|
|
|
|
T. C. Skalak. Angiogenesis and microvascular remodeling: a brief history and future roadmap. Microcirculation. 12 (1):47-58, 2005.
T. J. O'Neill, B. R. Wamhoff, G. K. Owens, and T. C. Skalak. Mobilization of bone marrow-derived cells enhances the angiogenic response to hypoxia without transdifferentiation into endothelial cells. Circ Res 97 (10):1027-1035, 2005.
W. L. Murfee, T. C. Skalak, and S. M. Peirce. Differential arterial/venous expression of NG2 proteoglycan in perivascular cells along microvessels: identifying a venule-specific phenotype. Microcirculation. 12 (2):151-160, 2005.
S. M. Peirce, E. J. Van Gieson, and T. C. Skalak. Multicellular simulation predicts microvascular patterning and in silico tissue assembly. FASEB J 18 (6):731-733, 2004.
E. J. Van Gieson, W. L. Murfee, T. C. Skalak, and R. J. Price. Enhanced smooth muscle cell coverage of microvessels exposed to increased hemodynamic stresses in vivo. Circ Res 92 (8):929-936, 2003.
S. M. Peirce and T. C. Skalak. Microvascular remodeling: a complex continuum spanning angiogenesis to arteriogenesis. Microcirculation. 10 (1):99-111, 2003.
R. J. Price, J. R. Less, E. J. Van Gieson, and T. C. Skalak. Hemodynamic stresses and structural remodeling of anastomosing arteriolar networks: design principles of collateral arterioles. Microcirculation. 9 (2):111-124, 2002.
R. J. Price, G. K. Owens, and T. C. Skalak. Immunohistochemical identification of arteriolar development using markers of smooth muscle differentiation. Evidence that capillary arterialization proceeds from terminal arterioles. Circ Res 75 (3):520-527, 1994.
|
|
|
