747), rendered important medical services to the State by his researches on the diseases incident to sea427men. He banished¹⁴⁸ scurvy¹⁴⁹ from the fleet by his arrangements for provisioning ships on foreign stations, particularly by making lemon juice a regular ingredient of diet.

 

Sir William Watson, M.D. (1715-1787), was a devoted botanist and student of electricity. His electrical researches raised him to a position of European fame. He was the first in England who succeeded in igniting spirit of wine by electricity; he was the first to note the different colour of the spark, as drawn¹⁵⁰ from different bodies; and his researches in the power and accumulation of electricity, the nature of its conductors, etc., qualified¹⁵¹ him to take part in the experiments carried out in 1747 and 1748, by which the “electric current was extended to four miles in order to prove the velocity of its transmission.”1004 The doctor’s house in Aldersgate Street was long the resort of the most distinguished men of science in Europe. He was not less the benign¹⁵² and generous friend to the poor and suffering, than the ardent¹⁵³ investigator of the secrets of Nature. His work Experiments and Observations on Electricity is quite a remarkable production considering the age in which it was published (1768).

 

Robert Willan, M.D. (1757-1812), was the founder¹⁵⁴ of the science of skin diseases in England. His attention was directed in 1784 to the elementary forms of eruption¹⁵⁵, and on this basis he erected¹⁵⁶ his magnum opus, The Description and Treatment of Cutaneous Diseases (1798).

 

John Brown (1735-1788), was a systematizer of medicine, whose popularity was even continental¹⁵⁷. He endeavoured to explain the processes of life and disease and the principles of cure upon one simple idea, the property of “excitability.” The “exciting powers” are the external forces, and the functions of the body are stimulants¹⁵⁸, so that “the whole phenomena of life, health as well as disease, consist in stimulus¹⁵⁹ and nothing else.” Diseases he divided as sthenic, attended with preternatural excitement, and asthenic, characterized by debility.

 

Ninety-seven per cent. of all diseases, he declared, require a “stimulating treatment.” One good result of this theory was that it introduced a milder treatment of disease than the bleeding and purging¹⁶⁰ doctors of his time advocated. The theory was called the Brunonian, and received greater attention in Italy than in England.

 

John Morgan, M.D. (1736-1789), was born in Philadelphia. He wrote an essay on his graduation at Edinburgh (1763), wherein “he maintained that pus is a secretion from the vessels, and in this view anticipated John Hunter.”1005

 

428

 

Robert James, M.D. (1703-1776), was the inventor of the celebrated¹⁶¹ fever-powder which bears his name.

 

Francis de Valingen, M.D. (1725-1805), was a Swiss who practised in London. He was the first to suggest the employment of chloride of arsenic¹⁶² in practice. His preparation was admitted into the London Pharmacop?ia.

 

Erasmus Darwin (1701-1802), a physician of Lichfield, was a true poet of science. His fame rests on the Botanic Garden, in which he describes the Loves of the Plants according to the Linn?an system. His most important scientific work is his Zoonomia, a pathological work, and a treatise⁷⁹ on generation, in which he anticipated the views of Lamarck. He asks: “Would it be too bold to imagine that in the great length of time since the earth began to exist, perhaps millions of ages before the commencement of the history of mankind, would it be too bold to imagine that all warm-blooded animals have arisen from one living filament¹⁶³, which the Great First Cause endued with animality, with the power of acquiring new parts, attended with new propensities¹⁶⁴, directed by irritations¹⁶⁵, sensations, volitions, and associations, and thus possessing the faculty¹⁶⁷ of continuing to improve by its own inherent activity, and of delivering down these improvements by generation to its posterity¹⁶⁸, world without end!” He believed that plants possess sensation and volition¹⁶⁶.

 

Edward Spry, M.D. (lived in 1756). At the fire of Eddystone lighthouse an old man was injured by the fall of a quantity of molten lead upon him. Dying of his injuries in twelve days, he was examined by Dr. Spry, who stated that he found in the stomach a lump of lead three and three-quarter inches long by one and a half in breadth. As no surgeon would believe this story, Dr. Spry performed a number of experiments upon animals by pouring molten lead down their throats, with the result that at the Royal Society, Dr. Huxham, in his letter to Sir William Watson, “testified to his own belief in Mr. Spry’s veracity¹⁶⁹.”1006

 

John Coakley Lettsom, M.D. (1744-1815), was a learned and amiable¹⁷⁰ philanthropist, who published several important medical and scientific works. His Reflections on the Treatment and Cure of Fevers and The Natural History of the Tea Tree appeared in 1772. He wrote the following lines:—

 

429

 

“When patients sick to me apply,

I physics, bleeds, and sweats ’em.

Sometimes they live, sometimes they die:

What’s that to me? I. Lettsom.”

He gave away immense sums in charity, he was not so unfeeling as his verse would make him appear.

 

William Stark¹⁷¹ (1742-1770) was the earliest writer who distinguished between tuberculosis¹⁷² and scrofula.

 

Jean Astruc (1684-1766), professor at Montpellier, the oldest of the celebrated French obstetricians, was the author of a work on the diseases of women from the pathological point of view.

 

Johann E. Wichmann (1740-1802), a scientific physician of Hanover, in 1786 explained the cause of itch¹⁷³ as due to the itch-mite passing from one individual to another. He experimented upon himself. Bonomo had, however, discovered the insect in the itch pustules in 1687.

 

Wichmann suggested the contagiousness¹⁷⁴ of consumption, whooping¹⁷⁵ cough, diarrh?a, and several other complaints.

 

J. P. Frank (1745-1821) was “the founder of medical police as a distinct department of science.”1007

 

Hospitals.

 

The condition of the hospitals for the sick in the eighteenth century was scandalous almost beyond belief. Thus, in the H?tel Dieu of Paris, the mortality at one time was 220 per 1,000; a state of affairs which, however, we surpassed in the present century, when in the British hospitals at Scutari the mortality reached between 400 and 500 per 1,000. In both cases this was due to overcrowding. At the H?tel Dieu two or three small-pox cases, or several surgical¹⁷⁶ cases, or sometimes even four lying-in women would be packed into one bed. A large proportion of the beds were purposely made for four patients, and six were frequently crowded in.

 

John Howard (1726-1790), the philanthropist, by his splendid and devoted labours in connection with the reform of prisons, hospitals, and lazarettos, drew attention to the means of preventing the communication of the plague and other infectious fevers. In the words of Burke430 “his philanthropic spirit led him to dive into the depths of dungeons¹⁷⁷; to plunge¹⁷⁸ into the infection of hospitals; to survey the mansions¹⁷⁹ of sorrow and pain; to take the gauge¹⁸⁰ and dimensions of misery¹⁸¹, depression, and contempt; to remember the forgotten; to attend to the neglected; to visit the forsaken¹⁸², and to compare and collate¹⁸³ the distresses¹⁸⁴ of all men in all countries.” Not the least of his services were those he rendered to the cause of sanitary¹⁸⁵ science and public health.

 

Théophile de Bordeu (1722-1776) was a professor of anatomy and midwifery at Montpellier. By his great work, Recherches sur le Pouls, he so enraged¹⁸⁶ his professional brethren (who, like the Jews, always either maim¹⁸⁷ or kill the prophets sent unto them), that he was attacked in his personal character with disgraceful malignity¹⁸⁸ for several years. He rendered very great services to the progress of medical science. His physiology was far in advance of his age, and many men have found in his researches on the functions of the glands a mine of wealth for the establishment of their own reputation.

 

M. F.?X. de Bichat (1771-1802) was a celebrated French anatomist and physiologist³, whose great work, Anatomie Générale, was the foundation of the reform of French medicine at the intellectual awakening¹⁸⁹ after the great revolution. Pathology, the science of disease, would have been impossible without such researches as those of Bichat. He first took a “commanding view,” not merely of the organs of the body, but of the tissues of which they are built up. He resolved the complex into its elements, and investigated the structure of each. He completed the overthrow¹⁹⁰ of the iatro-mathematical school, regarding the properties of the living tissues as vital actions. He classified the functions as organic and animal, and greatly aided in systematising the phenomena of life.

 

Mesmerism.

 

Frederick Anton Mesmer (1733-1815) studied medicine at Vienna. He embraced astrology, and believed in the influence of the stars on living beings. He came to think that cures might be effected by stroking with magnets; afterwards he discarded the magnets, and convinced himself that he could influence others by stroking them with his hands alone. In 1778 Paris was greatly excited over the miraculous¹⁹¹ cures of mesmerism. The medical faculty denounced him as a charlatan¹⁹², though a Government Commission in its report admitted many of the facts, while tracing them to physiological causes. The Marquis de Puysegur revolutionised the art of mesmerism by producing all the phenomena without the mummeries and violent means resorted to by Mesmer. Dr. John Elliotson in England in 1830 successfully practised the art.

 

In 1845 Baron¹⁹³ von Reichenbach declared he had discovered a new force which he called odyl, and in 1850 his Researches on Magnetism¹⁹⁴ were translated into English by Dr. Gregory, professor of chemistry in the University of Edinburgh.

 

431

 

G. Van Swieten (1700-1772) was a pupil of Boerhaave, and famous in the history of medicine as the founder of the Old Vienna School. He brought about the clinical teaching for which that school has since been so famous. Following the instructions of Paracelsus, he introduced into his practice the use of mercuric perchloride internally in the treatment of syphilis. His commentaries on Boerhaave were considered to be more valuable than the text itself.

 

De Haen (1704-1776), of the Hague, studied under Boerhaave, and having been recommended by Van Swieten, was invited to Vienna as president of the clinical school in the hospital of that city. Observation, and the simplest treatment in disease, especially in fevers, made up the chief part of his medical system. Purgatives¹⁹⁵ and emetics¹⁹⁶ and powerful medicines he would use only on the most urgent necessity. Hygiene¹⁹⁷, both for the patient and the state, he considered of the highest importance in medical education. Clinical thermometry received great attention from De Haen, who demonstrated that in what is considered by the patient the cold stage of fevers there is really a notable increase in the temperature.

 

James Yonge (1646-1721), physician and F.R.S., wrote an important treatise on the use of turpentine as a means of arresting h?morrhage, entitled Currus Triumphalis de Terebintho. He described the flap operation in amputations, and was acquainted with the principle of the tourniquet¹⁹⁸ for the arrest of bleeding during operations.

 

John Addenbrooke, M.D., died 1719, leaving by his will four thousand pounds to found a hospital at Cambridge, which now bears his name.

 

James Drake, M.D. (1667-1707), wrote a work, once deservedly popular, entitled Anthropologia Nova; or, a New System of Anatomy.

 

John Arbuthnot, M.D. (1658-1735), physician to Queen Anne, was a man of extensive learning and of great scientific abilities, characterized by Thackeray as “one of the wisest, wittiest¹⁹⁹, most accomplished, gentlest of mankind.”

 

Daniel Turner, M.D. (1667-1741), achieved a certain fame as the inventor of an excellent ointment²⁰⁰, still known as “Turner’s Cerate,” composed of oil, wax, and calamine.

 

Richard Mead, M.D. (1673-1754), was the author of the Mechanical Account of Poisons, a work which at once established his reputation. He was elected a Fellow of the Royal Society in 1703. On the accession of George II. he was appointed physician-in-ordinary to the King. He was the friend of Radcliffe, and like him a generous promoter of science and learning and of unbounded charity to those in misery. It was Mead who persuaded Guy to bequeath his fortune to432 found the noble hospital which bears his name. Mead was a political physician, and it is said by Miss Strickland that his prompt boldness occasioned the peaceable proclamation of George I. Mead’s work on the diseases of the Bible, entitled Medica Sacra, is a curious and interesting treatise. Excellent physician as he was, he recommended pepper and lichen²⁰¹ as a specific against the bite of a mad dog.

 

John Freind, M.D. (1675-1728), a learned and accomplished physician, is famous as the author of an elaborate work, The History of Physick from the Time of Galen to the Beginning of the Sixteenth Century. He laid the plan of this important work whilst a prisoner in the Tower, to which he was committed on suspicion of participation²⁰² in the so-called “Bishop²⁰³’s plot.” He was liberated²⁰⁴ after about three months’ confinement²⁰⁵ by the firmness of Dr. Mead, who refused to prescribe for Sir Robert Walpole till he consented to admit him to bail²⁰⁶.1008 During his imprisonment²⁰⁷ Freind wrote a Latin letter On certain Kinds of Small Pox.

 

How near the physicians of Mead’s time came towards the discovery of the germ theory of infectious disorders²⁰⁸ may be seen from his account of the leprosy.1009 In this treatise he says it has been found by experiments that in the plague and other malignant²⁰⁹ eruptive fevers the infection once received into articles of clothing remains²¹⁰ in them for a long time, and thence passes into human bodies, and “like seeds sown produces the disease peculiar to them.” With reference to the retention²¹¹ of the infection by dry walls, he says, “I thought it probable that they may, by a kind of fermentation, produce these hollow, greenish, or reddish strokes,” etc.

 

Surgeons.

 

Dominique Anel (1679-1730) was the famous French surgeon who invented the operation for aneurism, which Hunter afterwards modified and called by his own name.

 

He successfully treated lachrymal fistula, and invented several surgical instruments which are named after him.

 

J. L. Petit (1674-1750) in 1718 invented the screw tourniquet for compressing bleeding arteries²¹². He was one of the most famous surgeons in the brightest period of the art in France, and was besides an excellent ophthalmologist.

 

Le Cat (1700-1768) was the famous lithotomist, and opponent of the doctrines of Haller.

 

Le Dran (1685-1770) performed the first disarticulation of the thigh²¹³.

 

Morand (1697-1773) performed disarticulation of the upper arm.

 

433

 

Pierre Joseph Desault (1744-1795) was a great French anatomist and surgeon, who instituted a clinical school of surgery at the H?tel Dieu in Paris. He frequently had an audience of six hundred.

 

He introduced many improvements in surgical practice and in the construction of surgical instruments.

 

G. de la Faye (d. 1781), a great surgeon and oculist²¹⁴, also disarticulated the shoulder joint²¹⁵.

 

A. Louis (1723-1792) was a distinguished military surgeon.

 

R. B. Sabatier (1723-1811) was a distinguished surgeon, anatomist, and ophthalmologist, and a man of great and all-round information on medical subjects in general.

 

P. F. Percy (1754-1825) was a military surgeon who introduced cold-water dressings²¹⁶ into French surgery.

 

Antonio Scarpa (1748-1832), the famous Italian anatomist, held the chair of anatomy at Modena, was distinguished in every branch of anatomical research, and investigated the minute anatomy of the nerves and bones. He decided²¹⁷ the long-debated question whether the heart is supplied with nerves in the affirmative. He wrote on diseases of the eye, on aneurism, and on hernia. He was an elegant scholar, “equally at home in the criticism of the fine arts and in the details of scientific agriculture.”

 

Amongst the principal Italian surgeons of the century were Bertrandi (1723-1797), Troja (1747-1827), and Palletta (1747-1823).

 

Of the Germans the great names are, Schmucker (1712-1786), Richter (1742-1812), and Siebold (1736-1807), who first taught surgery clinically in Germany.

 

Callisen (1740-1824), the great Danish surgeon, and Anel (1741-1801), the founder of the Swedish School of Surgery, are two famous names which must be remembered in the surgical history of the period.

 

William Cheselden (1688-1752) was famous as a lithotomist and oculist. His dexterity²¹⁸ in the performance of lithotomy caused marvellous legends to be told of him, it was even said that he had operated in fifty-four seconds. He published his Anatomy of the Human Body in 1713.

 

Samuel Sharp (1700-1778) excelled in nearly every branch of surgery, and was a skilful operator, who by his efforts to stimulate²¹⁹ English surgeons to emulate²²⁰ the French did much to advance British surgery.

 

Benjamin Gooch of Norwich, Hey of Leeds, and Park of Liverpool, were also famous in this period.

 

Percival Pott (1713-1788) was a surgeon to St. Bartholomew’s Hospital, London, whose life formed a sort of epoch²²¹ in the history of434 surgery in England. Samuel Cooper says of him1010 that he was in his time the best practical surgeon, the best lecturer, the best writer on surgery, the best operator of which the metropolis²²² could boast.

 

John Hunter (1728-1793) was a physiologist and surgeon combined, unrivalled in the annals of medicine. He raised surgery, which before his time was little more than a mechanical art, to the rank of a scientific profession. As a pathologist and comparative anatomist, he rendered the greatest services to medicine and surgery. He dissected²²³ 500 different species of animals. One of the most brilliant surgical discoveries of the century was Hunter’s operation for the cure of popliteal aneurism, by tying the femoral artery²²⁴ above the tumour²²⁵ and without interfering²²⁶ with it. He improved the treatment of rupture²²⁷ of the tendo achillis, and invented a method of curing lachrymal fistula, and of curing hydrocele radically²²⁸ by injection.

 

He was the first to describe phlebitis (inflammation of the veins²²⁹), and he made the discovery that the white blood corpuscles are antecedent to the red. He investigated the subject of inflammation, the results of which he published in his Treatise on the Blood, Inflammation and Gun-shot Wounds. Other works of Hunter’s are his Treatise on the Natural History of the Human Teeth, A Treatise on the Venereal Disease, and Observations on Certain Points of the Animal Economy. “His greatest monument is the splendid museum which he formed by his sole efforts, which he made too when labouring under every disadvantage of deficient²³⁰ education and limited means.” His brother-in-law, Sir Everard Home, prepared the catalogue of the museum and then burned Hunter’s manuscripts, probably that he might conceal¹²⁸ the plagiarisms²³¹ of which he had been guilty in writing his book on Comparative Anatomy. The Government purchased Hunter’s museum from his widow for ￡15,000, upon condition that twenty-four lectures should be delivered every year to members of the college, and that the museum should be open to the public.

 

Charles White, a Manchester surgeon (circ. 1768), was the first to introduce what is known as conservative surgery. He first resected1011 the humerus, and taught the reduction of shoulder dislocations with the heel in the arm-pit.

 

The German surgeons in the seventeenth century held simply the position of barbers; they began life by cutting hair, shaving, cupping and bleeding, and then rose to be dressers of wounds and ulcers²³², and to treat fractures and dislocations.1012 In 1713, Berlin acquired its first435 anatomical theatre for the instruction of military doctors and “medico-surgeons.” Dresden and Hanover began to improve the education of clever barbers about the middle of the eighteenth century. The Military Medical School of Vienna was opened in 1781. Barbers and bathmen in the eighteenth century were trained into district medical officers and surgeons by a course of instruction lasting²³³ from two to three years. In Holland students were privileged to assist in operations at the hospitals. The first surgical clinic in Germany was established at Würzburg, in 1769. The Vienna surgical clinic arose in 1774. The greatest teacher of surgery in Germany, A.?G. Richter, gave clinical instruction at G?ttingen, in 1781.1013

 

G. M. Thilenius in 1784 performed the first division of the tendo achillis for the cure of club-foot.

 

Justus Arneman (1763-1807) was a surgical professor at G?ttingen, who wrote a system of surgery and advanced the study of diseases of the ear.

 

Camper (1722-1789), a Dutch surgeon of a mechanical turn of mind, made improvements in trusses. Leguin, a Frenchman, was the first to employ steel springs in trusses (1663). Tipharie in 1761 introduced the double truss.1014

 

Obstetricians.

 

Johann Palfyn (1649-1730), a celebrated obstetric physician, in 1721 invented, or rather re-introduced, a species of forceps in difficult labour.

 

Hugh Chamberlen, M.D. (1664-1728), was the most famous man-midwife of his day. His name is for ever associated with the invention of the obstetric forceps—a noble instrument, which has saved more lives than any mechanical invention ever associated with the healing art. A monument was erected to his memory in Westminster Abbey, with a long Latin epitaph by Bishop Atterbury.

 

William Smellie (1680-1763), a distinguished English obstetric physician, improved the midwifery forceps and suggested and performed various operations in obstetric practice.

 

William Bromfield (1712-1792) founded the Lock Hospital, London. He invented a tenaculum (a fine sharp hook by which the mouths of bleeding arteries are drawn out). He was a celebrated operator, and wrote a work on surgery.

 

The Medical College of Philadelphia was the first institution estab436lished in North America to give medical instruction. It was organized in May, 1765, by Drs. Shippen and Morgan. The University of Pennsylvania developed its medical department from this humble²³⁴ beginning.

 

Anatomists, Physiologists, Botanists²³⁵, etc.

 

Alexander Monro (1697-1767) was a very eminent surgeon and anatomist of Edinburgh, whose Medical School owes more to him probably than to any other individual. He wrote on the Anatomy of the Bones, and an Essay on Comparative Anatomy.

 

Frank Nicholls, M.D. (1699-1778), was a famous anatomist and physiologist at Oxford. “He was the inventor of corroded²³⁶ anatomical preparations, and one of the first to study and teach the minute anatomy of tissues, in other words, general, as distinguished from regional and descriptive anatomy.”1015 He was one of the first to describe correctly the mode of the production of aneurism, and he distinctly recognised the existence and function of the vaso-motor nerves.1016

 

Browne Langrish, M.D., was elected a Fellow of the Royal Society in 1734. He was the author of several medical treatises, one of which was entitled Physical Experiments upon Brutes²³⁷ to discover a Method of dissolving Stone in the Bladder by Injections; to which is added a course of Experiments with the Lauro-Cerasus; on Fumes²³⁸ of Sulphur, etc. 8vo. Lond., 1746. His researches on the action of cherry laurel water are said to have suggested the use of prussic acid in medicine.1017

 

John Fothergill, M.D. (1712-1780), was a distinguished botanist, who collected a great number of rare plants from all parts of the world.

 

William Cruikshank (1745-1800) was an anatomist who discovered urea.

 

Stephen Hales (1677-1761), an experimental physiologist and pathologist, produced dropsy by injecting water into the veins of animals, and investigated by experiments on animals the relative movements of the blood.

 

Antonio Valsalva (1666-1723), a great Italian anatomist, held the professor’s chair at Bologna and wrote a valuable treatise upon the ear and its anatomy.

 

Giovanni Santorini (1681-1737) was a Venetian anatomist whose investigations in the anatomy of the larynx, nose, face, etc., have immortalised his name in connection with several structures of those parts.

 

437

 

Giovanni B. Morgagni (1682-1772) was the great founder of pathological anatomy. He was a pupil of Valsalva. His famous book on pathological anatomy was not published until he was in his 79th year. He was the author of the maxim¹³⁰ that “observations should be weighed, not counted.” The researches in morbid anatomy carried out by Morgagni formed an epoch in the history of modern medicine, which may indeed be said to rest on the two methods of Sydenham and Morgagni. The work of the Italian anatomist was complementary to that of the English Hippocrates, who neglected anatomy. Morgagni and the “Encyclop?dic Haller,” whom we are next to consider, were two of the brightest medical lights of the century.

 

Albert von Haller (1708-1777), surnamed “the Great,” was a Swiss physician of Berne, who was not only a distinguished scientist, but a man of letters and a famous poet. He studied comparative anatomy at Tübingen; in 1725 he removed to Leyden, which at that time was the first medical school in Europe. He visited England in 1727, and made the acquaintance of Sir Hans Sloane, Cheselden, Dr. James Douglas, and other eminent persons. Leaving London, he went to Paris, but having been detected by the police in dissecting²³⁹ in his lodgings²⁴⁰, he had to leave France, and he went to Basle to continue his investigations in anatomy; there he studied mathematics under John Bernoulli, and, having imbibed²⁴¹ a taste for botany, studied the flora²⁴² of Switzerland, on which he afterwards published a work. In 1729 he returned to Berne and lectured on anatomy; invited in 1726 to accept the professorship of anatomy, surgery, and botany in the newly founded University of G?ttingen, he removed to that city, and by his influence a botanical garden, an anatomical theatre, a school of surgery and midwifery were established there. In 1747 he published his most valuable work, the Prim²⁴³? Line? Physiologi? which was used as a text-book in medical schools.

 

Van Swieten (1700-1772), the pupil of Boerhaave, established the first clinical institution in Germany. He was with Sanchez the first to use corrosive²⁴⁴ sublimate²⁴⁵ in medicine. To his exertions²⁴⁶ it was due that the teaching of medicine was greatly improved in Austria.

 

J. F. Meckel (1724-1774) was an anatomist whose researches on the nerves, blood-vessels, glands, etc., have greatly contributed to our knowledge of their physiological functions.

 

J. C. Peyer (1653-1712) and J. C. Bruner (1653-1727) discovered the glands in the intestines²⁴⁷ which are known to this day by their names.

 

A. Pacchioni (1665-1726) described the glands we call in his honour “Pacchionian.” W. Cowper (1666-1709) discovered those which bear his name. M. Naboth (1675-1721) described the struc438tures we call ovula Nabothi. H. Meibom (1638-1700) discovered the glands of the eyelids²⁴⁸ named after him.

 

Walter Charlton, M.D. (1619-1707), anatomist, a voluminous writer, was to some extent a follower²⁵ of Van Helmont.

 

Thomas Fuller, M.D. (died 1734), published several pharmacop?ias and an account of eruptive fevers, with several other works.

 

Nehemiah Grew, M.D. (born about 1641), wrote The Anatomy of Plants, with an Idea of a Philosophical History of Plants, which Sprengel calls opus absolutum et immortale. Hallam says,1018 “no man, perhaps, who created a science has carried it further than Grew; few discoveries of great importance have been made in the mere anatomy of plants since his time.” His great discovery was the sexual system of plants; “that the sexual system is universal in the vegetable kingdom, and that the dust of the anther? is endowed with an impregnating power.”1019

 

He was the first to obtain sulphate of magnesia from the Epsom waters, and to investigate its properties. His treatise on Epsom salts was published in 1697.

 

William Briggs, M.D. (died 1704), was famous for his “skill in difficult cases of the eye.”

 

Edward Tyson, M.D. (died 1708), wrote on anatomy; he was the Carus of Garth’s Dispensary, and the discoverer of “Tyson’s Glands.”

 

William Pitcairn, M.D. (1711-1791), was an accomplished botanist. He lived in the Upper Street, Islington, where he had a botanical garden five acres in extent, stocked with the scarcest and most valuable plants. He introduced into St. Bartholomew’s Hospital a much freer use of opium in the treatment of disease, and especially of fevers, than had hitherto been customary, and that with the greatest benefit to the patients.

 

Peter Shaw, M.D. (1694-1763), greatly facilitated the study of chemistry in England by his translations of the chemical works of Stahl and Boerhaave, as well as by his own works. He edited the works of Bacon and Boyle, and published a number of books on medicine and chemistry.

 

William Hunter, M.D. (1718-1783), was an earnest and devoted anatomist and obstetrician. He was a pupil of Cullen, and was so successful a practitioner²⁴⁹ that he expended²⁵⁰ ￡100,000 upon his house and anatomical collection, etc. The Hunterian Museum of the University of Glasgow was formed from this collection. The famous John Hunter was his younger brother.

 

439

 

Thomas Dimsdale, M.D. (1711-1800), a celebrated promoter of inoculation for small-pox, acquired a great reputation and immense wealth by the process. Catherine II. of Russia paid him enormous sums for successful inoculations, and gave him a barony.

 

William Heberden, M.D. (1710-1801), lectured on Materia Medica at Cambridge. Dr. Munk1020 gives an interesting extract from one of Heberden’s lectures on Mithridatum and Theriaca, the famous classic medicines; he proves that the only poisons known to the ancients were hemlock²⁵¹, monk’s-hood, and those of venomous beasts, and that they had no antidotes²⁵² for these. He says that the first accounts of powerful poisons concealed in seals or rings, poisonous vapours in gloves and letters, etc., are idle inventions of ignorant and superstitious²⁵³ persons.

 

Buffon (1707-1788) was the celebrated French naturalist²⁵⁴ to whom “we owe our first clear and practical connection of the distribution of animals with the geography of the globe.”

 

George Armstrong in 1769 opened the first children’s hospital in Europe; he was the physician who first devoted special attention to the diseases of children. Armstrong was a London man, and died 1781.

 

Joh. E. Gredring (1718-1775) was a German physician who was the first to investigate “the seat, cause, and diagnosis²⁵⁵ of insanity²⁵⁶.”1021

 

James Currie (1756-1805) advocated the cold-water treatment of typhus fever patients, and thus introduced a method of treatment which in one form or another is used at the present time for reducing the temperature of the body in such cases. Currie determined²⁵⁷ the temperature by the thermometer.

 

Lady Wortley Montagu (1690-1762) is famous in the annals of medicine for her courageous²⁵⁸ adoption²⁵⁹ of the Turkish practice of inoculation for small-pox in the case of her own son. By her zealous²⁶⁰ advocacy she was instrumental in causing the practice to be introduced into England in 1721. Dr. Keith having subjected his son to the operation, experiments were conducted upon criminals by Maitland, and these having been successful, the Prince of Wales and the royal princesses were inoculated²⁶¹ by Mead. On behalf of the Almighty²⁶², whose province was supposed to be trespassed²⁶³ upon by these and similar proceedings²⁶⁴, the practice was violently opposed by the clergy²⁶⁵ and others.

 

Edward Jenner (1749-1823) introduced the practice of vaccination as a preventive of small-pox. He commenced his investigations concerning cow-pox about the year 1776. The practice of inoculation440 with the virus of small-pox, which had been introduced into England through the suggestion of Lady Wortley Montagu, indirectly led Jenner to his grand discovery. His attention was excited by finding that certain persons to whom he attempted to communicate small-pox by inoculation were not susceptible²⁶⁶ to the disease; on pursuing his inquiries²⁶⁷ he found that these persons had undergone cow-pox—a complaint common among the dairy-servants and farmers in Gloucestershire, and that these people were aware that cow-pox in some way was a preventive against the small-pox. Local medical men had long been acquainted with this idea, but had paid no attention to it, considering it merely a popular and groundless belief. Jenner’s genius, however, led him to divine the truth of the matter and turn it to practical advantage. The disease which affects the udder of the cow was found to be inoculable²⁶⁸ in the human subject, and could be propagated from one person to another, rendering²⁶⁹ those who had passed through the complaint secure from an attack of small-pox. Having confided²⁷⁰ the fact of this discovery to some medical friends, it was taken up in 1796 by Mr. Clive, of St. Thomas’s Hospital, who introduced vaccination into London. Vaccination was adopted in the army and navy, and Jenner was honoured by professional distinctions and a parliamentary grant of ￡20,000. He was made a Fellow of the Royal Society, and his fame and the benefits of his discovery were rapidly extended to continental nations.