Ernest Henry Starling (1866-1927) on the Glomerular and Tubular Functions of the Kidney

Broadly speaking, there are two main avenues of approach in the attempt to unravel the complicated processes which determine the function of any individual organ. On the one hand, we may study its reaction in the intact animal to comparatively small environmental changes—a method of inestimable value, since it is one which may readily be applied to man ; on the other hand, we may remove the organ and study its reaction under grossly artificial conditions. In the former case, we sacrifice simplicity and full control to a close approximation to normality in environment ; in the latter case, we sacrifice normality in environment in order to obtain greater simplicity and a higher degree of experimental control. The former may be referred to as the analytic method of experimentation, the latter as the synthetic. On the one hand, we attempt to dissociate the medley of influences which share in determining the normal function of the organ, and to relegate to each its particular office in maintaining this normality ; on the other hand, we attempt to associate these influences in such a degree and in such a manner as to bring the isolated organ back to an environment and function comparable to the normal. We have used the latter method in an attempt to throw more light on the mechanism of urinary secretion in mammals. In order that the mammalian kidney may be kept alive in the isolated state, it is obvious from a consideration of its relatively enormous oxygen consumption—a consumption per gram per minute which may exceed that of the heart(10) (68)—that an efficient means of supplying this want must be at hand. Perfusion experiments such as those of Ludwig(1) in which a dog’s kidney was perfused with a solution containing 3 per cent. gum and 1 per cent. NaCI, can only hope to throw some light on the mechanical conditions obtaining in the dead organ. In 1890, Jacoby(2) perfused the isolated kidney of the dog with defibrinated blood by means of a pump and arterialised the blood by means of a current of air. With v. Sobieranski(3) he succeeded in obtaining a very slow urine flow by this means, but the fluid secreted invariably contained protein in considerable amounts. Three years later an improvement(4) in the form of apparatus was introduced in that an artificial pulmonary circulation was maintained by means of a second pump, the arterialised blood being then sent to the kidney as before. This improvement in technique, however, failed to give results of any promise. Similarly, Pfaff and Vejux Tyrode, (5) perfusing the dog’s kidney with defibrinated blood, invariably obtained blood and protein in the fluid issuing from the ureter. They claim to have shown that this untoward result was due to the toxic action of defibrinated blood. On defibrinating an animal the urine simultaneously secreted contained blood and protein, but this rapidly disappeared on removing the defibrinated blood, and replacing it with normal blood from another dog by bleeding this animal directly into the other’s venous system. Hirudin was tried and gave better results, but the experiments were not continued. The experiments of Sollmann(6) were performed with dog’s kidneys in the dead or dying condition. These were perfused with saline or highly diluted defibrinated blood in an attempt to study the mechanics of the organ. In 1903, Brodie(7) described an apparatus for the perfusion of isolated organs with oxygenated and defibrinated blood. He noticed, as had Pfaff and Vejux Tyrode, that vasoconstriction quickly set in under the conditions of experiment, but that(8) this could be overcome by the addition of chloral or amyl nitrite to the blood. A urine flow up to 16 c. c. per 15 minutes was obtained. Again, Hooker, (9) in a study of the influence of pulse pressure upon renal function, perfused dog’s kidneys by means of a pump with defibrinated blood through which oxygen was bubbled. He obtained a “ filtrate, neutral to litmus.” No other details of its composition are given. Up to this time it is clear that little success had been forthcoming in attempts to keep the isolated mammalian kidney alive, much less to function in a capacity approaching normal.

An in vitro approach to the study of single nephron function in uremia has been employed in evaluating the control of fluid reabsorption by the renal superficial proximal straight tubule (PST). Isolated segments of PSTs from the remnant kidneys of uremic rabbits (stage III) were perfused in vitro and their rate of fluid reabsorption compared with normal PSTs and with PSTs derived from the remnant kidneys of nonuremic rabbits (stage II). All segments were exposed to a peritubular bathing medium of both normal and uremic rabbit serum thereby permitting a differentiation to be made between adaptations in function which are intrinsic to the tubular epithelium and those which are dependent upon a uremic milieu.Compared with normal and stage II PSTs, there was significant hypertrophy of the stage III tubules as evidenced by an increase in length and internal diameter, and a twofold increase in the dry weight per unit length. Fluid reabsorption per unit length of tubule was 70% greater in stage III than in normal and stage II PSTs, and was closely correlated with the increase in dry weight. Substitutions between normal and uremic rabbit serum in the peritubular bathing medium did not affect fluid reabsorption significantly in any of the three groups of PSTs. Perfusion of the tubules with an ultrafiltrate of normal vs. uremic serum likewise failed to influence the rate of net fluid reabsorption. It has previously been observed that net fluid secretion may occur in nonperfused or stop-flow perfused normal rabbit PSTs exposed to human uremic serum. Additional studies were thus performed on normal and stage III PSTs to evaluate whether net secretion occurs in the presence of rabbit uremic serum. No evidence for net secretion was found. These studies demonstrate that fluid reabsorption is greatly increased in the superficial PST of the uremic remnant kidney and that this functional adaptation is closely correlated with compensatory hypertrophy of the segment. Humoral factors in the peritubular environment do not appear to be important mediators of the enhanced fluid reabsorption.

Ernest Henry Starling laid the groundwork for our modern understanding of how the interstitial fluid, which he referred to as ‘lymph', is regulated. Together with his colleague, William Bayliss, he provided the crucial insight into how fluid is driven out of the capillary to form interstitial fluid. That was to measure (estimate) the capillary pressure in different parts of the circulation and to relate changes in these pressures to altered lymph formation. In addressing how interstitial fluid re-enters the circulation, he was able to show that this occurs not only via the lymphatics, but also by re-entering the capillaries, mediated by the oncotic pressure of the plasma proteins. Starling's discoveries put to rest all notions that the processes of filtration and reabsorption of fluid are mediated by the ‘vital activity' of cells. They could be explained entirely on the basis of physic-chemical forces. Based upon his insights from animal experiments, he was able to explain the genesis of edema (dropsy) in a number of disease states, including venous obstruction, cardiac disease and inflammatory conditions.