Intramural delivery of Sirolimus prevents vascular remodeling following balloon injury.

OBJECTIVE: Several studies have demonstrated that Sirolimus-eluting stents reduce restenosis in patients with coronary artery disease. Here, we tested whether direct delivery of Sirolimus into the vessel wall during balloon angioplasty can modify vascular remodeling over several weeks. METHODS AND RESULTS: During angioplasty of the rabbit iliac artery we administered an intramural infusion of Sirolimus or its vehicle directly through a balloon catheter into the vessel wall. After 3 weeks neointimal formation was decreased (0.71+/-0.1 vs. 1.4+/-0.12 intima/media ratio), and this process was attributed to the inhibitory properties of Sirolimus on ECM deposition and smooth muscle cell proliferation. Sirolimus also significantly reduced the deposition of elastin, collagen III and fibronectin within the vascular wall. In parallel, proteomic profiles of arterial wall segments were obtained and 485 protein spots were consistently matched between non-dilated and dilated vessels. Differential expression of 12 proteins were observed between the groups and direct sequencing of digested peptides was performed. Local delivery of sirolimus during angioplasty attenuated the expression of structural proteins that included lamin A, vimentin, alpha-1-antitrypsin, and alpha-actin. CONCLUSIONS: Local administration of Sirolimus during angioplasty prevents smooth muscle cell proliferation associated with vascular remodeling as well as the expression of extracellular matrix and structural proteins. Therefore, local injection of Sirolimus during balloon inflation may be an alternative therapeutic approach for preventing restenosis in small stenotic vessels (i.e., <2.5 mm).

Identification of the adult human hemangioblast.

Recent studies show that human CD133(+) (previously known as AC133(+)) cells from mobilized peripheral blood consist of stem cells with either hematopoietic or endothelial potential. To test whether this population also contains individual precursors with both capacities, the defining characteristics of the elusive adult hemangioblast, we developed a culture system that allows single-cell analyses of differentiation. In the presence of vascular endothelial growth factor (VEGF), stem cell growth factor (SCGF), and FLT-3 ligand, CD133(+)-enriched cells were first expanded and the amplified cells were transduced with a vector encoding an enhanced green fluorescent protein (EGFP) marker gene. Single EGFP(+) cells were then cocultured with corresponding non-transduced cells from the same experiment, yielding 50-100 marked cells in 8% of the wells after 2 weeks. The resultant cells were divided and differentiated with either granulocyte colony-stimulating factor (G-CSF) or with SCGF and VEGF. These culture conditions resulted in the formation of neutrophil or endothelial cells, respectively, as identified morphologically and by phenotypic staining. Dual differentiation of EGFP(+) cells could be observed in one-quarter of clones from single-seeded cells, suggesting that 2% of EGFP(+) cells were in fact human hemangioblasts. These cells could be expanded for at least 28 days without losing this dual capacity. Hence, this culture system may be of clinical relevance in the development of cellular therapies for disorders involving hematopoiesis and the vascular system. In addition, our results provide important information related to the development of the vasculature and the potential role of hemangioblasts in vasculogenesis in adult humans.