Zheng Zefeng, Ran Jisheng, Chen Weishan, Hu Yejun, Zhu Ting, Chen Xiao, Yin Zi, Heng Boon Chin, Feng Gang, Le Huihui, Tang Chenqi, Huang Jiayun, Chen Yangwu, Zhou Yiting, Dominique Pioletti, Shen Weiliang, Ouyang Hong-Wei
Dr. Li Dak Sum & Yip Yio Chin Center for Stem Cell and Regenerative Medicine, Zhejiang University, Zhejiang 310000, China; Department of Orthopedic Surgery, 2nd Affiliated Hospital, School of Medicine, Zhejiang University, Zhejiang 310009, China; Department of Orthopedic Surgery, The Children's Hospital, School of Medicine, Zhejiang University, Zhejiang 310052, China.
Department of Orthopedic Surgery, 2nd Affiliated Hospital, School of Medicine, Zhejiang University, Zhejiang 310009, China; Department of Orthopedics Research Institute of Zhejiang University, Zhejiang, China.
Acta Biomater. 2017 Mar 15;51:317-329. doi: 10.1016/j.actbio.2017.01.041. Epub 2017 Jan 16.
Rotator cuff tear is one of the most common types of shoulder injuries, often resulting in pain and physical debilitation. Allogeneic tendon-derived decellularized matrices do not have appropriate pore size and porosity to facilitate cell infiltration, while commercially-available synthetic scaffolds are often inadequate at inducing tenogenic differentiation. The aim of this study is to develop an advanced 3D aligned collagen/silk scaffold (ACS) and investigate its efficacy in a rabbit massive rotator cuff tear model. ACS has similar 3D alignment of collagen fibers as natural tendon with superior mechanical characteristics. Based on ectopic transplantation studies, the optimal collagen concentration (10mg/ml), pore diameter (108.43±7.25μm) and porosity (97.94±0.08%) required for sustaining a stable macro-structure conducive for cellular infiltration was determined. Within in vitro culture, tendon stem/progenitor cells (TSPCs) displayed spindle-shaped morphology, and were well-aligned on ACS as early as 24h. TSPCs formed intercellular contacts and deposited extracellular matrix after 7days. With the in vivo rotator cuff repair model, the regenerative tendon of the ACS group displayed more conspicuous native microstructures with larger diameter collagen fibrils (48.72±3.75 vs. 44.26±5.03nm) that had better alignment and mechanical properties (139.85±49.36vs. 99.09±33.98N) at 12weeks post-implantation. In conclusion, these findings demonstrate the positive efficacy of the macroporous 3D aligned scaffold in facilitating rotator cuff tendon regeneration, and its practical applications for rotator cuff tendon tissue engineering.
Massive rotator cuff tear is one of the most common shoulder injuries, and poses a formidable clinical challenge to the orthopedic surgeon. Tissue engineering of tendon can potentially overcome the problem. However, more efficacious scaffolds with good biocompatibility, appropriate pore size, favorable inductivity and sufficient mechanical strength for repairing massive rotator cuff tendon injuries need to be developed. In this study, we developed a novel macroporous 3D aligned collagen/silk scaffold, and demonstrated that this novel scaffold enhanced the efficacy of rotator cuff tendon regeneration by inducing aligned supracellular structures similar to natural tendon, which in turn enhanced cellular infiltration and tenogenic differentiation of stem/progenitor cells from both the tendon itself and surrounding tissues. Hence, it can potentially be a clinically useful application for tendon tissue engineering.
肩袖撕裂是最常见的肩部损伤类型之一,常导致疼痛和身体功能障碍。异体肌腱来源的脱细胞基质没有合适的孔径和孔隙率来促进细胞浸润,而市售的合成支架在诱导肌腱分化方面往往不足。本研究的目的是开发一种先进的三维排列胶原/丝素支架(ACS),并在兔大型肩袖撕裂模型中研究其效果。ACS具有与天然肌腱相似的胶原纤维三维排列,且机械性能优越。基于异位移植研究,确定了维持有利于细胞浸润的稳定宏观结构所需的最佳胶原浓度(10mg/ml)、孔径(108.43±7.25μm)和孔隙率(97.94±0.08%)。在体外培养中,肌腱干/祖细胞(TSPCs)呈纺锤形形态,早在24小时就很好地排列在ACS上。7天后,TSPCs形成细胞间接触并沉积细胞外基质。在体内肩袖修复模型中,ACS组的再生肌腱在植入后12周显示出更明显的天然微观结构,胶原原纤维直径更大(48.72±3.75对44.26±5.03nm),排列更好,机械性能更强(139.85±49.36对99.09±33.98N)。总之,这些发现证明了大孔三维排列支架在促进肩袖肌腱再生方面的积极效果及其在肩袖肌腱组织工程中的实际应用。
大型肩袖撕裂是最常见的肩部损伤之一,给骨科医生带来了巨大的临床挑战。肌腱组织工程有可能克服这个问题。然而,需要开发出具有良好生物相容性、合适孔径、良好诱导性和足够机械强度以修复大型肩袖肌腱损伤的更有效的支架。在本研究中,我们开发了一种新型的大孔三维排列胶原/丝素支架,并证明这种新型支架通过诱导类似于天然肌腱的排列超细胞结构增强了肩袖肌腱再生的效果,这反过来又增强了来自肌腱本身和周围组织的干/祖细胞的细胞浸润和肌腱分化。因此,它有可能成为肌腱组织工程的一种临床有用应用。
