Plaque neovascularization: defense mechanisms, betrayal, or a war in progress.

Angiogenesis is induced from sprouting of preexisting endothelial cells leading to neovascularization. Imbalance in the angiogenic and antiangiogenic mediators triggers angiogenesis, which may be physiological in the normal state or pathological in malignancy and atherosclerosis. Physiologic angiogenesis is instrumental for restoration of vessel wall normoxia and resolution inflammation, leading to atherosclerosis regression. However, pathological angiogenesis enhances disease progression, increasing macrophage infiltration and vessel wall thickness, perpetuating hypoxia and necrosis. In addition, thin-walled fragile neovessels may rupture, leading to intraplaque hemorrhage. Lipid-rich red blood cell membranes and free hemoglobin are detrimental to plaque composition, increasing inflammation, lipid core expansion, and oxidative stress. In addition, associated risk factors that include polymorphysms in the haptoglobin genotype and diabetes mellitus may modulate the features of plaque vulnerability. This review will focus on physiological and pathological angiogenesis in atherosclerosis and summarizes the current status of anti-vascular endothelial growth factor (VEGF) therapy, microvascular rarefaction, and possible statin-mediated effects in atherosclerosis neovascularization.

Increased macrophage infiltration and neovascularization in congenital bicuspid aortic valve stenosis.

OBJECTIVES: Patients with congenital bicuspid aortic valves have aortic valve stenosis at a relatively young age compared with patients with tricuspid aortic valves. We hypothesize that aortic valve stenosis evolves from a more aggressive inflammatory process, with increased macrophage/T-cell and neovessel content in congenital bicuspid aortic valveswhen compared with that seen in tricuspid valves. METHODS: Fifty-one severely stenotic aortic valves were obtained at the time of aortic valve replacement. A total of 17 bicuspid and 34 tricuspid aortic valves were evaluated. Macrophage/T-cell infiltration (CD68 plus CD3) and neovessel density (CD34) were evaluated with immunohistochemical staining. Leaflet calcification and ossification were also quantified. Real-time polymerase chain reaction was used to assess expression of chondromodulin 1 and vascular endothelial growth factor. RESULTS: The density of macrophages/T cells was greater in congenital bicuspid aortic valves than in tricuspid valves (51 ± 31 vs 23 ± 13 cells/mm(2), P = .002). Neovascularization was more frequently noted in congenital bicuspid aortic valves when compared with tricuspid valves (31 ± 10 vs 21 ± 9 vessels/mm(2), P = .0005), and calcification was more severe (P = .03). Expression of chondromodulin 1 demonstrated a 6-fold downregulation (P = .0003) and expression of vascular endothelial growth factor demonstrated a 2-fold increase (P = .02) in congenital bicuspid aortic valves compared with that seen in tricuspid valves. Multivariable analyses demonstrated significant associations between bicuspid aortic valve anatomy and increased inflammatory cell infiltration (ß = 25.8, P = .0007) and neovascularization (ß = 9.4, P = .001), despite adjusting for measured covariates. CONCLUSIONS: The pathogenesis of aortic valve stenosis in bicuspid aortic valves is associated with a more aggressive inflammatory process with increased macrophage infiltration and neovascularization when compared with that seen in tricuspid valves.