Ultrasound-guided percutaneous delivery of tissue-engineered endothelial cells to the adventitia of stented arteries controls the response to vascular injury in a porcine model.

OBJECTIVE: High restenosis rates are a limitation of peripheral vascular interventions. Previous studies have shown that surgical implantation of a tissue-engineered endothelium onto the adventitia surface of injured vessels regulates vascular repair. In the present study, we developed a particulate formulation of tissue-engineered endothelium and a method to deliver the formulation perivascular to injured blood vessels using a percutaneous, minimally invasive technique. METHODS: Stainless steel stents were implanted in 18 balloon-injured femoral arteries of nine domestic swine, followed by ultrasound-guided percutaneous perivascular injection of gelatin particles containing cultured allogeneic porcine aortic endothelial cells (PAE). Controls received injections of empty particles (matrix) or no perivascular injection (sham) after stent deployment. Animals were sacrificed after 90 days. RESULTS: Angiographic analysis revealed a significantly greater lumen diameter in the stented segments of arteries treated with PAE/matrix (4.72 ± 0.12 mm) compared with matrix (4.01 ± 0.20 mm) or sham (4.03 ± 0.16 mm) controls (P < .05). Similarly, histologic analysis revealed that PAE/matrix-treated arteries had the greatest lumen area (20.4 ± 0.7 mm(2); P < .05) compared with controls (16.1 ± 0.9 mm(2) and 17.1 ± 1.0 mm(2) for sham and matrix controls, respectively) and the smallest intimal area (3.3 ± 0.4 mm(2); P < .05) compared with controls (6.2 ± 0.5 mm(2) and 4.4 ± 0.5 mm(2) for sham and matrix controls, respectively). Overall, PAE-treated arteries had a 33% to 50% decrease in percent occlusion (P < .05) compared with controls. Histopathological analysis revealed fewer leukocytes present in the intima in the PAE/matrix group compared with control groups, suggesting that the biological effects were in part due to inhibition of the inflammatory phase of the vascular response to injury. CONCLUSIONS: Minimally invasive, perivascular delivery of PAE/matrix to stented arteries was performed safely using ultrasound-guided percutaneous injections and significantly decreased stenosis. Application at the time of or subsequent to peripheral interventions may decrease clinical restenosis rates.

Delivery site of perivascular endothelial cell matrices determines control of stenosis in a porcine femoral stent model.

PURPOSE: Endothelial cells, grown within gelatin matrices and implanted onto the adventitia of injured vessels, inhibit stenosis in experimental models. To determine if this technology could be adapted for minimally invasive procedures, the authors compared the effects of cells in an implantable sponge to that of an injectable formulation and investigated the importance of delivery site in a stent model. MATERIALS AND METHODS: Stents were implanted in the femoral arteries of 30 pigs. This was followed by perivascular implantation of sponges or injection of particles containing allogeneic endothelial cells. Controls received acellular matrices or nothing. The effects of delivery site were assessed by injecting cellular matrices into or adjacent to the perivascular tissue or into the neighboring muscle. Animals were sacrificed after 28 days. Pre-sacrifice angiograms and tissue sections were evaluated for stenosis. RESULTS: Arteries treated with cellular matrices had a 55%-63% decrease in angiographic stenosis (P < .05) and a 38%-43% reduction in histologic stenoses (P < .05) compared to controls. Intimal area was greatest when cellular matrices were delivered into the muscle (6.35 mm(2) +/- 0.95) rather than into or adjacent to the perivascular tissue (4.05 mm(2) +/- 0.56 and 4.73 mm(2) +/- 0.53, respectively; P < .05). CONCLUSIONS: Perivascular endothelial cell matrices reduced stenosis after stent-induced injury. The effects were not dependent on the formulation but appeared to be dependent on delivery site. Minimally invasive injections of endothelial cell matrices to the adventitia of arteries following peripheral interventions may decrease restenosis rates.

Adventitial endothelial implants reduce matrix metalloproteinase-2 expression and increase luminal diameter in porcine arteriovenous grafts.

OBJECTIVE: Vascular access dysfunction is a major problem in hemodialysis patients. Only 50% of arteriovenous grafts (AVGs) will remain patent 1 year after surgery. AVGs frequently develop stenoses and occlusions at the venous anastomoses in the venous outflow tract. Lumen diameter is not only determined by intimal thickening but is also influenced by remodeling of the vessel wall. Vascular remodeling requires degradation and reorganization of the extracellular matrix by the degradation enzymes, matrix metalloproteinases (MMPs). In this study, we aimed to provide further insight into the mechanism of endothelial regulation of vascular remodeling and luminal narrowing in AVGs. METHODS: End-to-side carotid artery-jugular vein polytetrafluoroethylene grafts were created in 20 domestic swine. The anastomoses and outflow vein were treated with Gelfoam matrices (Pfizer, New York, NY) containing allogeneic porcine aortic endothelial (PAE, n = 10) cells or control matrices without cells (n = 10), and the biologic responses to PAE implants were investigated 3 and 28 days postoperatively. Angiograms before euthanasia were compared with baseline angiograms. Tissue sections were stained with hematoxylin and eosin, Verhoeff elastin, and antibodies specific to MMP-9 and MMP-2 and underwent histopathologic, morphometric and immunohistochemical analysis. RESULTS: Veins treated with PAE cell implants had a 2.8-fold increase in venous lumen diameter compared with baseline (P < .05), a 2.3-fold increase in lumen diameter compared with control, and an 81% decrease in stenosis (P < .05) compared with control at 28 days. The increase in lumen diameter by angiographic analysis correlated with morphometric analysis of tissue sections. PAE implants increased the venous lumen area 2.3-fold (P < .05), decreased venous luminal occlusion 66%, and increased positive venous remodeling 1.9-fold (P < .05) compared with control at 28 days. PAE cell implants reduced MMP-2 expression and neovascularization at 3 and 28 days and adventitial fibrosis at 28 days, suggesting a role of the implants in controlling the affects of medial and adventitial cells in the response to vascular injury. CONCLUSIONS: These results demonstrate that the adventitial application of endothelial implants significantly reduced MMP-2 expression within the venous wall, and increased venous lumen diameter and positive remodeling in a porcine arteriovenous graft model. Adventitial endothelial implants may be useful in decreasing luminal narrowing in a clinical setting.

Autologous skeletal myoblast transplantation improved hemodynamics and left ventricular function in chronic heart failure dogs.

BACKGROUND: Previous studies have suggested that autologous skeletal myoblast transplantation (ASMT) improves left ventricular (LV) function in small animals after myocardial infarction. We tested the effects of ASMT on hemodynamics, LV function and remodeling in coronary microembolization-induced chronic heart failure (CHF) in conscious dogs. METHODS: Nineteen dogs were continuously instrumented with LV pressure sensors and mid-myocardial sonomicrometry crystals for dP/dt(max) and LV volume determination. Each dog underwent baseline assessment in a conscious state. CHF (20% to 30% reduction in dP/dt(max) and LV end-diastolic pressure >16 mm Hg) was created by daily coronary microembolizations via a continuously implanted coronary catheter. Skeletal muscle biopsy was performed and myoblasts were isolated and expanded. Then 2.7 x 10(8) to 8.3 x 10(8) myoblasts were injected into the infarcted region of 11 dogs after establishment of CHF. Saline injection (sham) was performed in 8 control dogs. Animals were evaluated every 2 weeks for up to 10 weeks. Global ejection fraction was determined by echocardiography. The end-systolic pressure-end-systolic volume relationship (ESPVR) was analyzed by the Sonomicrometic system. RESULTS: Compared with saline injection, ASMT significantly increased dP/dt(max) (105 +/- 9% vs 97 +/- 7%, values were expressed as percentage change from baseline CHF, p = 0.013) and ejection fraction (46 +/- 3% vs 40 +/- 2%, p = 0.034) at 10 weeks after myoblast transplantation. There was a significant leftward and upward shift of the ESPVR back toward normal at 10 weeks after myoblast transplantation (p = 0.034). Three animals labeled with BrdU myoblasts showed no histologic evidence of viable engraftment. CONCLUSIONS: ASMT provided mild improvements in hemodynamics and LV function and reduced LV remodeling in conscious dogs with CHF.