posted on 2020-03-20, 18:33authored byAda AdminAda Admin, Michael P. Dybala, Andrey Kuznetsov, Maki Motobu, Bryce K. Hendren-Santiago, Louis H. Philipson, Alexander V. Chervonsky, Manami Hara
The pancreatic islet is a highly-vascularized endocrine micro-organ. The unique architecture of rodent islets, a so-called-core-mantle arrangement seen in 2D images, led researchers to seek functional implications for islet hormone secretion. Three models of
islet blood flow were previously proposed, all based on the assumption that
islet microcirculation occurs in an enclosed structure. Recent
electrophysiological and molecular biological studies using isolated islets
also presumed uni-directional flow. Using intravital analysis of the islet
microcirculation in mice, we find that islet capillaries are continuously
integrated to those in the exocrine pancreas, which makes the islet circulation
rather open, not self-contained. Similarly in human islets, the capillary
structure was integrated with pancreatic microvasculature in its entirety.
Thus, islet microcirculation has no relation to islet cytoarchitecture, which
explains its well-known variability throughout species. Furthermore, tracking
fluorescent-labeled red blood cells at the endocrine-exocrine interface
revealed bi-directional blood flow, with similar variability in blood flow
speed in both the intra- and extra-islet vasculature. To date, the endocrine and exocrine pancreas
have been studied separately by different fields of investigators. We propose
that the open circulation model physically links both endocrine and exocrine
parts of the pancreas as a single organ through the integrated vascular
network.
Funding
The study is supported by National Institutes of Health, DK117192, DK020595 to the University of Chicago Diabetes Research and Training Center (Physiology Core), and a gift from the Kovler Family Foundation to M.H.