This Bioengineering Research Partnership assembles a team led by two biomedical engineers and a molecular physiologist to focus on the integrative control of vascular pattern formation. While vascular assembly and pattern formation will be needed as critical elements of successful therapeutic collateralization of progressively ischemic organs and in tissue engineering of various tissue substitutes in the future, remarkably little is known of the cells involved, the array of signal molecules and their genetic regulation, and the biophysical factors regulating the spatial and temporal dynamics of vascular pattern formation. Key questions now are: what is the origin of cells responsible for the investment of arterioles with contractile cells and what are the signals that control their proliferation, migration, and differentiation? An integrative systems approach is proposed to measure the dynamics of arteriolar pattern formation in vivo across time scales from the embryo to the adult, and spanning spatial scales from genes to cells to whole networks, and to create a new generation of computational approaches to understand the complex interplay of multiple interacting cells and signal molecules.
The specific aims are 1) to determine the role of PDGF and TGF-beta in arteriolar pattern formation during embryonic development, 2) to determine the cell types involved, role of PDGF and TGF-beta signaling, and spatial and temporal patterns of arteriolar assembly in adults, and 3) to develop and use a new cell-based computer simulation to perform integrative spatio-temporal analysis of the arterialization process in the embryo and adult, including multi-signal control of fibroblast and smooth muscle cell proliferation, migration, and differentiation. The multidisciplinary team will utilize unique gene-targeted mice in conjunction with innovative in vivo measurements, and integration of the data into the new computational models will improve understanding of the gene circuitry regulating arteriolar pattern formation. This focused partnership with three investigators who have worked together previously brings a unique set of complementary tools to bear on the problem. Year 1 milestones are to obtain the first microvessel mappings of contractile cell recruitment in transgenic mouse embryonic tissues, to implement spatial guidance of arteriolar pattern formation through application of focal growth factors in adult window chambers, and to implement a novel computational model of arterialization that represents smooth muscle cells and fibroblasts discretely. The long term goal is to define the mechanisms that control arteriolar pattern formation, and to provide the basis for powerful therapeutic vascularization procedures that function in the native environment in vivo.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL065958-02
Application #
6527668
Study Section
Special Emphasis Panel (ZRG1-CVA (01))
Program Officer
Lundberg, Martha
Project Start
2001-09-01
Project End
2006-08-31
Budget Start
2002-09-01
Budget End
2003-08-31
Support Year
2
Fiscal Year
2002
Total Cost
$705,026
Indirect Cost
Name
University of Virginia
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
001910777
City
Charlottesville
State
VA
Country
United States
Zip Code
22904
Doyle, Megan E; Perley, Jeffrey P; Skalak, Thomas C (2012) Bone marrow-derived progenitor cells augment venous remodeling in a mouse dorsal skinfold chamber model. PLoS One 7:e32815
Benedict, Kelly F; Mac Gabhann, Feilim; Amanfu, Robert K et al. (2011) Systems analysis of small signaling modules relevant to eight human diseases. Ann Biomed Eng 39:621-35
Benedict, Kelly F; Coffin, Gregory S; Barrett, Eugene J et al. (2011) Hemodynamic systems analysis of capillary network remodeling during the progression of type 2 diabetes. Microcirculation 18:63-73
Glaw, Jason T; Skalak, Thomas C; Peirce, Shayn M (2010) Inhibition of canonical Wnt signaling increases microvascular hemorrhaging and venular remodeling in adult rats. Microcirculation 17:348-57
Nickerson, Meghan M; Song, Ji; Meisner, Joshua K et al. (2009) Bone marrow-derived cell-specific chemokine (C-C motif) receptor-2 expression is required for arteriolar remodeling. Arterioscler Thromb Vasc Biol 29:1794-801
Binder, Kyle W; Murfee, Walter L; Song, Ji et al. (2007) Computational network model prediction of hemodynamic alterations due to arteriolar remodeling in interval sprint trained skeletal muscle. Microcirculation 14:181-92
Murfee, Walter L; Rehorn, Michael R; Peirce, Shayn M et al. (2006) Perivascular cells along venules upregulate NG2 expression during microvascular remodeling. Microcirculation 13:261-73
Skalak, Thomas C (2005) Angiogenesis and microvascular remodeling: a brief history and future roadmap. Microcirculation 12:47-58
Perlegas, Demetra; Xie, Hui; Sinha, Sanjay et al. (2005) ANG II type 2 receptor regulates smooth muscle growth and force generation in late fetal mouse development. Am J Physiol Heart Circ Physiol 288:H96-102
Murfee, Walter L; Hammett, Laura A; Evans, Caroline et al. (2005) High-frequency, low-magnitude vibrations suppress the number of blood vessels per muscle fiber in mouse soleus muscle. J Appl Physiol 98:2376-80

Showing the most recent 10 out of 16 publications