Lymph vessels are scarce or lacking in the renal inner medulla, raising the
question of whether plasma proteins entering the medullary interstitium ar
e removed by diffusion through the interstitium to lymphatics in the outer
medulla or cortex, or by convection into the vasa recta.
2. Using micropipettes, we infused I-125-albumin into the papilla of anaest
hetized rats and watched its disappearance from the injection site as well
as the uptake in the thoracic duct and plasma.
3. Tracer infused into the renal cortex appeared almost immediately in the
thoracic duct lymph, and rose to a sevenfold higher concentration than in p
lasma, whereas tracer infused into the papilla appeared first and increased
more sharply in plasma than in the lymph. No spread from the papillary inj
ection site was observed. Tracer injected in renal hilar lymphatics was qua
ntitatively recovered in the thoracic duct.
4. The plasma concentration pattern following papillary infusion was simila
r to that obtained by intravenous injection, indicating uptake in blood and
subsequent distribution to extracellular fluid and lymph from all organs.
5. We conclude that plasma proteins normally diffusing out from the vasa re
cta are brought back through water flux (1) from the collecting ducts due t
o the high sodium chloride concentration in the papillary interstitium and
(2) from the interstitium into the vasa recta driven by plasma protein osmo
tic pressure. Accordingly, there is no need for lymph vessels in the inner
medulla.