Department of Plastic and Reconstructive Surgery, Shanghai Key Laboratory of Tissue Engineering, Shanghai 9th People's Hospital, Shanghai Jiao Tong University School of Medicine, Shanghai, People's Republic of China.
National Tissue Engineering Center of China, Shanghai, People's Republic of China.
Stem Cells Transl Med. 2017 Mar;6(3):982-991. doi: 10.5966/sctm.2016-0118. Epub 2016 Nov 7.
In vitro three-dimensional (3D) cartilage regeneration is a promising strategy for repair of cartilage defects. However, inferior mechanical strength and tissue homogeneity greatly restricted its clinical translation. Simulation of mechanical stress through a bioreactor is an important approach for improving in vitro cartilage regeneration. The current study developed a hydrostatic pressure (HP) bioreactor based on a novel pressure-transmitting mode achieved by slight deformation of a flexible membrane in a completely sealed stainless steel device. The newly developed bioreactor efficiently avoided the potential risks of previously reported pressure-transmitting modes and simultaneously addressed a series of important issues, such as pressure scopes, culture chamber sizes, sealability, contamination control, and CO balance. The whole bioreactor system realized stable long-term (8 weeks) culture under high HP (5-10 MPa) without the problems of medium leakage and contamination. Furthermore, the results of in vitro 3D tissue culture based on a cartilage regeneration model revealed that HP provided by the newly developed bioreactor efficiently promoted in vitro 3D cartilage formation by improving its mechanical strength, thickness, and homogeneity. Detailed analysis in cell proliferation, cartilage matrix production, and cross-linking level of collagen macromolecules, as well as density and alignment of collagen fibers, further revealed the possible mechanisms that HP regulated in vitro cartilage regeneration. The current study provided a highly efficient and stable bioreactor system for improving in vitro 3D cartilage regeneration and thus will help to accelerate its clinical translation. Stem Cells Translational Medicine 2017;6:982-991.
体外三维(3D)软骨再生是修复软骨缺损的一种很有前途的策略。然而,较差的机械强度和组织均一性极大地限制了其临床转化。通过生物反应器模拟机械应力是改善体外软骨再生的重要方法。本研究开发了一种基于新颖压力传递模式的静水压力(HP)生物反应器,该模式通过在完全密封的不锈钢装置中的柔性膜的轻微变形来实现。新开发的生物反应器有效地避免了先前报道的压力传递模式的潜在风险,同时解决了一系列重要问题,如压力范围、培养室尺寸、密封性、污染控制和 CO 平衡。整个生物反应器系统在高 HP(5-10 MPa)下实现了稳定的长期(8 周)培养,没有介质泄漏和污染的问题。此外,基于软骨再生模型的体外 3D 组织培养结果表明,新开发的生物反应器提供的 HP 通过提高其机械强度、厚度和均一性,有效地促进了体外 3D 软骨形成。细胞增殖、软骨基质产生以及胶原大分子交联水平以及胶原纤维密度和取向的详细分析进一步揭示了 HP 调节体外软骨再生的可能机制。本研究提供了一种高效稳定的生物反应器系统,用于改善体外 3D 软骨再生,从而有助于加速其临床转化。干细胞转化医学 2017;6:982-991.
