Ultrastructural characteristics of human atherectomy tissue from coronary and lower extremity arterial stenoses

In animal studies, smooth muscle cell phenotype conversion has been suggested to be an essential prerequisite for subsequent migratory and proliferative events leading to (neo)intima formation. To determine ultrastructural characteristics of individual smooth muscle cells and to relate them to specific lesion types and intimai cell density, we compared atherectomy samples from 17 restenotic and 32 primary coronary and peripheral lesions using transmission electron microscopy and histology. Ultrastructural analysis of cell-rich tissue, predominantly of restenotic origin, revealed smooth muscle cells full of synthetic organelles. Moreover, these cells were frequently found to be surrounded by loose extracellular matrix and partially fragmented basement membrane components. In contrast, plaques exhibiting low cell density, as exclusively seen with primary lesions, displayed an extensive buildup of extracellular matrix containing sparse numbers of microfilament-rich smooth muscle cells. The central finding of our study is a morphometrically quantitated, twofold greater (p < 0.001) volume fraction of synthetic organelles (Vs) within smooth muscle cells in restenotic versus primary plaques, indicating a more dedifferentiated cellular phenotype as a typical feature of restenotic lesions. Equally enhanced Vs values were seen for restenotic coronary and peripheral plaques. No Vs decrease was observed during time after angioplasty (2.2 to 30 months) regardless of previous revascularization procedures (balloon angioplasty or atherectomy). Despite intra- and interlesional variability, Vs and intimal cell density were strongly correlated (r = 0.74; p < 0.001). This correlation was observed more often with clinical restenoses and, importantly, in a portion (10% to 15%) of primary lesions. Data from restenotic lesions indicate that a dedifferentiated smooth muscle cell phenotype, pericellular matrix disintegration, and intimal hypercellularity are long-lasting biologic responses to previous smooth muscle cell injury. Similar tissue characteristics expressed in several primary lesions suggest that comparable pathogenic mechanisms are related to the progression and/or acuity of chronic lesions.