1. The Circulation of the Blood, suspected by Michel Servet, Realdo Colombo, and Andreas Cesalpin, was really established by Harvey in 1628.

Yet Harvey was only able to demonstrate it by experiments performed on the living bodies of frogs and deer. Since Harvey's time, the laws of the circulation have been established with admirable precision. Hales demonstrated the pressure of blood in the vessels. Chauveau and Marey introduced into the heart of a horse an apparatus which enabled the pressure of the blood in the heart, in the arteries, and in the veins, to be measured. Weber found that the pneumogastric nerve stopped the heart's action. Ludwig applied the graphic method to the circulation. Delicate instruments have been constructed which give diagrams of the pulsations and measure the pressure of the blood in the arteries and in the heart of man. Claude Bernard discovered the nerves which regulate the movements of the vessel walls. In short, the whole history of the circulation is due solely to vivisections, and it would be ridiculous to speak of our uncertainties in this respect; for the essential mechanical or nervous laws of the circulation are as well known now as those of the combinations of nitrogen with oxygen.

2. The Respiration remained profoundly unknown, as to its inmost nature, right up to Lavoisier's time. Lavoisier placed some guinea-pigs in a box filled with ice, measured the quantity of heat thrown off, the quantity of oxygen consumed, the quantity of carbonic acid produced; and he was thus able to deduce a fundamental law of life, viz., that life is essentially combustion. He made experiments on himself also; but however great one's respect for the life of a guinea-pig may be, must it be considered wrong that Lavoisier should have experimented on the guinea-pig before experimenting on himself?

As for the laws which regulate this consumption of oxygen and this production of carbonic acid, to discover these it was necessary to put into cages animals of every species and of every size. And there is, perhaps, not a single physiologist who has not made this experiment, at the risk of annoying the cats and dogs thus exposed—without, as far as that goes, doing them any harm—to varied temperatures or to different diets. Moreover, in order to study the respiratory exchanges, physiologists experiment on man as well; is, therefore, the extraordinary scruple against experimenting on animals to be imposed upon them also?

To take an excellent example of the services which experimental physiology can render not to science only—which would, indeed, be quite sufficient to justify them—but to humanity, I will cite the experiments of Paul Bert with relation to elevated atmospheric pressures. There are certain workmen who are obliged to work under water, at a depth of 20 to 30 yards, for the construction of piers and bridges, or the exploration of sunken vessels. Now, it had long been observed that some of these men died suddenly on returning to the surface. Experimental physiology was able to discover the cause of that sudden death. When a man (or an animal), after having been subjected to several times the normal atmospheric pressure, is suddenly released from this pressure, the nitrogen dissolved in the blood is disengaged suddenly: this produces gaseous embolism, that is to say, bubbles of gas are formed, which block the blood-vessels and prevent the blood circulating in the capillaries. Knowing this, the death of men working at a pressure of four atmospheres could then be avoided by releasing them slowly, that is by bringing them slowly back to the normal atmospheric pressure. Is it barbarous to attach more importance to the death of these men than to the death of the few dogs and mice that served to establish this law?

I was able to demonstrate that, if the temperature of the air is very high, as in the hottest days of summer, dogs that are muzzled die rapidly of hyperpyrexia (i.e. high fever), for they are no longer able to cool themselves by panting. It is true that this experiment cost the lives of a few dogs, but has it not saved many others by pointing out that dogs should not be muzzled under certain conditions? It goes without saying I am not speaking of the theoretical consequences of this experiment.

Artificial respiration, which can restore to life the apparently drowned, is one, of the conquests of experimental physiology; for we have been able to determine the best method and the essential conditions (for artificial breathing) by experiments of a very precise nature. Is it nothing to know how to restore to life the apparently drowned?

3. The Process of Digestion has also been learned solely by experiment. In the history of science there are two or three cases of individuals in whom a wound or an operation has produced a gastric fistula, that is to say an abdominal opening through which the stomach can be reached and food introduced. Had we remained satisfied with these accidental observations, we should have obtained but mediocre results. Physiologists therefore have made experimental gastric fistulæ. Dogs thus operated on, after an illness of a few days, recover thoroughly. Some physiologists have kept dogs for several years in this condition: gay, caressing, docile, they did not appear to complain of their lot. They were better nourished, more petted and loved than the many starving dogs which roam about the country. They were not a whit more unhappy than was Alexis St Martin (observed in 1831 by Dr Beaumont) and Marcellin (whom I observed in 1878, at the beginning of my career). Quite recently an eminent Russian physiologist, Pawloff, has, by making gastric fistulæ in animals, been able to discover a number of important facts, absolutely necessary to be known for the treatment of diseases of the stomach, and even for the establishment of a normal alimentation.

The problem of alimentation is, indeed, one of the most essential, perhaps the most essential, in the history of humanity. I suppose that anti-vivisectionists are aware of the fact that, even in Europe, large populations exist who are insufficiently nourished. Under these conditions, is it not desirable to know exactly the quantities of carbon, nitrogen, salt, lime, and phosphorus which are necessary for animals, and consequently for man? Should not anti-vivisectionists, interested in vegetarianism, before venturing to institute a vegetable diet for man, try it first of all upon carnivorous animals, so as to know how a mixed alimentation can be modified by a vegetable alimentation, and to what extent those modifications are compatible with health?

4. The Nervous System is not so well known, so far as its functions are concerned, as the circulatory system or the digestive system. Nevertheless, positive discoveries are extremely numerous: the action of the nerves on the glands and on the muscles; the part played by the different portions of the brain; nervous degenerations; the laws governing reflex actions—all this constitutes a formidable body of well-established facts. I do not pretend that everything is known. Alas! No! There are still innumerable truths to be discovered, and serious errors are doubtless most learnedly taught, with many contradictions, much uncertainty, much confusion—all of which simply proves that physiology is not a science whose last chapter has yet been written, that the last word of this science has not yet been pronounced. Nevertheless, blind indeed would the man be who would venture to conclude that physiology was not a science; or to assert that physiology is a science of little importance; that the rôle of the physiologist, from the point of view of the alleviation of human miseries, is null; and that knowledge of physiological facts is useless. Will it be claimed that the doctor has no need of a knowledge of physiology? I will reply by a comparison I am accustomed to make before my medical students when I wish to make them understand the necessity of a sound physiological education.