The Glycocoll Theory of Gout
Excessive meat feeding in dogs, according to Kochmann, induces degenerative changes in the liver and kidneys. Similar tissue alterations were noted by Walker Hall in rabbits, after injection with hypoxanthine, while the same was observed by Kionka in mice. These findings suggest that, although anatomical lesions are not apparent in the livers of “gouty” men, it is at least probable that functional damage results from the overeating of meat.
Now, if glycocoll be added to a solution of (neutral) dialkali-urate, it expedites the appearance of the (acid) mono-alkali-urate, a reaction more noticeable with the sodium salt. Urea, in contrast to glycocoll, markedly inhibits the formation of the acid salt. But if glycocoll be added to a solution of the (neutral) dialkali-urate and urea, the latter parts to some extent with its powers in this respect, and the mono-alkali-urate is deposited.
It is reasonable, then, to suppose that if, as testified by Ignatowski and Walker Hall, glycocoll is present in gouty urine, it is also present in the tissue fluids of the gouty individual, and so the precipitation of uric acid is favoured. Glycocoll, normally, is almost entirely transmuted into urea by the urea-forming ferment of the liver.
Impressed by these considerations, Kionka advances the hypothesis that gout is due to:
(1) Functional changes in the liver, a depressed urea-ferment action.
(2) A deficient uric acid excretion by the kidney, possibly due to the changed uric acid combinations in the blood.
(3) These pathological conditions may be “hereditary” or “acquired,” from overeating, alcohol, lead, etc.
In other words, given deficient action of the urea ferment in the liver, then more glycocoll will be present in the blood-stream, and the uric acid may be thrown out of solution.[7]
For it is possible, as Kionka suggests, that normally uric acid, on its way to urea, may pass through a glycocoll stage. Now, in the gouty individual the glycocoll may not be entirely transformed to urea, and its excess in the tissue fluids may lead to uric acid deposits. Perhaps, as Walker Hall observes, “since hepatic deficiency is generally admitted in the gouty, diminished destruction of uric acid and glycocoll may go hand in hand.”
In healthy cartilage glycocoll is undemonstrable. But, according to Kionka, if bruised or damaged, a considerable amount thereof is formed. Now, when blood, rich in uric acid, circulates through injured cartilage, the presence of glycocoll favours precipitation of the urates, a possible explanation of the formation of tophi. Unfortunately for the valency of this theory, Aberhalden and Schittenhelm show that the methods employed by Frey, to isolate glycocoll from cartilage, were such as yield errors which would quite account for the amount obtained by this worker. They, therefore, deny the presence of glycocoll in damaged cartilages. But, in conclusion, Kionka’s plea for a primary hepatic functional disability derives colour from the fact that the drugs which have gained most approval in the treatment of gout are those which increase the quantity of bile without augmenting the amount of bile acids; and the which are excreted in combination with glycocoll, for instance, salicyclic acid combines with glycocoll, and is excreted as salicyluric acid, and benzoic acid, which combines with glycocoll to form hippuric acid. Albeit, we must not overlook the fact that the presence of glycocoll is not peculiar to gouty urine, but, as shown by Walker Hall and Embden, is met with in other disorders. The glycocoll hypothesis as to the origin of gout is, though attractive, therefore still unproven.