[Drug-eluting stents do they make the difference? ]. / Gli stent ricoperti di farmaci fanno davvero la differenza?

The main limitation to further expansion of PTCI (percutaneous transluminal coronary intervention) is restenosis that occurs in 30% of the patients within 6-months after the procedure. Coronary stenting decreases the percent of restenosis due to arterial remodeling after PTCI but proliferation of smooth muscle cells due to vascular injury still remains. A mechanical approach the only treatment up to now (further balloon expansion, plaque removal with rotablator or directional atherectomy) failed. Because the restenotic process is due to a complex series of biological events which start with platelet aggregation, grow-factors and cytochine release, the use of antiflammatory, antithrombotic and antiproliferative drugs were attempted. Cortisone and heparin showed low benefits in clinical trial. New drugs (rapamycin, taxol, actinomycin D, tacrolimus, estradiol, dexamethazone) with antiproliferative and antiflammatory activities are under evaluation. They act as inhibitors of the cell migration and of the cell cicle progression with different specific molecular mechanisms. The first pilot study performed in 45 patients with sirolimus-eluting stents has shown a sustained suppression (25% in the fast release group and 23% in the slow release group) of neointimal formation at 12 months after procedure with absence of restenosis. The Ravel study, a randomized trial, has enrolled 238 patients treated with sirolimus coated stent vs a control group: the results confirm the previous data with a complete suppression of intimal hyperproliferation and restenosis at six months follow-up. The first 400 patients treated in the Sirius trial a similar study which will randomize 1100 pts show a low, but not a complete inhibition of the restenotic process probably due to a more complexity of the lesions treated in comparison to Ravel trial (9.2% of restenosis). Another very promising drug is taxol (paclitaxel). It is an antiproliferative and antinflammatory molecule tested in a series of clinical trials called Taxus. The still unpublished data of TAXUS I and TAXUS II randomized trial show extremely low restenosis rate. Other drugs (actinomycin D, estradiol, tacrolimus, dexamethazone) show to have a potential effect on restenosis and neointimal proliferation and are under investigation. Is very important to maintain lessons learned from the past. The design, the type, the smooth surface of the stent still remains very important as it is a good expansion and a full coverage of the lesions with a "good stent" in the attempt to reduce restenosis. Drug-eluting stents will add further improvement.

Growth of human melanoma xenografts is suppressed by systemic angiostatin gene therapy.

The effect of local and systemic delivery of the angiostatin gene on human melanoma growth was studied in nude mice. Liposome-coated plasmids carrying the cDNA coding for murine and human angiostatin (CMVang and BSHang) were injected weekly, locally or systemically, in mice transplanted with melanoma cells. The treatment reduced melanoma growth by 50% to 90% compared to that occurring in control animals treated with liposome-coated plasmid carrying the lacZ gene or in untreated controls. The growth of both locally injected and controlateral uninjected tumors in mice bearing two melanoma grafts was significantly suppressed after intratumoral treatment. Tumor growth inhibition was also observed in mice treated by intraperitoneal delivery, suggesting that angiostatin gene therapy acts through a systemic effect. Both melanoma growth suppression and delay in the onset of tumor growth were observed in treated mice. PCR performed on tumors and normal tissues showed that the lipofected DNA was present in tissues from treated mice, and angiostatin expression was demonstrated by RT-PCR. Histopathological analysis of melanoma nodules revealed an increase in apoptotic cells and a reduction in vessel density in tumors from treated mice. Our results suggest that systemic, liposome-mediated administration of genes coding for antiangiogenic factors represents a promising strategy for melanoma treatment in humans.