Engineered Decellularized Tendon Matrix Putty Preserves Native Tendon Bioactivity to Promote Cell Proliferation and Enthesis Repair

IF 3.1 3区 生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Anna-Laura Nelson, Kelsey M. O’Hara, Philip C. Nolte, N. Fukase, Yoichi Murata, Anna-Katharina Nolte, Johnny Huard, David L. Bernholt, Peter J. Millett, C. Bahney
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Abstract

Rotator cuff tears are a common soft tissue injury that can significantly decrease function of the shoulder and cause severe pain. Despite progress in surgical technique, rotator cuff repairs (RCRs) do not always heal efficiently. Many failures occur at the bone-tendon interface as a result of poor healing capacity of the tendon and failure to regenerate the native histological anatomy of the enthesis. While allografts are commercially available, clinical use is limited as they do not stimulate tissue regeneration and are associated with a structural failure of up to 40% in re-tear cases. Novel tissue engineering strategies are being developed with promise, but most involve addition of cells and/or growth factors which extends the timeline for clinical translation. Thus, there exists a significant unmet clinical need for easily translatable surgical augmentation approaches that can improve healing in RCR. Here we describe the development of a decellularized tendon matrix (DTM) putty that preserves native tendon bioactivity using a novel processing technique. In vitro, DTM promoted proliferation of tenocytes and adipose-derived stem cells with an increase in expression-specific transcription factors seen during enthesis development, Scleraxis and Sox9. When placed in a rabbit model of a chronic rotator cuff tear, DTM improved histological tissue repair by promoting calcification at the bone-tendon interface more similar to the normal fibrocartilaginous enthesis. Taken together, these data indicate that the engineered DTM putty retains a pro-regenerative bioactivity that presents a promising translational strategy for improving healing at the enthesis.
工程化脱细胞肌腱基质腻子可保留原生肌腱的生物活性,促进细胞增殖和实体修复
肩袖撕裂是一种常见的软组织损伤,可明显降低肩部功能并导致剧烈疼痛。尽管手术技术不断进步,但肩袖修复术(RCR)并非总能有效愈合。由于肌腱的愈合能力差以及无法再生出原生的组织解剖结构,许多修复失败都发生在骨与肌腱的交界处。虽然市场上有同种异体移植物,但由于其不能刺激组织再生,而且在再次撕裂的病例中,高达 40% 的结构性失败与同种异体移植物有关,因此临床应用受到限制。目前正在开发的新型组织工程策略前景广阔,但大多涉及细胞和/或生长因子的添加,从而延长了临床转化的时间。因此,对于能改善 RCR 愈合的、易于转化的手术增量方法,还存在着大量未得到满足的临床需求。在此,我们介绍了一种脱细胞肌腱基质(DTM)腻子的开发情况,这种腻子采用新颖的加工技术保留了原生肌腱的生物活性。在体外,DTM 促进了腱细胞和脂肪来源干细胞的增殖,并增加了在内膜发育过程中出现的特异性转录因子 Scleraxis 和 Sox9 的表达。当把 DTM 放入慢性肩袖撕裂的兔子模型中时,DTM 通过促进骨-肌腱界面的钙化,改善了组织修复,使其更接近正常的纤维软骨内膜。总之,这些数据表明,工程 DTM 粘合剂具有促进再生的生物活性,是一种很有前景的改善关节内愈合的转化策略。
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来源期刊
CiteScore
7.50
自引率
3.00%
发文量
97
审稿时长
4-8 weeks
期刊介绍: Journal of Tissue Engineering and Regenerative Medicine publishes rapidly and rigorously peer-reviewed research papers, reviews, clinical case reports, perspectives, and short communications on topics relevant to the development of therapeutic approaches which combine stem or progenitor cells, biomaterials and scaffolds, growth factors and other bioactive agents, and their respective constructs. All papers should deal with research that has a direct or potential impact on the development of novel clinical approaches for the regeneration or repair of tissues and organs. The journal is multidisciplinary, covering the combination of the principles of life sciences and engineering in efforts to advance medicine and clinical strategies. The journal focuses on the use of cells, materials, and biochemical/mechanical factors in the development of biological functional substitutes that restore, maintain, or improve tissue or organ function. The journal publishes research on any tissue or organ and covers all key aspects of the field, including the development of new biomaterials and processing of scaffolds; the use of different types of cells (mainly stem and progenitor cells) and their culture in specific bioreactors; studies in relevant animal models; and clinical trials in human patients performed under strict regulatory and ethical frameworks. Manuscripts describing the use of advanced methods for the characterization of engineered tissues are also of special interest to the journal readership.
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