MULTILAYER VASCULAR GRAFTS BASED ON COLLAGEN-MIMETIC HYDROGELS

基于仿胶原水凝胶的多层血管移植物

• 批准号: 8302864
• 负责人: Elizabeth Marie Cosgriff-Hernandez
• 金额: $ 31.6万
• 依托单位: TEXAS ENGINEERING EXPERIMENT STATION
• 依托单位国家: 美国
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-04-01 至 2016-01-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8302864
• 关键词: Address; Adhesions; Adult; Affect; Affinity; American; Animals; Arteries; Autologous; Behavior; Binding; Biopolymers; Blood Vessels; Caliber; Cardiovascular Diseases; Cardiovascular system; Carotid Arteries; Cell Adhesion; Cell Communication; Cell Proliferation; Cells; Characteristics; Clinical; Collagen; Collagen Type IV; Coronary Arteriosclerosis; Coronary artery; Coupled; Development; Devices; Drug Formulations; Endothelial Cells; Environment; Enzymes; Ethylene Glycols; Experimental Designs; Failure; Family; Family suidae; Gel; Goals; Hybrids; Hydrogels; Hyperplasia; Individual; Integrin Binding; Integrins; Mechanics; Mediating; Modeling; Nature; Outcome; Parents; Peripheral arterial disease; Phenotype; Platelet aggregation; Polymer Chemistry; Polyurethanes; Process; Property; Proteins; Resistance; Risk; Role; Signal Transduction; Site; Smooth Muscle Myocytes; Stem cells; Sterilization; Structure; Surgical sutures; Thrombosis; United States; Vascular Graft; Work; base; biomaterial compatibility; cell behavior; cell growth; cell type; clinically relevant; cytokine; density; design; ethylene glycol; implantation; improved; in vivo; migration; mimetics; mortality; novel; pre-clinical; pressure; repaired; response; scaffold; success; tool

DESCRIPTION (provided by applicant): A major roadblock in the development of off-the-shelf, small-caliber vascular grafts is achieving rapid endothelialization of the scaffold while minimizin the risk of thrombosis, intimal hyperplasia, and mechanical failure. Given that platelet aggregation and smooth muscle cell proliferation may be mediated by controlling endothelial cell (EC) growth and phenotype, the development of materials that direct appropriate EC behavior would have a significant impact on small vessel repair and replacement. However, matrix properties which promote graft endothelialization may not be consistent with those appropriate to sustain the loads associated with adult vasculature. To address this limitation, we propose to fabricate multilayered hydrogel-electrospun mesh scaffolds in which a hydrogel layer provides a local environment inductive of rapid endothelialization and an electrospun mesh sleeve provides bulk strength, compliance matching, and suture retention. Thus, each component can be individually tuned to achieve improved outcomes without detriment to other design goals. We propose to circumvent the limitations associated with native biopolymer gels by generating novel bioactive hydrogels using the collagen-mimetic protein Scl2.28 (Scl2). Scl2 is a recently discovered protein which has the triple helical structure characteristic of native collagen but lacks collagen's array of cell adhesion, cytokine binding, and enzyme-cleavage sites. For the present work, we have introduced ¿1¿1 and ¿2¿1 adhesion sites into the "parent" Scl2 to provide a mechanism for EC interactions while maintaining the low platelet aggregation associated with Scl2. Scl2-based hydrogel formulations that induce desired cell behaviors will be utilized in the fabrication of the multilayer vascular graft reinforced with non-degradable electrospun mesh "sleeves" designed to have mechanical properties similar to native coronary arteries. Aim 1. Identify PEGDA-Scl2 compositions that promote rapid endothelialization of the vascular graft (adhesion, migration, quiescent phenotype) while maintaining the non-thrombogenic nature of Scl2 proteins. Aim 2. Fabricate a multilayer vascular graft with clinically-relevant mechanical properties (burst pressure, suture retention strength, compliance) by reinforcing hydrogels with electrospun polyurethane sleeves. Aim 3. Assess biocompatibility and biostability of each component of the composite graft. Aim 4. Evaluate multilayer grafts in vivo after implantation as carotid grafts in a Yucatan miniature pig model. At the end of the 5 year period, we will have evaluated these new conduits in preclinical animal studies and demonstrated their potential utility as off-the-shelf, small-caliber vascular grafts. From a fundamental perspective, this family of hybrid materials will provide the tools to elucidate endothelialization processes critical to the clinical success of numerous cardiovascular devices. Furthermore, the control over both bioactivity and modulus afforded by PEGDA-Scl2 gels, combined with the ability to target a range of different cell types by incorporating different integrin binding motifs into Scl2, will form a powerful platform in the creation of new bioactive materials for a wide range of biomedical applications. PUBLIC HEALTH RELEVANCE: Cardiovascular diseases, including coronary artery disease and peripheral arterial disease, affect approximately 1 in 3 Americans and remain the leading cause of mortality in the United States. Bioactive vascular grafts have the potential to replace damaged arteries without the complications associated with autologous or current synthetic grafts. At the end of the 5 year period, we will have evaluated bioactive, multilayer grafts in preclinical animal studies and demonstrated the potential utility of this novel design as an off-the-shelf, small-caliber vascular graft. From a fundamental perspective, the development of the proposed family of hybrid materials will provide the tools to elucidate endothelialization processes critical to the clinical success of numerous cardiovascular devices.

描述（由申请人提供）：开发现成的小口径血管移植物的主要障碍是实现支架的快速内皮化，同时将血栓形成、内膜增生和机械故障的风险降至最低。考虑到血小板聚集和平滑肌细胞增殖可能是通过控制内皮细胞（EC）的生长和表型来介导的，因此，指导内皮细胞适当行为的材料的开发将对小血管修复和置换产生重大影响。然而，促进移植物内皮化的基质特性可能与适合维持与成人血管相关的负荷的基质特性不一致。为了解决这一限制，我们建议制造多层水凝胶-电纺丝网支架，其中水凝胶层提供快速内皮化的局部环境，电纺丝网套管提供体积强度，顺应性匹配和缝合保留。因此，每个组件都可以单独调优，以在不损害其他设计目标的情况下实现改进的结果。我们建议通过使用拟胶原蛋白Scl2.28 （Scl2）生成新型生物活性水凝胶来规避与天然生物聚合物凝胶相关的局限性。Scl2是一种新发现的蛋白，具有天然胶原的三螺旋结构特征，但缺乏胶原的一系列细胞粘附、细胞因子结合和酶裂解位点。在目前的工作中，我们将¿1¿1和¿2¿1粘附位点引入到“亲本”Scl2中，以提供EC相互作用的机制，同时维持与Scl2相关的低血小板聚集。诱导所需细胞行为的基于scl2的水凝胶配方将用于制造多层血管移植物，这些血管移植物由不可降解的静电纺网“袖子”增强，其机械性能与天然冠状动脉相似。目的1。鉴定PEGDA-Scl2成分，促进血管移植物的快速内皮化（粘附、迁移、静态表型），同时保持Scl2蛋白的非血栓性。目标2。通过静电纺聚氨酯套管加强水凝胶，制作具有临床相关机械性能（破裂压力、缝线保持强度、顺应性）的多层血管移植物。目标3。评估复合移植物各组分的生物相容性和生物稳定性。目标4。在尤卡坦微型猪模型中评估植入后作为颈动脉移植物的多层活体移植物。在5年期间结束时，我们将在临床前动物研究中评估这些新的导管，并证明它们作为现成的小口径血管移植物的潜在用途。从一个基本的角度来看，这种混合材料家族将提供工具来阐明内皮化过程对许多心血管装置的临床成功至关重要。此外，PEGDA-Scl2凝胶对生物活性和模量的控制，以及通过将不同的整合素结合基序结合到Scl2中来靶向一系列不同细胞类型的能力，将形成一个强大的平台，为广泛的生物医学应用创造新的生物活性材料。