Amina Arab scite author profile

Polymer stent coatings may not be suitable for drug elution because of inherent proinflammatory effects. A previous study suggested a beneficial effect of a stent eluting tacrolimus from a nanoporous ceramic aluminum oxide coating in a rabbit restenosis model. We investigated whether this stent is effective in preventing in-stent restenosis in a porcine restenosis model. Thirty-four juvenile swine underwent balloon overstretch injury and were subjected to implantation of either stainless steel (bare) stents, bare stents coated with nanoporous aluminum oxide alone, and coated stents eluting 50 and 180 mug of tacrolimus (FK506). In-stent restenosis was quantified at 1 and 3 months after stent placement by histomorphometry. A significant increase of neointimal hyperplasia was noted with the stents coated with aluminum oxide alone compared with bare stents (2.92 +/- 1.02 and 1.38 +/- 0.51 mm(2), respectively; P < 0.02). In all arteries containing coated stents, particle debris was found in the media and neointima, resulting in augmented vascular inflammation. In the group of stents coated with aluminum oxide, FK506 elution at a dose 180 mug reduced neointimal hyperplasia vs. no drug elution (1.66 +/- 0.49 vs. 2.92 +/- 1.02 mm(2); 180 mug vs. ceramic alone; P < 0.03). At a dose of 50 mug stent-based delivery of FK506, no reduction of neointimal hyperplasia was found (2.88 +/- 1.31 and 2.92 +/- 1.02 mm(2), respectively; P = NS; FK506 vs. ceramic alone). In summary, particle debris shed from a drug-eluting aluminum oxide coating of a stainless steel stent counteracts potential antiproliferative effects of stent-based tacrolimus delivery in a porcine model of restenosis. We propose that stent coatings eluting drugs need to be routinely tested for being tightly anchored into the stent surface. Alternatively, omission of any coating used as a drug reservoir may eliminate inflammatory particle debris after placement of drug-eluting stents.

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Zn-alloy provides a novel platform for mechanically stable bioresorbable vascular stents

Hehrlein

Schorch

Kress

et al. 2019

PLoS ONE

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Metallic Zn alloys have recently gained interest as potential candidates for developing platforms of bioresorbable vascular stents (BVS). Previous studies revealed that Mg alloys used for BVS can degrade too early, whereas PLLA materials may fail to provide effective scaffolding properties. Here we report on results of a new bioresorbable, metallic stent made from a Zn-Ag alloy studied in a porcine animal model of thrombosis and restenosis. While the tensile strength (MPa) of Zn-3Ag was higher than that of PLLA and resembled Mg’s (WE43), fracture elongation (%) of Zn-3Ag was much greater (18-fold) than the PLLA’s or Mg alloy’s (WE43). Zn-3Ag exposed to HAoSMC culture medium for 30 days revealed degradation elements consisting of Zn, O, N, C, P, and Na at a 6 nm surface depth. Platelet adhesion rates and blood biocompatibility did not differ between Zn-3Ag, PLLA, Mg (WE43), and non-resorbable Nitinol (NiTi) stent materials. Balloon-expandable Zn-3Ag alloy BVS implanted into iliofemoral arteries of 15 juvenile domestic pigs were easily visible fluoroscopically at implantation, and their bioresorption was readily detectable via X-ray over time. Histologically, arteries with Zn-3Ag BVS were completely endothelialized, covered with neointima, and were patent at 1, 3, and 6 months follow-up with no signs of stent thrombosis. Zn-3Ag alloy appears to be a promising material platform for the fabrication of a new generation of bioresorbable vascular stents.

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Differences of platelet adhesion and thrombus activation on amorphous silicon carbide, magnesium alloy, stainless steel, and cobalt chromium stent surfaces

Hansi

Arab

Rzany

et al. 2009

Cathet Cardio Intervent

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Drug-eluting stent: the "magic bullet" for prevention of restenosis?

Hehrlein¹,

Arab²,

Bode³

2002

Basic Research in Cardiology

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The need for repeat interventions after initially successful PTCA due to restenosis has been called the "Archilles heel" of a percutaneous revascularization procedure. The incidence of restenosis varies between 20-50 % depending on the stent material, the presence of risk factors, and the location of vascular disease. Some risk factors such as diabetes have been clearly identified, others are currently debated. After years of failures trying to reduces restenosis rates, locally administered antiproliferative means have been shown to successfully inhibit excessive cell growth in response to PTCA. Local radiotherapy of in-stent restenosis results in a reduction of recurrent stenosis versus a conventional PTCA procedure. However, long-term evaluation indicated that restenosis may only be delayed with radiation therapy. Moreover, the restenosis rates were reduced, but the restenotic process was not eliminated. Coronary stents eluting the anti-proliferative agent rapamycin have demonstrated for the first time, that restenosis rates of zero percent are achievable after percutaneous revascularization procedures. Thus, it is intriguing to believe that the elimination of restenosis may have become reality. The purpose of this review is to discuss, whether a stent eluting drugs should be considered as the "magic bullet" for prevention of restenosis after PTCA.

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Oxygenated Perfluorochemicals Improve Cell Survival during Reoxygenation by Pacifying Mitochondrial Activity

Arab

Kuemmerer²,

Wang³

et al. 2008

J Pharmacol Exp Ther

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Perfluorochemicals (PFCs) are known to provide a unique tool for controlled uptake and delivery of oxygen. We have characterized the effects of incremental oxygen delivery on cell viability of human ischemic cardiomyocytes using chemically inert PFCs as oxygen carrier. We have found that cell viability after prolonged ischemia depends on the dose of oxygen supplementation by oxygenated (ox) PFCs during reoxygenation. Although reoxygenation with the transient addition of oxPFCs in high concentrations (2250 M O 2 in 0.4 M PFCs) results in decreased cell viability compared with normoxic reoxygenation, cell survival increases by 30 Ϯ 4% after reoxygenation with moderate oxPFC concentrations (750 M O 2 in 0.1 M PFCs). Immunoblot analysis revealed that oxPFC-supplemented reoxygenation causes marked (16-fold) deactivation of death-associated protein kinase (DAPK) signaling an increase in mitochondrial membrane potential and a decreased steady-state level of superoxide by 19 Ϯ 3%. Reoxygenation with oxPFCs is further responsible for a 2-fold activation of AMP-activated protein kinase (AMPK) signaling an inadequate ATP supply by oxidative phosphorylation during reoxygenation. Addition of oxPFCs stabilizes both hypoxia-inducible factor (HIF) 1-␣ and 2-␣ during reoxygenation. Overall, these results indicate that moderate doses of oxPFCs can improve cell survival during reoxygenation, causing deactivation of DAPK, up-regulation of AMPK, and HIF1-␣ and 2-␣ stabilization. These effects of oxPFCs are dose-dependent, and they lead to a stabilization of the mitochondrial membrane potential, decreased steady-state levels of superoxide, and pacification of mitochondrial activity.

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Amina Arab

Particle debris from a nanoporous stent coating obscures potential antiproliferative effects of tacrolimus-eluting stents in a porcine model of restenosis

Zn-alloy provides a novel platform for mechanically stable bioresorbable vascular stents

Differences of platelet adhesion and thrombus activation on amorphous silicon carbide, magnesium alloy, stainless steel, and cobalt chromium stent surfaces

Drug-eluting stent: the "magic bullet" for prevention of restenosis?

Oxygenated Perfluorochemicals Improve Cell Survival during Reoxygenation by Pacifying Mitochondrial Activity

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