Wall tissue remodeling regulates longitudinal tension in arteries.

Changes in blood pressure or flow induce arterial remodeling that normalizes mechanical loads that are imposed on arterial tissue. Arteries are also under substantial longitudinal stretch (axial strain) that may be altered by growth or atrophy of tissues to which they are attached. We therefore tested whether axial strain is also regulated in a negative feedback manner through arterial remodeling. Axial strain in rabbit carotid arteries was increased from 62+/-2% to 97+/-2% without altering other mechanical loads on wall tissues. Strain was reduced within 3 days and completely normalized by 7 days. Remodeling involved tissue elaboration, endothelial cell replication rates were increased by >50-fold and smooth muscle cell replication rates were increased by >15-fold, and substantially elevated DNA, elastin, and collagen contents were recorded. Also, increased rates of apoptosis were indicated by degradation of DNA into oligonucleosomes, and matrix remodeling was reflected in enlarged fenestrae in the internal elastic lamina and increased expression and activation of gelatinases, especially matrix metalloproteinase-2. Intriguingly, reduced axial strain was not normalized, presumably because remodeling processes, apart from cell contraction, are ineffective in decreasing strain, and arterial smooth muscle orientation precludes large effects of contraction on axial strain.

Partial off-loading of longitudinal tension induces arterial tortuosity.

OBJECTIVES: Arterial tortuosity is a frequent manifestation of vascular disease and collateral vessel growth, but its causes are poorly understood. This study was designed to assess the relationship between the development of tortuosity and the mechanical forces that are imposed on arterial tissue. METHODS AND RESULTS: Axial strain in rabbit carotid arteries was reduced from 62+/-2% to 33+/-2% by implanting an interposition graft, prepared from the contralateral carotid, at the downstream end of the artery. Axial strain remained unchanged for 12 weeks; however, all vessels became tortuous because of tissue growth and remodeling. After 7 days, there was a marked elevation in proliferation rates of endothelial and smooth muscle cells; however, increased apoptosis was also detected, and no net accumulation of DNA was observed. Significant accumulations of elastin (24%) and total collagen (26%) occurred by 5 weeks. Gelatin zymography detected upregulation and activation of matrix metalloproteinase-2 (MMP-2), and confocal microscopy revealed enlargement of fenestrae in the internal elastic lamina. MMP inhibition by treatment with doxycycline prevented enlargement of fenestrae and development of tortuosity, and it enabled normalization of axial strain by 5 weeks. CONCLUSIONS: These findings indicate that substantial axial strain is necessary to sustain the morphological stability of arteries, and that a reduction in strain results in arterial tortuosity attributable to aberrant MMP activity.

Collagenase plaque digestion for facilitating guide wire crossing in chronic total occlusions.

BACKGROUND: Chronic total occlusions (CTOs) are associated with significant angina, impaired left ventricular function, and worse long-term outcomes. Percutaneous coronary interventions in CTO are unsuccessful in up to 50% of cases, primarily because of inability to cross the lesion with a guide wire. Collagen is the predominant component of the atherosclerotic plaque. The objective of this study was to determine the efficacy and toxicity of local delivery of a collagen-degrading enzyme to facilitate guide wire crossing in CTO. METHODS AND RESULTS: Type IA collagenase (100 or 450 microg) or placebo was locally administered to 45 CTOs in a rabbit femoral artery model. Mean occlusion duration was 16+/-5 weeks. Attempts to cross the CTO (mean length, 28+/-9 mm) with conventional guide wires were assessed at 72 hours after treatment. An additional 3 arteries per group were assessed for collagenase effects at 24 hours after treatment. Successful guide wire crossings were significantly higher in collagenase-treated arteries (13 of 21, 62%) than in placebo-treated arteries (7 of 24, 29%) (P=0.028). No adverse effects on arterial structure were observed in collagenase-treated arteries. At 24 hours, collagenase-treated arteries demonstrated increased collagenase protein, gelatinase activity, and collagen fragments. CONCLUSIONS: Local delivery of collagenase can safely facilitate guide wire crossing of CTO. This novel approach could lead to higher percutaneous coronary intervention success rates in CTO.

Recombinant factor VIIa affects anastomotic patency of vascular grafts in a rabbit model.

OBJECTIVE: Recombinant factor VIIa can decrease postoperative bleeding after cardiac surgery. However, the potential for recombinant factor VIIa to cause early vascular graft occlusion at the site of new vascular anastomoses has not been fully explored. We hypothesized that recombinant factor VIIa would cause a dose-dependent reduction in vascular graft patency in rabbits. METHODS: Reversed end-to-end interpositional vein grafts were sutured into the carotid artery of heparinized rabbits, and then recombinant factor VIIa (300 µg/kg, 90 µg/kg, or 20 µg/kg intravenously) or placebo was administered (n = 16/group). Graft patency was assessed at 24 hours using a vascular ultrasound probe. Factor VII activity levels were measured using a prothrombin time-based assay. In different rabbits, the patency of venous end-to-side anastomoses and simple carotid arterial repairs was assessed (recombinant factor VIIa, 300 µg/kg vs placebo, n = 8/group). Data were analyzed using Fisher's exact test, t tests, or analysis of variance. RESULTS: Physiologic variables (activated clotting time, hemoglobin, pH, Pao(2)) and vessel diameter were not different between groups. Vein graft patency was reduced (93.8%, 81.2%, 13.8%, and 6.3%) as factor VII activity levels increased (1.8 ± 0.4, 4.4 ± 2.1, 11.8 ± 4.7, and 23.6 ± 16.9 U/mL, respectively) with increasing doses of recombinant factor VIIa administered (0, 20, 90, and 300 µg/kg, respectively, P < .05). Patency in the arterial repairs and end-to-side venous grafts was also reduced in recombinant factor VIIa-treated rabbits (P < .05 for both). CONCLUSIONS: This study suggests that recombinant factor VIIa is associated with a dose-dependent increase in fresh vascular graft occlusion. Higher doses of recombinant factor VIIa may be associated with increased thrombotic outcomes.

Expansive remodeling in venous bypass grafts: novel implications for vein graft disease.

OBJECTIVE: To date, intimal hyperplasia has been regarded as the principle mechanism responsible for subsequent vein graft disease. Lumen remodeling has not been previously considered as an additional mechanism. The objectives of this study were to determine changes in lumen remodeling in arterialized vein grafts, the accompanying cellular and extracellular matrix events contributing to remodeling, and the effects of a high cholesterol diet. METHODS AND RESULTS: Reversed jugular vein-to-common carotid artery interposition grafts were constructed in 70 normocholesterolemic and 11 hypercholesterolemic male New Zealand white rabbits. The lumen area initially remained unchanged between 1 and 4 weeks but significantly increased by 40% at 12 weeks. This phase of expansive positive remodeling was accompanied by significantly increased cell apoptosis, collagen synthesis (1.7-fold), collagen content (3.7-fold), gelatinase (MMP-2 and MMP-9) levels and decreased tissue inhibitor of metalloproteinase (TIMP) levels. Expansive remodeling temporally corresponded to high macrophage infiltration and increased low density lipoprotein (LDL) retention (fourfold) in the vein grafts. A high cholesterol diet stimulated early macrophage infiltration and increased MMP-12 (metalloelastase) levels, which was associated with earlier onset of expansive remodeling. CONCLUSION: Expansive lumenal remodeling is a novel mechanism of vein graft response to the arterial circulation, which is accelerated by a high cholesterol diet.