I E Hoefer1, N van Royen, I R Buschmann, J J Piek, W Schaper. 1. Department of Experimental Cardiology, Max-Planck-Institute for Physiological and Clinical Research, Benekestr. 2, D-61231, Bad Nauheim, Germany. ihoefer@kerkhoff.mpg.de
Abstract
OBJECTIVE: We examined the time course of arteriogenesis (collateral artery growth) after femoral artery ligation and the effect of monocyte chemoattractant protein-1 (MCP-1). METHODS: New Zealand White rabbits received MCP-1 or phosphate buffered saline (PBS) for a 1-week period, either directly or 3 weeks after femoral artery ligation (non-ischemic model). A control group was studied with intact femoral arteries and another 1 min after acute femoral artery ligation. RESULTS: Collateral conductance index significantly increased when MCP-1 treatment started directly after femoral artery ligation (acute occlusion: 0.94+/-0.19; without occlusion: 168.56+/-15.99; PBS: 4.10+/-0.48; MCP-1: 33.96+/-1.76 ml/min/100 mmHg). However, delayed onset of treatment 3 weeks after ligation and final study of conductance at 4 weeks showed no significant difference against a 4-week control (PBS: 79.08+/-7.24; MCP-1: 90.03+/-8.73 ml/min/100 mmHg). In these groups increased conductance indices were accompanied by a decrease in the number of visible collateral vessels (from 18 to 36 identifiable vessels at day 7 to about four at 21 days). CONCLUSION: We conclude that the chemokine MCP-1 markedly accelerated collateral artery growth but did not alter its final extent above that reached spontaneously as a function of time. We show thus for the first time that a narrow time window exists for the responsiveness to the arteriogenic actions of MCP-1, a feature that MCP-1 may share with other growth factors. We show furthermore that the spontaneous adaptation by arteriogenesis stops when only about 50% of the vasodilatory reserve of the arterial bed before occlusion are reached. The superiority of few large arterial collaterals in their ability to conduct large amounts of blood flow per unit of pressure as compared to the angiogenic response where large numbers of small vessels are produced with minimal ability to allow mass transport of bulk flow is stressed.
OBJECTIVE: We examined the time course of arteriogenesis (collateral artery growth) after femoral artery ligation and the effect of monocyte chemoattractant protein-1 (MCP-1). METHODS: New Zealand White rabbits received MCP-1 or phosphate buffered saline (PBS) for a 1-week period, either directly or 3 weeks after femoral artery ligation (non-ischemic model). A control group was studied with intact femoral arteries and another 1 min after acute femoral artery ligation. RESULTS: Collateral conductance index significantly increased when MCP-1 treatment started directly after femoral artery ligation (acute occlusion: 0.94+/-0.19; without occlusion: 168.56+/-15.99; PBS: 4.10+/-0.48; MCP-1: 33.96+/-1.76 ml/min/100 mmHg). However, delayed onset of treatment 3 weeks after ligation and final study of conductance at 4 weeks showed no significant difference against a 4-week control (PBS: 79.08+/-7.24; MCP-1: 90.03+/-8.73 ml/min/100 mmHg). In these groups increased conductance indices were accompanied by a decrease in the number of visible collateral vessels (from 18 to 36 identifiable vessels at day 7 to about four at 21 days). CONCLUSION: We conclude that the chemokine MCP-1 markedly accelerated collateral artery growth but did not alter its final extent above that reached spontaneously as a function of time. We show thus for the first time that a narrow time window exists for the responsiveness to the arteriogenic actions of MCP-1, a feature that MCP-1 may share with other growth factors. We show furthermore that the spontaneous adaptation by arteriogenesis stops when only about 50% of the vasodilatory reserve of the arterial bed before occlusion are reached. The superiority of few large arterial collaterals in their ability to conduct large amounts of blood flow per unit of pressure as compared to the angiogenic response where large numbers of small vessels are produced with minimal ability to allow mass transport of bulk flow is stressed.
Authors: Hans-Joerg Busch; Stephan H Schirmer; Marco Jost; Sylvia van Stijn; Stephan L M Peters; Jan J Piek; Christoph Bode; Ivo R Buschmann; Guenter Mies Journal: J Cereb Blood Flow Metab Date: 2010-10-27 Impact factor: 6.200
Authors: June Yun; Petra Rocic; Yuh Fen Pung; Souad Belmadani; Ana Catarina Ribeiro Carrao; Vahagn Ohanyan; William M Chilian Journal: Antioxid Redox Signal Date: 2009-08 Impact factor: 8.401
Authors: Randolph W Seidler; Susanne Allgäuer; Susanne Ailinger; Andreas Sterner; Nagendu Dev; Dietmar Rabussay; Henri Doods; Martin C Lenter Journal: Pharm Res Date: 2005-09-22 Impact factor: 4.200
Authors: Guosong Hong; Jerry C Lee; Arshi Jha; Shuo Diao; Karina H Nakayama; Luqia Hou; Timothy C Doyle; Joshua T Robinson; Alexander L Antaris; Hongjie Dai; John P Cooke; Ngan F Huang Journal: Circ Cardiovasc Imaging Date: 2014-03-21 Impact factor: 7.792
Authors: Andreas Kampmann; Borja Fernández; Elisabeth Deindl; Thomas Kubin; Frederic Pipp; Inka Eitenmüller; Imo E Hoefer; Wolfgang Schaper; René Zimmermann Journal: Mol Cell Biochem Date: 2008-11-04 Impact factor: 3.396