Using a freezing point depression method osmolality in the intestinal tissue of four mammals (gerbils, guinea-pigs, rabbits and rats) was estimated in vivo, during fluid transport from an isotonic electrolyte-glucose solution. Net fluid transport was also measured. In gerbils, guinea-pigs and rabbits tissue osmolality was also estimated during in vitro conditions. A marked hyperosmolality was observed in vivo in the upper parts of the villi of all four mammals studied. The tissue osmolality was significantly higher than that seen in the same species during in vitro conditions. A villus hyperosmolality was observed also in species which exhibited a net fluid secretion (guinea-pig, rabbit ileum), indicating that the fluid secretion emanated from the intestinal crypts. Based on the results of the present experiments and on observations made in earlier experiments performed on the cat, it is proposed that the villus hyperosmolality is created by a countercurrent multiplier present in the intestinal villus. The hyperosmolar compartment in the villus tissue creates the force that drives fluid from lumen to tissue.
A new perfusion technique has been developed for the study of net water transport across the intestinal epithelium in vivo. The lumen of an isolated intestinal segment is steadily perfused with a solution of known composition in a closed perfusion system with a reservoir large enough to prevent recirculation. The intestinal segment may be enclosed in a plethysmorgraph. Changes in the perfused volume is recorded by a volume transducer coupled to the recirculating system via a T-tube. If no motility occurs, the changes of the perfusion volume reflects net water transport across the intestinal epithelium. A quantitative comparison of this technique with the convention polyethylene glycol method revealed no significant difference. The plethysmorgraphic method also makes it possible to quantify the net water absorption via lymph and blood.
A cryoscoptic technique has been developed that makes it possible to determine tissue osmolality in the core of the intestinal villi. During absorption from an isotonic electrolyte solution containing glucose an osmolality gradient was demonstrated from tip to base of the villi in both the jejunum and the ileum. The tissue osmolality at the villous tips was measured to 1 000-1 200 mOsm/kg H2O while the osmolality at the villous base was approximately isotonic with plasma. Increasing intestinal blood flow by i.a. administration of a vasodilator drug, or making the intestine ischemic by clamping the intestinal vascular supply while supplying the mucosa with oxygen, markedly decreased tissue osmolality. Substituting all sodium ions with choline in the luminal perfusate abolished almost completely the tissue hyperosmolality and the intestine became a secretory organ. These observations are consistent with the view that the observed villous tissue hyperosmolality was created by a countercurrent multiplication of sodium chloride. The physiological implications of this mechanism is discussed and it is, among other things, proposed that the hyperosmolar region represents the hyperosmotic compartment necessary for explaining intestinal water absorption.
The hemodynamic reactions of the parallel coupled vascular circuits in the cat small intestine were studied before, during and after a two-hour period of intestinal hypotension induced by lowering the intestinal arterial inflow pressure by partially occluding the superior mesenteric artery during a continuous stimulation of the postganglionic nerves to the small intestine. Furthermore, fluid and electrolyte transport and villous tissue osmolality were measured. A histological examination of biopsies taken during and after the hypotensive period was also carried out. The animals were divided into two groups (undamaged and damaged) according to the histological appearance of the intestinal mucosa. The hemodynamic reactions were investigated with a method that made it possible to study total intestinal, absorptive site ("villous"), nonabsorptive site ("crypt") and muscle layer blood flow. Total intestinal blood flow was lower in the damaged group than in the undamaged group during the arterial hypotension. However, absorptive site blood flow was similar in the two groups. Consequently, a significantly larger fraction of blood flow was distributed to the "villi" in the damaged group. Moreover, absorptive site red blood cell flow was only slightly reduced despite the development of mucosal ulcerations. These findings are discussed in relation to the pathophysiology of the mucosal lesions. Net fluid, net sodium and net chloride absorption was unchanged in the undamaged group whereas in the damaged group a marked decrease was observed after lowering the perfusion pressure. The decrease in net sodium absorption was due to a decrease in the lumen to tissue transport of sodium. Thus, the capacity of the small intestine to absorb fluid and electrolytes is unchanged even during a marked arterial hypotension with a pronounced decrease of intestinal blood flow as long as no mucosal damage has developed.
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