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Abstract
This article will discuss the lessons learned by using stents implanted with low activities of radioisotopes to prevent in-stent restenosis. A continuous low-dose rate radiation delivered by radioisotope stents has been shown to reduce the proliferative activity of smooth muscle cells and to inhibit neointimal growth. However, the radiation also delays endothelialization of the stents. Both the dose rate and the cumulative dose delivered by radioisotope stents appear to affect outcome. The neointima covering radioactive stents is characterized by a reduced cellularity, increased amounts of fibrin and extracellular matrix proteins. Aneurysm formation or excessive tissue destruction due to the radiation were not observed. Animals studies including up to 1 year follow-up periods suggest that beta-particle-radiation as well as gamma-radiation are effective in reducing neointimal hyperplasia. It is still unknown, however, which range of activities are needed and if a combination of radioisotopes, i.e. with short and long halflives, further reduce neotima formation over the long-term. An appropriate stent design for homogenous dose distribution around the stent may be important, i.e. articulations or large cell sizes may have disadvantages. Augmented neointima formation at the ends of radioactive stents, in particular when using beta-particle emitting stents, has been observed in animal models. Future studies will focus on the effects of increasing activity levels at the stent ends, optimal stent designs, alternative isotopes and different dosing strategies.