This project focuses on the role of the terminal microvascular network in determining the variable behavior of blood cells (erythrocytes, RBC and leukocytes, WBC) and in determining blood flow distributions in the microvasculature. We view the heterogeneity in blood flow and blood cell behavior as a predictable result of local biophysical phenomena and their biological outcomes. Gen.
Aim 1 centers on determinants of RBC distribution.
Aim 1. 1 tests the hypothesis that RBC distribution into, and flow through, capillaries is a function of RBC surface to volume ration. With Project 3, flow properties of modified RBCs will be determined in capillaries both acute and chronically; cell mechanical properties will be measured in vitro and RBC flux and velocity and capillary geometry in vivo.
Aim 1. 2 tests the hypothesis that bifurcation geometry contributes to asymmetries in distribution of RBCs, using RBC suspensions perfused through microchannel systems constructed to mimic terminal arteriolar bifurcation geometry. Gen.
Aim 2 explores the relationship between endothelial cell (EC) cytoskeletal realignment with flow, and the geometry (curvature) of the EC growth surface.
Aim 2. 1 tests the hypothesis that the cytoskeletal responses of ECs to flow is different in cells growing on curved compared to flat surfaces. F-actin distribution will be measured in ECs of different origins grown under varying flow and curvature. Focal adhesion distribution will also be measured.
Aim 2. 2 tests the hypothesis that ECs in vivo can respond to flow changes with cytoskeletal realignment. Local perfusion of arterioles will be used to mix microvessels and stain F-actin, under differing flow of vasoactive stimuli. Gen.
Aim 3 addresses the mechanisms underlying WBC-EC interactions in vivo.
Aim 3. 1 tests the hypothesis that heterogeneity in WBC distribution among venules is due to preferred flow channels for WBCs. WBC flow variables will be quantitated in related to the venular architecture, at differing flows, or without selected adhesion molecules. Local venular heterogeneity in adhesion molecules will be quantitated from the distribution of P-selectin and ICAM-1, and also by using a WBC stopped time analysis developed by Project 1.
Aim 3. 2 tests they hypothesis that EC-WBC interactions can be changed due to flow related changes in ECs. With Project 2 we will measure EC volume changes and WBC flows in vivo before and after tissue ischemia, and with amiloride to prevent EC changes. In microchannels we will explore that mechanism underlying the EC volume response to flow, and effects on WBC-EC interactions.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Program Projects (P01)
Project #
5P01HL018208-27
Application #
6470090
Study Section
Project Start
2001-07-01
Project End
2002-06-30
Budget Start
1997-10-01
Budget End
1998-09-30
Support Year
27
Fiscal Year
2001
Total Cost
$109,973
Indirect Cost
Name
University of Rochester
Department
Type
DUNS #
208469486
City
Rochester
State
NY
Country
United States
Zip Code
14627
Vats, Kanika; Marsh, Graham; Harding, Kristen et al. (2017) Nanoscale physicochemical properties of chain- and step-growth polymerized PEG hydrogels affect cell-material interactions. J Biomed Mater Res A 105:1112-1122
Henry, Steven J; Crocker, John C; Hammer, Daniel A (2016) Motile Human Neutrophils Sense Ligand Density Over Their Entire Contact Area. Ann Biomed Eng 44:886-94
Marsh, Graham; Waugh, Richard E (2016) A simple approach for bioactive surface calibration using evanescent waves. J Microsc 262:245-51
Rocheleau, Anne D; Wang, Weiwei; King, Michael R (2016) Effect of Pseudopod Extensions on Neutrophil Hemodynamic Transport Near a Wall. Cell Mol Bioeng 9:85-95
Svetina, Saša; Kokot, Gašper; Kebe, Tjaša Švelc et al. (2016) A novel strain energy relationship for red blood cell membrane skeleton based on spectrin stiffness and its application to micropipette deformation. Biomech Model Mechanobiol 15:745-58
Rocheleau, Anne D; Cao, Thong M; Takitani, Tait et al. (2016) Comparison of human and mouse E-selectin binding to Sialyl-Lewis(x). BMC Struct Biol 16:10
MacKay, Joanna L; Hammer, Daniel A (2016) Stiff substrates enhance monocytic cell capture through E-selectin but not P-selectin. Integr Biol (Camb) 8:62-72
Hind, Laurel E; Lurier, Emily B; Dembo, Micah et al. (2016) Effect of M1-M2 Polarization on the Motility and Traction Stresses of Primary Human Macrophages. Cell Mol Bioeng 9:455-465
Lim, Kihong; Hyun, Young-Min; Lambert-Emo, Kris et al. (2015) Visualization of integrin Mac-1 in vivo. J Immunol Methods 426:120-7
Beste, Michael T; Lomakina, Elena B; Hammer, Daniel A et al. (2015) Immobilized IL-8 Triggers Phagocytosis and Dynamic Changes in Membrane Microtopology in Human Neutrophils. Ann Biomed Eng 43:2207-19

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