Delivery of N-Cadherin Targeting Peptides to Vascular Tissues by Surface-Modified Polyurethane Nanoparticles via a Drug-Coated Balloon.

IF 5.4 2区医学 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Biomaterials Science & Engineering Pub Date : 2025-01-14 DOI:10.1021/acsbiomaterials.4c02417

Chantal M Trepanier, Jonah Burke-Kleinman, Guangpei Hou, Jonathan Rubianto, Bradley H Strauss, Michelle P Bendeck, J Paul Santerre

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Abstract

Restenosis remains a long-standing limitation to effectively maintain functional blood flow after percutaneous transluminal angioplasty (PTA). While the use of drug-coated balloons (DCBs) containing antiproliferative drugs has improved patient outcomes, limited tissue transfer and poor therapeutic targeting capabilities contribute to off-target cytotoxicity, precluding adequate endothelial repair. In this work, a DCB system was designed and tested to achieve defined arterial delivery of an antirestenosis therapeutic candidate, cadherin-2 (N-cadherin) mimetic peptides (NCad), shown to selectively inhibit smooth muscle cell migration in vitro and limit intimal thickening in early animal PTA models. To enable successful tissue transfer in the current work, a nanoparticle excipient system previously demonstrated to be an effective carrier of NCad in vitro was integrated with customized DCB coating methodologies designed to prevent therapeutic loss during delivery. DCB design took into consideration four components: (1) the angioplasty balloon; (2) a poly(ethylene oxide) (PEO) monolayer acting as a hydrophilic spacer between the balloon surface and the nanoparticles to assist with improved nanoparticle release; (3) surface-modified degradable polar hydrophobic ionic polyurethane (D-PHI) nanoparticles loaded with NCad to facilitate the transport of the therapeutic peptide into vascular tissue; and (4) a PEO sacrificial coating applied over the nanoparticle excipient layer to prevent premature losses during transit to the artery. The nanoparticle-DCB platform successfully delivered NCad to rat carotid tissue, with superior efficacy and increased permeation within the vessel wall compared with soluble NCad infusion alone. Nanoscale technologies in conjunction with enhanced DCB design properties hold promise in advancing the localized delivery of preventive restenosis therapies in vascular disease.

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长期以来，经皮腔内血管成形术（PTA）后再狭窄一直是限制有效维持功能性血流的一个因素。虽然含有抗增生药物的药物涂层球囊（DCB）的使用改善了患者的预后，但有限的组织转移和较差的治疗靶向能力造成了脱靶细胞毒性，阻碍了充分的内皮修复。在这项工作中，设计并测试了一种 DCB 系统，以实现抗动脉狭窄候选疗法--Cadherin-2（N-cadherin）模拟肽（NCad）--的明确动脉输送，该疗法在体外选择性抑制平滑肌细胞迁移，并在早期动物 PTA 模型中限制内膜增厚。为了在目前的工作中实现成功的组织转移，以前在体外被证明是 NCad 有效载体的纳米颗粒赋形剂系统被整合到了定制的 DCB 涂层方法中，以防止输送过程中的治疗损失。DCB 的设计考虑到了四个部分：(1) 血管成形球囊；(2) 聚环氧乙烷（PEO）单层，作为球囊表面和纳米粒子之间的亲水隔层，帮助改善纳米粒子的释放；(3) 表面改性的可降解极性疏水性离子聚氨酯（D-PHI）纳米粒子装载有 NCad，以促进治疗肽向血管组织的运输；以及 (4) 在纳米粒子赋形剂层上涂覆一层 PEO 牺牲涂层，以防止在运输到动脉的过程中过早损失。纳米粒子-DCB平台成功地将NCad输送到了大鼠颈动脉组织，与单独输注可溶性NCad相比，疗效更佳，血管壁内的渗透率更高。纳米级技术与增强的 DCB 设计特性相结合，有望推进血管疾病预防性再狭窄疗法的局部输送。

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来源期刊

ACS Biomaterials Science & Engineering Materials Science-Biomaterials

CiteScore

10.30

自引率

3.40%

发文量

413

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