Effects of Endovascular Radiation From a β-Particle–Emitting Stent in a Porcine Coronary Restenosis Model

Abstract

Background Neointimal formation causes restenosis after intracoronary stent placement. Endovascular radiation delivered via a stent has been shown to reduce neointimal formation after placement in porcine and rabbit iliac arteries. The objective of this study was to evaluate the dose-related effects of a β-particle–emitting radioactive stent in a porcine coronary restenosis model. Methods and Results Thirty-seven swine underwent placement of 35 nonradioactive and 39 β-particle–emitting stents with activity levels of 23.0, 14.0, 6.0, 3.0, 1.0, 0.5, and 0.15 μCi of ³² P. Treatment effect was assessed by histological analysis 28 days after stent placement. Neointimal and medial smooth muscle cell density were inversely related to increasing stent activity. The neointima of the high-activity (3.0- to 23.0-μCi) stents consisted of fibrin, erythrocytes, occasional inflammatory cells, and smooth muscle cells with partial endothelialization of the luminal surface. In the 1.0-μCi stents, the neointima was expanded and consisted of smooth muscle cells and a proteoglycan-rich matrix. The neointima of the low-activity (0.15- and 0.5-μCi) stents was composed of smooth muscle cells and matrix with complete endothelialization of the luminal surface. At low and high stent activities, there was a reduction in neointimal area (low, 1.63±0.67 mm ² and high, 1.73±0.97 mm ² versus control, 2.40±0.87 mm ² ) and percent area stenosis (low, 26±7% and high, 26±12%) compared with control stents (37±12%, P ≤.01). The 1.0-μCi stents, however, had greater neointimal formation (4.67±1.50 mm ² ) and more luminal narrowing (64±16%) than the control stents ( P <.0001). Conclusions The differential response to the doses of continuous β-particle irradiation used in this experimental model suggests a complex biological interaction of endovascular radiation and vascular repair after stent placement. Further study is required to determine the clinical potential for this therapy to prevent stent restenosis.