In Vivo Fluorescence Imaging of Blood Flow in Mouse Pancreatic Islets

Abstract

Diabetes is a disease resulting from changes in pancreatic islets, which are insulin secreting micro-organs within the pancreas. With increased blood glucose, insulin is secreted from beta cells in the islets in a coordinated pulsatile manner. At the same time alpha cell glucagon secretion is inhibited. Mechanisms controlling these processes at the intercellular and at the inter-islet level remain unclear. We suggest that the three-dimensional organization of islet cells and the dynamics of islet blood flow have a role in regulating insulin and glucagon secretion. This is suggested by observation that the density of blood vessels within islets is much greater than in surrounding pancreatic tissue, and that most individual islet cells are adjacent to a blood vessel. As an initial test of our hypothesis, we have developed a high-speed in vivo fluorescence imaging method to track pancreatic blood flow in a living mouse. We are also developing methods necessary to analyze the large amounts of data generated. Using high speed line scan confocal microscopy the method has full frame sub-micron spatial and less than 10 ms temporal resolution. Islets are located within the pancreas by using mice with GFP-labeled beta cells. Blood plasma is labeled with a fluorescent dextran, allowing mapping of vascular dimensions and pathway. Individual blood cells are fluorescently labeled by osmotic shock loading with an Alexa dye, which allows tracking of the blood flow. We present current results for blood flow under different levels of blood glucose in clamping experiments. Our previous qualitative results have suggested that there are differences in blood flow parameters at different glucose levels. Here, a more quantitative analysis of blood flow velocity, any observed changes in vessel dimensions, and changes in blood flow coverage inside and outside islets is presented.