The Range of Adaptation by Collateral Vessels After Femoral Artery Occlusion
Natural adaptation to femoral artery occlusion in animals by collateral artery growth restores only ≈35% of adenosine-recruitable maximal conductance (Cmax) probably because initially elevated fluid shear stress (FSS) quickly normalizes. We tested the hypothesis whether this deficit can be mended by...
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| Published in | Circulation research Vol. 99; no. 6; pp. 656 - 662 |
|---|---|
| Main Authors | , , , , , , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
Hagerstown, MD
American Heart Association, Inc
15.09.2006
Lippincott |
| Subjects | |
| Online Access | Get full text |
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| Abstract | Natural adaptation to femoral artery occlusion in animals by collateral artery growth restores only ≈35% of adenosine-recruitable maximal conductance (Cmax) probably because initially elevated fluid shear stress (FSS) quickly normalizes. We tested the hypothesis whether this deficit can be mended by artificially increasing FSS or whether anatomical restraints prevent complete restitution. We chronically increased FSS by draining the collateral flow directly into the venous system by a side-to-side anastomosis between the distal stump of the occluded femoral artery and the accompanying vein. After reclosure of the shunt collateral flow was measured at maximal vasodilatation. Cmax reached 100% already at day 7 and had, after 4 weeks, surpassed (2-fold) the Cmax of the normal vasculature before occlusion. Expression profiling showed upregulation of members of the Rho-pathway (RhoA, cofilin, focal adhesion kinase, vimentin) and the Rho-antagonist Fasudil markedly inhibited arteriogenesis. The activities of Ras and ERK-1,-2 were markedly increased in collateral vessels of the shunt experiment, and infusions of L-NAME and L-NNA strongly inhibited MAPK activity as well as shunt-induced arteriogenesis. Infusions of the peroxinitrite donor Sin-1 inhibited arteriogenesis. The radical scavengers urate, ebselen, SOD, and catalase had no effect. We conclude that increased FSS can overcome the anatomical restrictions of collateral arteries and is potentially able to completely restore maximal collateral conductance. Increased FSS activates the Ras-ERK-, the Rho-, and the NO- (but not the Akt-) pathway enabling collateral artery growth. |
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| AbstractList | Natural adaptation to femoral artery occlusion in animals by collateral artery growth restores only approximately 35% of adenosine-recruitable maximal conductance (C(max)) probably because initially elevated fluid shear stress (FSS) quickly normalizes. We tested the hypothesis whether this deficit can be mended by artificially increasing FSS or whether anatomical restraints prevent complete restitution. We chronically increased FSS by draining the collateral flow directly into the venous system by a side-to-side anastomosis between the distal stump of the occluded femoral artery and the accompanying vein. After reclosure of the shunt collateral flow was measured at maximal vasodilatation. C(max) reached 100% already at day 7 and had, after 4 weeks, surpassed (2-fold) the C(max) of the normal vasculature before occlusion. Expression profiling showed upregulation of members of the Rho-pathway (RhoA, cofilin, focal adhesion kinase, vimentin) and the Rho-antagonist Fasudil markedly inhibited arteriogenesis. The activities of Ras and ERK-1,-2 were markedly increased in collateral vessels of the shunt experiment, and infusions of L-NAME and L-NNA strongly inhibited MAPK activity as well as shunt-induced arteriogenesis. Infusions of the peroxinitrite donor Sin-1 inhibited arteriogenesis. The radical scavengers urate, ebselen, SOD, and catalase had no effect. We conclude that increased FSS can overcome the anatomical restrictions of collateral arteries and is potentially able to completely restore maximal collateral conductance. Increased FSS activates the Ras-ERK-, the Rho-, and the NO- (but not the Akt-) pathway enabling collateral artery growth. Natural adaptation to femoral artery occlusion in animals by collateral artery growth restores only ≈35% of adenosine-recruitable maximal conductance (Cmax) probably because initially elevated fluid shear stress (FSS) quickly normalizes. We tested the hypothesis whether this deficit can be mended by artificially increasing FSS or whether anatomical restraints prevent complete restitution. We chronically increased FSS by draining the collateral flow directly into the venous system by a side-to-side anastomosis between the distal stump of the occluded femoral artery and the accompanying vein. After reclosure of the shunt collateral flow was measured at maximal vasodilatation. Cmax reached 100% already at day 7 and had, after 4 weeks, surpassed (2-fold) the Cmax of the normal vasculature before occlusion. Expression profiling showed upregulation of members of the Rho-pathway (RhoA, cofilin, focal adhesion kinase, vimentin) and the Rho-antagonist Fasudil markedly inhibited arteriogenesis. The activities of Ras and ERK-1,-2 were markedly increased in collateral vessels of the shunt experiment, and infusions of L-NAME and L-NNA strongly inhibited MAPK activity as well as shunt-induced arteriogenesis. Infusions of the peroxinitrite donor Sin-1 inhibited arteriogenesis. The radical scavengers urate, ebselen, SOD, and catalase had no effect. We conclude that increased FSS can overcome the anatomical restrictions of collateral arteries and is potentially able to completely restore maximal collateral conductance. Increased FSS activates the Ras-ERK-, the Rho-, and the NO- (but not the Akt-) pathway enabling collateral artery growth. Natural adaptation to femoral artery occlusion in animals by collateral artery growth restores only ≈35% of adenosine-recruitable maximal conductance (C max ) probably because initially elevated fluid shear stress (FSS) quickly normalizes. We tested the hypothesis whether this deficit can be mended by artificially increasing FSS or whether anatomical restraints prevent complete restitution. We chronically increased FSS by draining the collateral flow directly into the venous system by a side-to-side anastomosis between the distal stump of the occluded femoral artery and the accompanying vein. After reclosure of the shunt collateral flow was measured at maximal vasodilatation. C max reached 100% already at day 7 and had, after 4 weeks, surpassed (2-fold) the C max of the normal vasculature before occlusion. Expression profiling showed upregulation of members of the Rho-pathway (RhoA, cofilin, focal adhesion kinase, vimentin) and the Rho-antagonist Fasudil markedly inhibited arteriogenesis. The activities of Ras and ERK-1,-2 were markedly increased in collateral vessels of the shunt experiment, and infusions of L-NAME and L-NNA strongly inhibited MAPK activity as well as shunt-induced arteriogenesis. Infusions of the peroxinitrite donor Sin-1 inhibited arteriogenesis. The radical scavengers urate, ebselen, SOD, and catalase had no effect. We conclude that increased FSS can overcome the anatomical restrictions of collateral arteries and is potentially able to completely restore maximal collateral conductance. Increased FSS activates the Ras-ERK-, the Rho-, and the NO- (but not the Akt-) pathway enabling collateral artery growth. |
| Author | Cai, Wei-Jun Schmitz-Rixen, Thomas Schaper, Wolfgang Fischer, Silvia Eitenmüller, Inka Troidl, Kerstin Horrevoets, Anton J.G Kluge, Alexander Pipp, Frederic Barancik, Miroslav Volger, Oscar Heil, Matthias |
| AuthorAffiliation | From the Max-Planck-Institute for Heart and Lung Research (I.E., K.T., M.H., F.P., W.S.), Bad Nauheim, Germany; Department of Medical Biochemistry, Academic Medical Centre (O.V., A.J.G.H.), University of Amsterdam, The Netherlands; Kerckhoff Clinic (A.K.), Bad Nauheim, Germany; Division of Vascular and Endovascular Surgery (T.S.), Goethe-University of Frankfurt/Main, Germany; Slovak Academy of Sciences (M.B.), Bratislava, Slovakia; Department of Anatomy, Xiangsha School of Medicine (W.C.), Central South University, Xiangsha, Hunan, P.R. China; Department of Medical Biochemistry (S.F.), Liebig-University Giessen, Germany |
| AuthorAffiliation_xml | – name: From the Max-Planck-Institute for Heart and Lung Research (I.E., K.T., M.H., F.P., W.S.), Bad Nauheim, Germany; Department of Medical Biochemistry, Academic Medical Centre (O.V., A.J.G.H.), University of Amsterdam, The Netherlands; Kerckhoff Clinic (A.K.), Bad Nauheim, Germany; Division of Vascular and Endovascular Surgery (T.S.), Goethe-University of Frankfurt/Main, Germany; Slovak Academy of Sciences (M.B.), Bratislava, Slovakia; Department of Anatomy, Xiangsha School of Medicine (W.C.), Central South University, Xiangsha, Hunan, P.R. China; Department of Medical Biochemistry (S.F.), Liebig-University Giessen, Germany |
| Author_xml | – sequence: 1 givenname: Inka surname: Eitenmüller fullname: Eitenmüller, Inka organization: From the Max-Planck-Institute for Heart and Lung Research (I.E., K.T., M.H., F.P., W.S.), Bad Nauheim, Germany; Department of Medical Biochemistry, Academic Medical Centre (O.V., A.J.G.H.), University of Amsterdam, The Netherlands; Kerckhoff Clinic (A.K.), Bad Nauheim, Germany; Division of Vascular and Endovascular Surgery (T.S.), Goethe-University of Frankfurt/Main, Germany; Slovak Academy of Sciences (M.B.), Bratislava, Slovakia; Department of Anatomy, Xiangsha School of Medicine (W.C.), Central South University, Xiangsha, Hunan, P.R. China; Department of Medical Biochemistry (S.F.), Liebig-University Giessen, Germany – sequence: 2 givenname: Oscar surname: Volger fullname: Volger, Oscar – sequence: 3 givenname: Alexander surname: Kluge fullname: Kluge, Alexander – sequence: 4 givenname: Kerstin surname: Troidl fullname: Troidl, Kerstin – sequence: 5 givenname: Miroslav surname: Barancik fullname: Barancik, Miroslav – sequence: 6 givenname: Wei-Jun surname: Cai fullname: Cai, Wei-Jun – sequence: 7 givenname: Matthias surname: Heil fullname: Heil, Matthias – sequence: 8 givenname: Frederic surname: Pipp fullname: Pipp, Frederic – sequence: 9 givenname: Silvia surname: Fischer fullname: Fischer, Silvia – sequence: 10 givenname: Anton surname: Horrevoets middlename: J.G fullname: Horrevoets, Anton J.G – sequence: 11 givenname: Thomas surname: Schmitz-Rixen fullname: Schmitz-Rixen, Thomas – sequence: 12 givenname: Wolfgang surname: Schaper fullname: Schaper, Wolfgang |
| BackLink | http://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&idt=18139710$$DView record in Pascal Francis https://www.ncbi.nlm.nih.gov/pubmed/16931799$$D View this record in MEDLINE/PubMed |
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| Keywords | Femoral artery shunt growth factors arteriogenesis microarrays Vertebrata Mammalia Shear stress Circulatory system Artery occlusion Adaptation Growth factor fluid shear stress |
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| Snippet | Natural adaptation to femoral artery occlusion in animals by collateral artery growth restores only ≈35% of adenosine-recruitable maximal conductance (Cmax)... Natural adaptation to femoral artery occlusion in animals by collateral artery growth restores only approximately 35% of adenosine-recruitable maximal... Natural adaptation to femoral artery occlusion in animals by collateral artery growth restores only ≈35% of adenosine-recruitable maximal conductance (C max )... |
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| SubjectTerms | Adaptation, Physiological Animals Arterial Occlusive Diseases - physiopathology Arteries - growth & development Biological and medical sciences Cells, Cultured Collateral Circulation - physiology Femoral Artery - pathology Fundamental and applied biological sciences. Psychology Gene Expression Profiling Mitogen-Activated Protein Kinases - genetics Muscle, Smooth, Vascular - cytology Neovascularization, Physiologic - genetics Rabbits Regional Blood Flow rho GTP-Binding Proteins - genetics Stress, Mechanical Up-Regulation - genetics Vertebrates: cardiovascular system |
| Title | The Range of Adaptation by Collateral Vessels After Femoral Artery Occlusion |
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