ELECTROSPINNING ARTIFICIAL LIGAMENTS AND TENDONS FOR POTENTIAL PROSTHESES

用于潜在假肢的静电纺人工韧带和肌腱

• 批准号: 8129730
• 负责人: Javier Macossay-Torres
• 金额: $ 13.8万
• 依托单位: UNIVERSITY OF TEXAS RIO GRANDE VALLEY
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-09-01 至 2013-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8129730
• 关键词: Adverse effects; Allografting; American; Anterior Cruciate Ligament; Area; Articular ligaments; Autologous Transplantation; Award; Biocompatible; Biocompatible Materials; Biological; Carbon; Carbon Nanotubes; Carbon nanoparticle; Cells; Chemical Structure; Chemicals; Chemistry; Collaborations; Collagen; Continuing Education; Data; Development; Devices; Differential Scanning Calorimetry; Dimensions; Disease; Educational Activities; Educational process of instructing; Educational workshop; Electron Microscopy; Ensure; FDA approved; Fiber; Fibroblasts; Film; Funding; Funding Mechanisms; Growth; Healed; Health; Injury; International; Investigation; Joint Capsule; Journals; Knee; Laboratories; Learning; Letters; Ligaments; Manufactured basketball; Manufactured football; Mechanics; Mentors; Mentorship; Microscopic; Morbidity - disease rate; Natural regeneration; Patients; Peer Review; Phase; Polymers; Polyurethanes; Procedures; Process; Property; Prosthesis; Prosthesis Design; Public Health; Publications; Publishing; Reconstructive Surgical Procedures; Recording of previous events; Recovery; Research; Research Activity; Risk; Rupture; Scanning Electron Microscopy; Science; Secure; Series; Site; Skiing; Soccer; Societies; Solutions; Solvents; Spectroscopy, Fourier Transform Infrared; Spectrum Analysis; Sports; Structure; Surgical sutures; Techniques; Technology; Tendon Injuries; Tendon structure; Tensile Strength; Testing; Texas; Time; Tissue Engineering; Tissues; Transmission Electron Microscopy; Universities; Vascularization; Virginia; Work; anterior cruciate ligament reconstruction; anterior cruciate ligament rupture; base; biomaterial compatibility; cell growth; design; direct application; experience; healing; human tissue; improved; innovation; interest; kinematics; ligament injury; meetings; nanofiber; nanoparticle; professor; response; soft tissue; text searching; tissue regeneration; tissue support frame; voltage

DESCRIPTION (provided by applicant): Over 800,000 injuries to ligaments, tendons and the joint capsule occur every year in the U.S.A. While suturing is an alternative to treat ligaments' and tendons' injuries, it is not always successful because of the natural tissues' limited vascularization. As an option to this problem, grafts and prostheses are used to reconstruct these tissues. The Anterior Cruciate Ligament (ACL), an intra-articular ligament that contributes to the kinematics and stability of the knee, is commonly torn or ruptured in athletes and people practicing demanding activities. The approaches to ACL reconstruction include the use of autografts, allografts and prostheses, but these choices present shortcomings. In spite of these drawbacks, U.S. doctors performed an estimated 200,000 reconstructive surgeries in 2006. To overcome current limitations on treating ligament and tendon injuries like a torn ACL, the long term research objective of this proposal is to develop artificial ligaments and tendons that will mimic the properties of these human tissues. Since the mechanical properties of the materials selected to perform this project contrast significantly with those of the materials used in currently available prostheses, we expect to develop artificial ligaments and tendons with enhanced properties and closer resemblance to natural tissues. To achieve the long term research objective, three specific aims are proposed: 1) selection of polymers and investigation of the effect that secondary structures have on the properties of electrospun polymer nanofibers (EPN), 2) incorporation of carbon nanoparticles to the EPN to enhance their mechanical properties and 3) cell seeding to assess biological compatibility. These studies will investigate the electrospinning conditions of biocompatible polyurethanes to obtain micro- and nanofibers, which will be assembled into specific secondary structures to resemble ligaments and tendons. These assemblies will be extensively characterized, allowing us to design the targeted applications. Furthermore, carbon nanotubes and carbon nanofibers will be incorporated into the EPN to enhance the mechanical properties of the assemblies formed. Finally, studies on fibroblasts seeding and proliferation on the assemblies will examine the biological compatibility and potential for using the proposed structures as artificial ligaments and tendons. This project will investigate the hypothesis that certain synthetic polymers can be electrospun into micro- and nanofibers and assembled into specific secondary structures, which will possess mechanical properties similar to natural ligaments and tendons. Furthermore, we hypothesize that the mechanical properties of these secondary structures will be enhanced by incorporation of carbon nanoparticles. This project is innovative because it combines the use of certain polyurethanes (not explored for the proposed applications) through electrospinning to design prostheses. In addition to the unique combination of materials and technique proposed, the prosthetic ligaments and tendons targeted are potentially superior to the materials currently in use. PUBLIC HEALTH RELEVANCE: More than 800,000 injuries to ligaments, tendons and the joint capsule occur every year in the U.S.A., and many of these injuries require reconstructive surgery. The objective of this project is to develop artificial ligaments and tendons for potential prostheses, which could impact the public health.

描述(申请人提供)：美国每年发生超过80万例韧带、肌腱和关节囊损伤。虽然缝合是治疗韧带和肌腱损伤的一种替代方法，但由于天然组织的有限血运，缝合并不总是成功的。作为解决这一问题的一种选择，移植物和假体被用于重建这些组织。前十字韧带(前十字韧带)是一种关节内韧带，有助于膝关节的运动学和稳定性，在运动员和练习高强度运动的人中经常发生撕裂或断裂。重建前交叉韧带的方法包括自体移植物、同种异体移植物和假体，但这些方法都存在缺陷。尽管有这些缺点，美国医生在2006年估计进行了20万例重建手术。为了克服目前在治疗韧带和肌腱损伤(如前交叉韧带撕裂)方面的局限性，这项提议的长期研究目标是开发模仿这些人体组织特性的人工韧带和肌腱。由于该项目所用材料的力学性能与现有假体材料的力学性能有显著差异，我们希望开发出性能更好、更接近自然组织的人工韧带和肌腱。为了实现长期的研究目标，提出了三个具体的目标：1)聚合物的选择和研究二级结构对电纺聚合物纳米纤维(EPN)性能的影响；2)在EPN中掺入纳米碳以提高其力学性能；3)细胞接种以评估生物相容性。这些研究将探索生物相容聚氨酯的静电纺丝条件，以获得微米和纳米纤维，这些纤维将组装成特定的二级结构，类似于韧带和肌腱。这些程序集将被广泛描述，使我们能够设计目标应用程序。此外，碳纳米管和碳纳米纤维将被加入到EPN中，以提高形成的组件的机械性能。最后，对成纤维细胞在组件上的种植和增殖的研究将检验所提出的结构作为人工韧带和肌腱的生物相容性和潜力。该项目将研究某些合成聚合物可以电纺成微米和纳米纤维并组装成特定的二级结构的假设，这些二级结构将具有类似于天然韧带和肌腱的机械性能。此外，我们假设这些二级结构的机械性能将通过掺入碳纳米颗粒来增强。这个项目是创新的，因为它结合了某些聚氨酯的使用(未被探索用于拟议的应用)，通过静电纺丝来设计假体。除了所提出的材料和技术的独特组合外，所针对的人工韧带和肌腱潜在地优于目前使用的材料。 与公共卫生相关：美国每年发生超过80万例韧带、肌腱和关节囊损伤，其中许多需要进行重建手术。该项目的目标是为可能影响公众健康的潜在假体开发人工韧带和肌腱。

项目成果

A simple approach for synthesis, characterization and bioactivity of bovine bones to fabricate the polyurethane nanofiber containing hydroxyapatite nanoparticles.

牛骨的合成、表征和生物活性的简单方法，用于制造含有羟基磷灰石纳米粒子的聚氨酯纳米纤维。

• DOI: 10.3144/expresspolymlett.2012.5
• 发表时间: 2012
• 期刊: EXPRESS polymer letters
• 影响因子: 3.3
• 作者: Sheikh,FA;Kanjwal,MA;Macossay,J;Barakat,NAM;Kim,HY
• 通讯作者: Kim,HY

Fabrication of Mineralized Collagen from Bovine Waste Materials by Hydrothermal Method as Promised Biomaterials.

通过水热法从牛废料中制造矿化胶原蛋白作为有希望的生物材料。

• DOI: 10.1166/jbt.2011.1017
• 发表时间: 2011
• 期刊: Journal of biomaterials and tissue engineering
• 影响因子: 0.1
• 作者: Sheikh,FaheemA;Kanjwal,MuzafarA;Macossay,Javier;Muhammad,MuneebA;Cantu,Travis;Barakat,NasserAM;Kim,HakYong
• 通讯作者: Kim,HakYong

EELS Analysis of Nylon 6 Nanofibers Reinforced with Nitroxide-Functionalized Graphene Oxide.

• DOI: 10.1016/j.carbon.2013.12.087
• 发表时间: 2014
• 期刊: CARBON
• 影响因子: 10.9
• 作者: Leyva-Porras, Cesar;Ornelas-Gutierrez, C.;Miki-Yoshida, M.;Avila-Vega, Yazmin I.;Macossay, Javier;Bonilla-Cruz, Jose
• 通讯作者: Bonilla-Cruz, Jose

Fabrication of Poly(vinylidene fluoride) (PVDF) Nanofibers Containing Nickel Nanoparticles as Future Energy Server Materials.

• DOI: 10.1166/sam.2011.1148
• 发表时间: 2011-04
• 期刊: Science of advanced materials
• 影响因子: 0.9
• 作者: Sheikh FA;Cantu T;Macossay J;Kim H
• 通讯作者: Kim H

Biodegradable electrospun nanofibers coated with platelet-rich plasma for cell adhesion and proliferation.

• DOI: 10.1016/j.msec.2014.03.065
• 发表时间: 2014-07-01
• 期刊: MATERIALS SCIENCE & ENGINEERING C-MATERIALS FOR BIOLOGICAL APPLICATIONS
• 影响因子: 7.9
• 作者: Diaz-Gomez, Luis;Alvarez-Lorenzo, Carmen;Concheiro, Angel;Silva, Maite;Dominguez, Fernando;Sheikh, Faheem A.;Cantu, Travis;Desai, Raj;Garcia, Vanessa L.;Macossay, Javier
• 通讯作者: Macossay, Javier