Thermoresponsive, redox-polymerized cellulosic hydrogels undergo in situ gelation and restore intervertebral disc biomechanics post discectomy.

IF 3.2 3区 医学 Q3 CELL & TISSUE ENGINEERING
D M Varma, H A Lin, R G Long, G T Gold, A C Hecht, J C Iatridis, S B Nicoll
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引用次数: 0

Abstract

Back and neck pain are commonly associated with intervertebral disc (IVD) degeneration. Structural augmentation of diseased nucleus pulposus (NP) tissue with biomaterials could restore degeneration-related IVD height loss and degraded biomechanical behaviors; however, effective NP replacement biomaterials are not commercially available. This study developed a novel, crosslinked, dual-polymer network (DPN) hydrogel comprised of methacrylated carboxymethylcellulose (CMC) and methylcellulose (MC), and used in vitro, in situ and in vivo testing to assess its efficacy as an injectable, in situ gelling, biocompatible material that matches native NP properties and restores IVD biomechanical behaviors. Thermogelling MC was required to enable consistent and timely gelation of CMC in situ within whole IVDs. The CMC-MC hydrogel was tuned to match compressive and swelling NP tissue properties. When injected into whole IVDs after discectomy injury, CMC-MC restored IVD height and compressive biomechanical behaviors, including range of motion and neutral zone stiffness, to intact levels. Subcutaneous implantation of the hydrogels in rats further demonstrated good biocompatibility of CMC-MC with a relatively thin fibrous capsule, similar to comparable biomaterials. In conclusion, CMC-MC is an injectable, tunable and biocompatible hydrogel with strong potential to be used as an NP replacement biomaterial since it can gel in situ, match NP properties, and restore IVD height and biomechanical function. Future investigations will evaluate herniation risk under severe loading conditions and assess long-term in vivo performance.

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热致伸缩、氧化还原聚合纤维素水凝胶可在原位凝胶化,恢复椎间盘切除术后的椎间盘生物力学。
背部和颈部疼痛通常与椎间盘(IVD)退化有关。用生物材料对病变的髓核组织进行结构性增强,可以恢复与退化相关的 IVD 高度损失和退化的生物力学行为;然而,有效的髓核替代生物材料还没有商业化的产品。本研究开发了一种由甲基丙烯酸化羧甲基纤维素(CMC)和甲基纤维素(MC)组成的新型交联双聚合物网络(DPN)水凝胶,并通过体外、原位和体内测试评估了其作为一种可注射、原位胶凝、生物相容性材料的功效,该材料可匹配原生 NP 特性并恢复 IVD 生物力学行为。需要热凝胶 MC 才能使 CMC 在整个 IVD 内持续、及时地原位凝胶化。对 CMC-MC 水凝胶进行了调整,使其与 NP 组织的压缩和膨胀特性相匹配。椎间盘切除术损伤后,将 CMC-MC 注入整个 IVD,可使 IVD 高度和压缩生物力学行为(包括活动范围和中性区硬度)恢复到完好水平。在大鼠皮下植入水凝胶进一步证明了 CMC-MC 具有良好的生物相容性,纤维囊相对较薄,与同类生物材料相似。总之,CMC-MC 是一种可注射、可调节、生物相容性好的水凝胶,具有作为 NP 替代生物材料的强大潜力,因为它能在原位凝胶,与 NP 特性相匹配,并能恢复 IVD 高度和生物力学功能。未来的研究将评估在严重加载条件下的疝风险,并评估长期的体内性能。
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
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.
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