Optimized Biomanufacturing for Treatment of Volumetric Muscle Loss Enables Physiomimetic Recovery.

IF 3.5 3区 医学 Q3 CELL & TISSUE ENGINEERING
Rachel K Bour, Gavin T Garner, Shayn M Peirce, George J Christ
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Abstract

Volumetric muscle loss (VML) injuries are defined by loss of sufficient skeletal muscle to produce persistent deficits in muscle form and function, with devastating lifelong consequences to both soldiers and civilians. There are currently no satisfactory treatments for VML injuries. The work described herein details the implementation of a fully enclosed bioreactor environment (FEBE) system that efficiently interfaces with our existing automated bioprinting and advanced biomanufacturing methods for cell deposition on sheet-based scaffolds for our previously described tissue-engineered muscle repair (TEMR) technology platform. Briefly, the TEMR technology consists of a porcine bladder acellular matrix seeded with skeletal muscle progenitor cells and preconditioned via 10% uniaxial cyclic stretch in a bioreactor. Overall, TEMR implantation in an established rat tibialis anterior (TA) VML injury model can result in 60 to ∼90% functional recovery. However, our original study documented >50% failure rate. That is, more than half of the implanted TEMR constructs produced no functional improvement beyond no treatment/repair. The high failure rate was attributed to the untoward mechanical disruption of TEMR during surgical implantation. In a follow-up study, adjustments were made to the geometry of both the VML injury and the TEMR construct, and the "nonresponder" group was reduced from over half the TEMR-treated animals to just 33%. Nonetheless, additional improvement is needed for clinical applicability. The main objectives of the current study were twofold: (1) explore the use of advanced biomanufacturing methods (i.e., FEBE bioreactor) to further improve TEMR reliability (i.e., increase functional response rate), (2) determine if previously established bioprinting methods, when coupled to the customized FEBE system would further improve the rate, magnitude or amplitude of functional outcomes following TEMR implantation in the same rat TA VML injury model. The current study demonstrates the unequivocal benefits of a customized bioreactor system that reduces manipulation of TEMR during cell seeding and maturation via bioprinting while simultaneously maximizing TEMR stability throughout the biofabrication process. This new biomanufacturing strategy not only accelerated the rate of functional recovery, but also eliminated all TEMR failures. In addition, implementation of bioprinting resulted in more physiomimetic skeletal muscle characteristics of repaired muscle tissue.

优化生物制造,治疗肌肉体积损失,实现仿生恢复。
体积性肌肉缺失(VML)损伤是指失去足够的骨骼肌,导致肌肉形态和功能出现持续性缺陷,给士兵和平民带来终生的毁灭性后果。目前还没有令人满意的治疗 VML 损伤的方法。本文所描述的工作详细介绍了全封闭生物反应器环境(FEBE)系统的实施情况,该系统可与我们现有的自动生物打印和先进生物制造方法有效衔接,用于将细胞沉积在片状支架上,用于我们之前描述的组织工程肌肉修复(TEMR)技术平台。简而言之,TEMR 技术包括在猪膀胱无细胞基质 (BAM) 中播种骨骼肌祖细胞,并在生物反应器中通过 10% 的单轴循环拉伸进行预处理。总体而言,在已建立的大鼠胫骨前肌(TA)VML 损伤模型中植入 TEMR 可使功能恢复 60% 至 90%。然而,我们最初的研究记录显示失败率大于 50%。也就是说,超过一半的植入 TEMR 构建物在没有治疗/修复的情况下功能没有改善。高失败率的原因是在手术植入过程中,TEMR受到了意外的机械破坏。在后续研究中,对 VML 损伤和 TEMR 构造的几何形状进行了调整,"无反应 "组从一半以上接受过 TEMR 治疗的动物减少到仅 33%。尽管如此,临床应用仍需进一步改进。当前研究的主要目标有两个:(1)探索使用先进的生物制造方法(即 FEBE 生物反应器)来进一步提高 TEMR 的可靠性(即提高功能反应率),(2)确定以前建立的生物打印方法与定制的 FEBE 系统结合后是否能进一步提高在同一大鼠 TA VML 损伤模型中植入 TEMR 后的功能结果的速率、幅度或振幅。目前的研究证明了定制生物反应器系统的明显优势,该系统通过生物打印减少了细胞播种和成熟过程中对 TEMR 的操作,同时在整个生物制造过程中最大限度地提高了 TEMR 的稳定性。这种新的生物制造策略不仅加快了功能恢复的速度,而且消除了所有 TEMR 故障。此外,生物打印技术的实施还使修复后的肌肉组织具有更多仿生骨骼肌特征。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Tissue Engineering Part A
Tissue Engineering Part A Chemical Engineering-Bioengineering
CiteScore
9.20
自引率
2.40%
发文量
163
审稿时长
3 months
期刊介绍: Tissue Engineering is the preeminent, biomedical journal advancing the field with cutting-edge research and applications that repair or regenerate portions or whole tissues. This multidisciplinary journal brings together the principles of engineering and life sciences in the creation of artificial tissues and regenerative medicine. Tissue Engineering is divided into three parts, providing a central forum for groundbreaking scientific research and developments of clinical applications from leading experts in the field that will enable the functional replacement of tissues.
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