Inhibitory effect of n-butylidenephthalide on neointimal hyperplasia in balloon injured rat carotid artery.

This investigation was designed to determine the inhibitory effects and mechanisms of n-butylidenephthalide (BP) from Angelica sinensis on smooth muscle cell (SMC) proliferation in vitro and in balloon injured rat carotid artery. Treatment of cultured rat aorta SMC-derived A7r5 cells with 25-100 µg/mL BP significantly inhibited the proliferation and arrested the cell cycle in G(0)/G(1) phase. BP induced the expression and migration of Nur77 from the nucleus to the cytoplasm. Among signal pathways, JNK and p38 MAPK were phosphorylated after BP treatment. In vivo, the neointimal area of common carotid artery 2 weeks after balloon injury reduced significantly in Sprague-Dawley rats treated with 150-300 mg/kg BP compared with the control. The proliferative activity indicated by immunohistochemical detection of Ki-67 positive cells in the neointima was significantly decreased in the 60-300 mg/kg BP treatment groups. The apoptotic activity indicated by cleaved caspase-3 positive cells and Nur77 positive cells in the neointima was significantly increased in rats treated with 60-300 mg/kg BP. This study demonstrated BP inhibited neointimal hyperplasia in balloon injured rat carotid artery due to its dual effects of proliferative inhibition and apoptotic induction on SMCs. Up-regulation of Nur77 gene may partly explain the antihyperplasia activity of BP on the neointima.

In vivo cardiovascular assays for drug discovery: evolution of the drug-eluting stent.

Percutaneous intervention using balloon angioplasty accompanied by stent implantation has become the predominant procedure to treat occlusive coronary and peripheral vascular disease. Unfortunately, restenosis associated with intimal hyperplasia and arterial remodeling at the stented site occurs within 6 months in 20 to 30% of cases. To address this problem, the concept of utilizing a stent as the vehicle to deliver agents locally and limit the overexuberant tissue response related to its placement has been developed. Targeting excess arterial wall smooth muscle cell proliferation, preclinical studies have demonstrated the efficacy of two drugs, paclitaxel and rapamycin, in both in vitro and in vivo animal studies. Early, as well as large, randomized clinical studies using polymer-coated, drug-eluting stents have clearly demonstrated a significant and dramatic efficacy in reducing restenosis rates and improving clinical outcomes compared with the use of the bare stent for revascularization procedures. Despite the low incidence of late thrombosis associated with the rapamycin- and paclitaxel-eluting stents, some concerns remain (such as the need for sustained anticoagulant therapy), providing the impetus for developing coated stents that promote rather than inhibit endothelial healing in order to limit the restenotic response.

Drug-eluting stents studies in mice: do we need atherosclerosis to study restenosis?

In 2001, the first human study with drug-eluting stents (DES) was published showing a nearly complete abolition of restenosis by using a sirolimus-eluting stent. This success was very encouraging to test new compounds in combination with the DES platform. Nevertheless, several other anti-restenotic compounds have been used in human clinical trials with disappointing outcomes. Little is known concerning potential adverse effects on vessel wall integrity and (re)healing, atherosclerotic lesion formation, progression, and plaque stability of these DES. Although efficacy and safety need to be determined clinically, preclinical testing of candidate drugs in well-defined animal models is extremely helpful to gain insight into the basic biological responses to candidate compounds. Here, we discuss and report an animal model which enables rapid screening of candidate drugs for DES on an atherosclerotic background. The results from drug testing using this novel model could help to quickly and cost-effectively establish the dose range of candidate drugs with reasonable potential for DES.

Preclinical restenosis models: challenges and successes.

Coronary artery disease remains a major problem for Western societies. The advent of percutaneous interventions, including stents has brought clinical care to a new level of efficacy, yet problems remain. Restenosis following stenting in human coronary arteries appears at last to be yielding to therapeutic strategies, especially drug eluting stents. Because therapeutic percutaneous coronary intervention is widely dominated by the intracoronary stent, restenosis therapies must include the stented coronary artery. Animal models and in particular the porcine coronary model seem to represent the human coronary artery reaction to stenting. It mimics several clinical conditions including thrombosis and neointimal formation. A key question in the era of intravascular technologies is how well this and other models can predict clinical events. This paper discusses the models and their application.