Fabrication of micropored elastomeric film‐covered stents and acute‐phase performances

Nakayama, Yasuhide; Nishi, Shogo; Ueda-Ishibashi, Hatsue; Matsuda, Takehisa

doi:10.1002/jbm.a.10314

Cited by 26 publications

(11 citation statements)

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“…This raises questions on how PMMPI interacts with MMPs at the liquid-solid interface or whether the MMPI binding to the zinc ion located at the active site of the MMP is a reversible reaction or not. Irrespective of these processes, however, the present results support the reasonable application of PMMPI as a coating for metal stents and polymer-covered stents 32,33 to prevent restenosis after stent implantation. An additional advantage is the extremely low drug concentrations in blood and high local concentration at the treatment site provided by this polymer, which is a potentially significant prerequisite for DES.…”

Section: Discussionsupporting

confidence: 65%

Development of a polymeric matrix metalloproteinase inhibitor as a bioactive stent coating material for prevention of restenosis

Nakayama

Masuda

2006

J Biomed Mater Res

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Abstract:Drug-eluting stents have been developed to prevent restenosis derived from excessive growth of smooth muscle cells (SMCs) after stenting. In almost every case, however, less-or non-biocompatible polymers were selected for the platform material for impregnating drugs on the stent strut. Consideration was given principally to the physical properties of the polymers, such as their adhesion to the strut and the drug dispersibility in the polymeric matrix. In this study, we designed a matrix metalloproteinase inhibitor (MMPI)-derivatized hydrophobic polymer (PMMPI) for use as a bioactive material for stent coating. This was a copolymer of n-butylmethacrylate and a vinyl monomer of synthetic MMPI (N-Hydroxy-5- carboxyethylcarbonyloxy-2(S)-methy-4(S)-(4-phenoxybenzoyl)amino-pentanamide:ONO-M11-335) with a molecular weight of about 32,000 and MMPI content of 45 per molecule. The precursor of the MMPI monomer produced significant activity in temporally inhibiting SMC proliferation without any cellular damage. After coating with the PMMPI, adhesion and proliferation of SMCs were manifestly prevented even when a small amount of MMPI was released from the polymer. The MMPI-immobilized surface may thus be effective for inhibiting both adhesion and proliferation of SMCs, which is the first step toward in vivo experimentation. It is very much expected that coating stent struts with PMMPI containing an appropriate combination of impregnated drugs will provide a powerful tool for prevention of restenosis with little cytotoxicity.

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Section: Discussionsupporting

confidence: 65%

Development of a polymeric matrix metalloproteinase inhibitor as a bioactive stent coating material for prevention of restenosis

Nakayama

Masuda

2006

J Biomed Mater Res

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“…Second, the cover film was micropored using a KrF excimer laser apparatus (L4500, Hamamatsu Photonics, Shizuoka, Japan). [22][23][24][25] The pore diameter and the interpore distance were fixed at 100 and 250 mm, respectively. Finally, the luminal and outer surfaces of the microporous covered stents were coated with argatroban (500 mg/cm 2 ) and FK506 (140 mg/cm 2 ), respectively.…”

Section: Fabrication Of Self-expandable Drug-eluting Covered Stentsmentioning

confidence: 99%

Development of self‐expandable covered stents

et al. 2007

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We newly developed self-expandable covered stents by combining two of our original technologies. Of these, the first is the dip-coating covering method that was developed previously for balloon-expandable stents; the other is the newly developed self-expandable Nitinol stents, namely, Sendai stents. The three types of covered stents with the expansion diameter of 4.5, 5.0, or 6.0 mm thus obtained had a laser-processed microporous elastomeric cover film (pore diameter: 100 microm, interpore distance: 250 microm). Although the film was extremely thin (approximately 15 microm), the film could be expanded without causing any damage, the strut was completely embedded within the film, and the luminal surface of the film was smooth and flat. Mechanical properties such as ideal flexibility to follow the shapes of arteries were almost retained even after covering. As appropriate drugs, the blood-contacting inner and tissue-contacting outer surfaces of the film were differentially coated with argatroban for antithrombogenicity or FK506 for anti-inflammation, respectively. The preliminary in vivo study indicated that the covered stents mounted in the delivery catheter were navigated and placed to appropriate position in the arteries, and permissible neointimal thickening after 1-month implantation was observed similarly in noncovered stents.

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“…Unfortunately, the synthetic materials originally used for covering small-caliber stents (Table 1) display limited hemocompatibility, and their use has resulted in restenosis, thrombotic [8,9] and inflammatory events [10,11]. Table 1: Materials employed for the fabrication of covered coronary stents and clinical outcomes.…”

Section: Introductionmentioning

confidence: 99%

Layer-by-layer biofabrication of coronary covered stents with clickable elastin-like recombinamers

Fernández‐Colino

Wolf

Moreira

et al. 2019

European Polymer Journal

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Coronary artery disease is the leading cause of death around the world. Endovascular stenting is the preferred treatment option to restore blood flow in the coronary arteries due to the lower perioperative morbidity when compared with more invasive treatment options. However, stent failure is still a major clinical problem, and further technological solutions are required to improve the performance of current stents. Here, we developed coronary stents covered with elastin-like recombinamers (ELRs) by exploiting a layer-by-layer technique combined with catalyst free click-chemistry. The resulting ELR-covered stents were intact after an in vitro simulated implantation procedure by balloon dilatation, which evidence the elastic performance of the membrane. Additionally, the stents were mechanically stable under high flow conditions, which is in agreement with the covalent and stable nature of the click-chemistry crosslinking strategy exploited during the ELR-membrane manufacturing and the successful embedding of the stent. Minimal platelet adhesion was detected after blood exposure in a Chandler loop as shown by scanning electron microscopy. The seeding of human endothelial progenitor cells (EPCs) on the ELR-membranes resulted in a confluent endothelial layer. These results prove the potential of this strategy to develop an advanced generation of coronary stents, with a stable and bioactive elastin-like membrane to exclude the atherosclerotic plaque from the blood stream or to seal coronary perforations and aneurysms, while providing a non-thrombogenic luminal surface and favouring the endothelialization.

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Fabrication of micropored elastomeric film‐covered stents and acute‐phase performances

Cited by 26 publications

References 50 publications

Development of a polymeric matrix metalloproteinase inhibitor as a bioactive stent coating material for prevention of restenosis

Development of a polymeric matrix metalloproteinase inhibitor as a bioactive stent coating material for prevention of restenosis

Development of self‐expandable covered stents

Layer-by-layer biofabrication of coronary covered stents with clickable elastin-like recombinamers

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