Development of a 3D-printed bioabsorbable composite scaffold with mechanical properties suitable for treating large, load-bearingarticular cartilage defects.

IF 3.2 3区 医学 Q3 CELL & TISSUE ENGINEERING European cells & materials Pub Date : 2023-06-29 DOI:10.22203/eCM.v045a11
M Joyce, T Hodgkinson, M Lemoine, A González-Vázquez, D J Kelly, F J O'Brien
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Abstract

Extracellular matrix (ECM) biomaterials have shown promise for treating small artucular-joint defetcs. However, ECM-based biomaterials generally lack appropriate mechanical properties to support physiological loads and are prone to delamination in larger cartilage defects. To overcome these common mechanical limitations, a collagen hyaluronic-acid (CHyA) matrix, with proven regenerative potential, was reinforced with a bioabsorbable 3D-printed framework to support physiological loads. Polycaprolactone (PCL) was 3D-printed in two configurations, rectilinear and gyroid designs, that were extensively mechanically characterised. Both scaffold designs increased the compressive modulus of the CHyA matrices by three orders of magnitude, mimicking the physiological range (0.5-2.0 MPa) of healthy cartilage. The gyroid scaffold proved to be more flexible compared to the rectilinear scaffold, thus better contouring to the curvature of a femoral condyle. Additionally, PCL reinforcement of the CHyA matrix increased the tensile modulus and allowed for suture fixation of the scaffold to the subchondral bone, thus addressing the major challenge of biomaterial fixation to articular joint surfaces in shallow defects. In vitro evaluation confirmed successful infiltration of human mesenchymal stromal cells (MSCs) within the PCL-CHyA scaffolds, which resulted in increased production of sulphated glycosaminoglycans (sGAG/DNA; p = 0.0308) compared to non-reinforced CHyA matrices. Histological staining using alcian blue confirmed these results, while also indicating greater spatial distribution of sGAG throughout the PCL-CHyA scaffold. These findings have a great clinical importance as they provide evidence that reinforced PCL-CHyA scaffolds, with their increased chondroinductive potential and compatibility with joint fixation techniques, could be used to repair large-area chondral defects that currently lack effective treatment options.

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一种具有机械性能的3d打印生物可吸收复合支架的开发,适用于治疗大型负重关节软骨缺陷。
细胞外基质(ECM)生物材料已显示出治疗小关节缺陷的希望。然而,基于ecm的生物材料通常缺乏适当的力学性能来支持生理负荷,并且在较大的软骨缺损中容易分层。为了克服这些常见的机械限制,胶原质透明质酸(CHyA)基质被证明具有再生潜力,用生物可吸收的3d打印框架进行加固,以支持生理负荷。聚己内酯(PCL)以两种构型3d打印,直线和陀螺仪设计,广泛的机械特性。两种支架设计都将CHyA基质的压缩模量提高了三个数量级,模拟了健康软骨的生理范围(0.5-2.0 MPa)。与直线支架相比,旋转支架被证明更灵活,因此更好地勾勒出股骨髁的曲率。此外,CHyA基质的PCL增强增加了拉伸模量,并允许将支架缝合固定到软骨下骨,从而解决了浅层缺陷中关节表面生物材料固定的主要挑战。体外评估证实PCL-CHyA支架内成功浸润人间充质间质细胞(MSCs),导致硫酸糖胺聚糖(sGAG/DNA;p = 0.0308)。alcian blue的组织学染色证实了这些结果,同时也表明sGAG在PCL-CHyA支架中的空间分布更大。这些发现具有重要的临床意义,因为它们提供了证据,增强PCL-CHyA支架具有增强的软骨诱导潜能和与关节固定技术的相容性,可用于修复大面积软骨缺损,目前缺乏有效的治疗选择。
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来源期刊
European cells & materials
European cells & materials 生物-材料科学:生物材料
CiteScore
6.00
自引率
6.50%
发文量
55
审稿时长
1.5 months
期刊介绍: eCM provides an interdisciplinary forum for publication of preclinical research in the musculoskeletal field (Trauma, Maxillofacial (including dental), Spine and Orthopaedics). The clinical relevance of the work must be briefly mentioned within the abstract, and in more detail in the paper. Poor abstracts which do not concisely cover the paper contents will not be sent for review. Incremental steps in research will not be entertained by eCM journal.Cross-disciplinary papers that go across our scope areas are welcomed.
期刊最新文献
Notochordal cell-derived matrix inhibits MAPK signaling in the degenerative disc environment Relationship between microscale shear modulus, composition, and structure in porcine, canine, and human temporomandibular-joint cartilage: relevance to disease and degeneration Treatment of volumetric muscle loss in female rats with biomimetic sponges Creating tissue with intervertebral disc-like characteristics using gdf5 functionalized silk scaffolds and human mesenchymal stromal cells Development of a 3D-printed bioabsorbable composite scaffold with mechanical properties suitable for treating large, load-bearingarticular cartilage defects.
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