屏障材料预防肌腱粘连的研究进展

肌腱与腱周组织粘连是肌腱损伤修复术后最主要的并发症,使用屏障材料预防肌腱粘连是一种最直接有效的方法。传统使用的不可吸收材料常常会导致严重免疫反应或阻隔肌腱营养而导致肌腱愈合不良,且常需二次手术取出,已基本淘汰。可吸收膜和水凝胶等具有良好通透性及组织相容性的可吸收大分子材料是目前研究的重点。使用自体或异体组织材料重建腱鞘也可预防肌腱粘连,但自体组织重建腱鞘损伤较大且手术复杂,异体组织常常受到安全性、伦理学等诸多限制,而组织工程化腱鞘可能是未来预防肌腱粘连的一个重要研究方向。     

屏障材料预防肌腱粘连的研究进展

肌腱与腱周组织粘连是肌腱损伤修复术后最主要的并发症,使用屏障材料预防肌腱粘连是一种最直接有效的方法。传统使用的不可吸收材料常常会导致严重免疫反应或阻隔肌腱营养而导致肌腱愈合不良,且常需二次手术取出,已基本淘汰。可吸收膜和水凝胶等具有良好通透性及组织相容性的可吸收大分子材料是目前研究的重点。使用自体或异体组织材料重建腱鞘也可预防肌腱粘连,但自体组织重建腱鞘损伤较大且手术复杂,异体组织常常受到安全性、伦理学等诸多限制,而组织工程化腱鞘可能是未来预防肌腱粘连的一个重要研究方向。     

肌腱再生相关转录因子研究进展

肌腱作为骨骼和肌肉的连接往往容易受到损伤,目前对肌腱基本生物学有限的了解妨碍了肌腱修复技术的发展。最近,一系列肌腱生长相关因子被发现,其中Scleraxis(Scx)和Mohawk(Mkx)已被确定为肌腱生长和分化中的关键转录因子,Sox9和EGR1/2也被报道参与肌腱的生长。然而,目前研究尚未明确这些转录因子的生物学功能及其分子机制。本文就上述转录因子的分布与功能,及转录因子相关分子进行综述,为肌腱的修复提供生物学基础并探讨肌腱损伤治疗的未来发展方向。     

前臂屈指肌腱修复术后功能恢复的影响因素分析

目的：探讨影响前臂屈指肌腱修复术后功能恢复效果的因素,以利于制定合理的手术及康复方案。方法：对2011年1月～2012年10月解放军第401医院手外科收治的58例（其中男性41例,女性17例,年龄13．62岁,平均33．8岁）屈指肌腱在前臂损伤患者的伤因及手术方式进行回顾、分析总结并进行随访,分析其受伤严重程度、手术方式、术后功能锻炼情况。结果：术后随访54例,失访4例,随访时间为术后3-6个月。根据中华医学会手外科学会手功能评定试用标准评定54例前臂屈指肌腱损伤修复术后的患手的恢复情况,其中优31例,良16例,中5例,差2例。指浅、深屈肌腱同时损伤较单纯指浅屈肌腱损伤修复术后粘连发生率较高,手功能的优良率较低（P〈0．05）,合理应用防粘连技术和术后进行系统功能锻炼的患者术后手功能的优良率分别较未合理应用防粘连技术和术后未进行系统功能锻炼的患者显著升高（P〈0．05）。结论：手术切口是否合理的延长,术中操作是否重视无创操作,是否合理的应用防粘连技术以及缺乏系统的功能锻炼以及肌腱断端吻合质量是影响前臂屈指肌腱修复术后功能恢复的重要因素。     

前臂屈指肌腱修复术后功能恢复的影响因素分析

目的:探讨影响前臂屈指肌腱修复术后功能恢复效果的因素,以利于制定合理的手术及康复方案。方法:对2011年1月~2012年10月解放军第401医院手外科收治的58例(其中男性41例,女性17例,年龄13-62岁,平均33.8岁)屈指肌腱在前臂损伤患者的伤因及手术方式进行回顾、分析总结并进行随访,分析其受伤严重程度、手术方式、术后功能锻炼情况。结果:术后随访54例,失访4例,随访时间为术后3~6个月。根据中华医学会手外科学会手功能评定试用标准评定54例前臂屈指肌腱损伤修复术后的患手的恢复情况,其中优31例,良16例,中5例,差2例。指浅、深屈肌腱同时损伤较单纯指浅屈肌腱损伤修复术后粘连发生率较高,手功能的优良率较低(P0.05),合理应用防粘连技术和术后进行系统功能锻炼的患者术后手功能的优良率分别较未合理应用防粘连技术和术后未进行系统功能锻炼的患者显著升高(P0.05)。结论:手术切口是否合理的延长,术中操作是否重视无创操作,是否合理的应用防粘连技术以及缺乏系统的功能锻炼以及肌腱断端吻合质量是影响前臂屈指肌腱修复术后功能恢复的重要因素。     

肌腱组织工程的研究进展

肌腱组织工程的发展为肌腱损伤的修复提供了新的希望.本文综合国内外最新文献,就肌腱组织工程的种子细胞、应用生物材料及转基因技术应用研究等方面的进展进行了综述.     

脂肪干细胞促进肌腱损伤修复研究进展

脂肪干细胞（adipose-derived stem cells, ADSCs）具有来源广泛、易于获取、体外扩增、免疫原性低等许多优于其他组织来源间充质干细胞（mesenchymal stem cells, MSCs）的特点,越来越多的研究开始关注如何将其应用于组织损伤的治疗与修复。就近几年来国内外ADSCs的发现与分离、向肌腱谱系分化能力以及在肌腱损伤修复方面的应用进行了综述,分析了ADSCs应用于肌腱损伤修复时的优势和面临的问题,并对未来的研究方向进行了展望。     

肌腱组织工程研究进展

随着人口的年龄和预期寿命的增加,尤其是在年轻的人群中,肌腱损伤将变得更加普遍。传统的肌腱修复方法有许多不足之处,其功能重建不能令人满意。组织工程是一个发展的领域,组织工程肌腱体外的构建和体内的应用技术逐渐成熟,为临床上治疗肌腱缺损提供了一种不需要自体肌腱移植而且更加有前景的途径。在肌腱组织工程的研究中所面临的挑战和未来的发展方向为:种子细胞,新型支架材料和力学刺激。近年来肌腱干细胞的发现为种子细胞的选择提供了新思路,力学刺激对组织工程肌腱的影响也逐渐成为热点。本文就组织工程肌腱研究中种子细胞、支架材料和力学刺激的进展做一综述,并对未来的发展进行展望。     

防止肌腱粘连及促进其愈合的研究进展

随着对肌腱愈合研究的不断深入和发展,预防肌腱粘连以及促进其愈合的方法越来越多。通过改进缝合方法、修复腱鞘或采用替代品、置入药物或药物薄膜及早期康复等治疗来有效预防肌腱粘连;通过重建腱鞘、药物、生长因子、基因干预等促进肌腱愈合。本文就近年来防止肌腱粘连及促进其愈合方面的研究予以综述。     

肌腱组织工程支架与种子细胞研究进展

目的:综述肌腱组织工程支架材料、细胞来源、制备技术及体外构建的研究进展.方法:查阅近期肌腱组织工程研究的相关文献,对组织工程肌腱支架的材料来源、制备技术,复合细胞种类,体外构建力学刺激等进行分析、归纳.结果:肌腱组织工程支架材料有天然材料、人工合成材料及复合材料等;制备技术包括静电纺丝和编织法等;其中支架材料的表面修饰是组织工程化肌腱构建的重要环节.与肌腱材料进行复合的种子细胞有肌腱细胞、骨髓间充质干细胞及成纤维细胞等.结论:复合材料是近年肌腱组织工程支架材料研究的重点,静电纺丝技术是一种具有潜力的支架制备技术,支架材料的表面修饰可促进细胞在支架上的黏附及肌腱的形成,种子细胞的研究仍是肌腱组织工程发展的瓶颈,周期性张力的存在为组织工程化肌腱的形成创造了条件.     

Regeneration of rabbit calcaneal tendon

Summary The regenerated tissue which fills the gap between the stumps of sectioned and unsutured rabbit calcaneal tendon was studied by immuno-fluorescence, light and electron microscopy from 2 days to 30 weeks after surgery. In the early stages, the newly formed tissue consisted of few connective tissue cells of variable shape dispersed in an abundant intercellular matrix. At 7 days after tenotomy most of the cells were spindle shaped and arranged along the major tendon axis. They showed a well developed rough endoplasmic reticulum, a prominent Golgi complex and bundles of thin and thick filaments. Moreover, they appeared intensely stained when treated with anti-actin and anti-myosin sera. The bulk of the intercellular matrix consisted of bundles of collagen fibers, mostly arranged parallel to the cells.In the subsequent stages the regenerating tissue became more compact, acquiring the morphological characteristics of tendon tissue. At 30 weeks after tenotomy, however, it did not show yet the typical texture of the normal adult tendon. The tenocytes were more numerous and less uniformly distributed, and contained a greater amount of ergastoplasm and contractile proteins. The collagen fibers were similar in size to those of the neonatal normal tendon and the elastic fibers appeared often immature.These findings suggest that, at least on the experimental conditions under which this study was performed, the regenerated tendon does not acquire the typical morphology of the normal adult tendon, possibly owing to the reduced mechanical stress acting on it.     

Mechanotransduction of stem cells for tendon repair

Tendon is a mechanosensitive tissue that transmits force from muscle to bone. Physiological loading contributes to maintaining the homeostasis and adaptation of tendon, but aberrant loading may lead to injury or failed repair. It is shown that stem cells respond to mechanical loading and play an essential role in both acute and chronic injuries, as well as in tendon repair. In the process of mechanotransduction, mechanical loading is detected by mechanosensors that regulate cell differentiation and proliferation via several signaling pathways. In order to better understand the stem-cell response to mechanical stimulation and the potential mechanism of the tendon repair process, in this review, we summarize the source and role of endogenous and exogenous stem cells active in tendon repair, describe the mechanical response of stem cells, and finally, highlight the mechanotransduction process and underlying signaling pathways.     

Mechanical response of individual collagen fibrils in loaded tendon as measured by atomic force microscopy

A precise analysis of the mechanical response of collagen fibrils in tendon tissue is critical to understanding the ultrastructural mechanisms that underlie collagen fibril interactions (load transfer), and ultimately tendon structure–function. This study reports a novel experimental approach combining macroscopic mechanical loading of tendon with a morphometric ultrascale assessment of longitudinal and cross-sectional collagen fibril deformations. An atomic force microscope was used to characterize diameters and periodic banding (D-period) of individual type-I collagen fibrils within murine Achilles tendons that were loaded to 0%, 5%, or 10% macroscopic nominal strain, respectively. D-period banding of the collagen fibrils increased with increasing tendon strain (2.1% increase at 10% applied tendon strain, p < 0.05), while fibril diameter decreased (8% reduction, p < 0.05). No statistically significant differences between 0% and 5% applied strain were observed, indicating that the onset of fibril (D-period) straining lagged macroscopically applied tendon strains by at least 5%. This confirms previous reports of delayed onset of collagen fibril stretching and the role of collagen fibril kinematics in supporting physiological tendon loads. Fibril strains within the tissue were relatively tightly distributed in unloaded and highly strained tendons, but were more broadly distributed at 5% applied strain, indicating progressive recruitment of collagen fibrils. Using these techniques we also confirmed that collagen fibrils thin appreciably at higher levels of macroscopic tendon strain. Finally, in contrast to prevalent tendon structure–function concepts data revealed that loading of the collagen network is fairly homogenous, with no apparent predisposition for loading of collagen fibrils according to their diameter.     

In situ fibril stretch and sliding is location-dependent in mouse supraspinatus tendons

Tendons are able to transmit high loads efficiently due to their finely optimized hierarchical collagen structure. Two mechanisms by which tendons respond to load are collagen fibril sliding and deformation (stretch). Although many studies have demonstrated that regional variations in tendon structure, composition, and organization contribute to the full tendon׳s mechanical response, the location-dependent response to loading at the fibril level has not been investigated. In addition, the instantaneous response of fibrils to loading, which is clinically relevant for repetitive stretch or fatigue injuries, has also not been studied. Therefore, the purpose of this study was to quantify the instantaneous response of collagen fibrils throughout a mechanical loading protocol, both in the insertion site and in the midsubstance of the mouse supraspinatus tendon. Utilizing a novel atomic force microscopy-based imaging technique, tendons at various strain levels were directly visualized and analyzed for changes in fibril d-period with increasing tendon strain. At the insertion site, d-period significantly increased from 0% to 1% tendon strain, increased again from 3% to 5% strain, and decreased after 5% strain. At the midsubstance, d-period increased from 0% to 1% strain and then decreased after 7% strain. In addition, fibril d-period heterogeneity (fibril sliding) was present, primarily at 3% strain with a large majority occurring in the tendon midsubstance. This study builds upon previous work by adding information on the instantaneous and regional-dependent fibrillar response to mechanical loading and presents data proposing that collagen fibril sliding and stretch are directly related to tissue organization and function.     

Stem cell therapies in tendon-bone healing

Tendon-bone insertion injuries such as rotator cuff and anterior cruciate ligament injuries are currently highly common and severe. The key method of treating this kind of injury is the reconstruction operation. The success of this reconstructive process depends on the ability of the graft to incorporate into the bone. Recently, there has been substantial discussion about how to enhance the integration of tendon and bone through biological methods. Stem cells like bone marrow mesenchymal stem cells (MSCs), tendon stem/progenitor cells, synovium-derived MSCs, adipose-derived stem cells, or periosteum-derived periosteal stem cells can self-regenerate and potentially differentiate into different cell types, which have been widely used in tissue repair and regeneration. Thus, we concentrate in this review on the current circumstances of tendon-bone healing using stem cell therapy.     

Perivascular cells of the supraspinatus tendon express both tendon- and stem cell-related markers

Tendons and ligaments are often affected by mechanical injuries or chronic impairment but other than muscle or bone they possess a low healing capacity. So far, little is known about regeneration of tendons and the role of tendon precursor cells in that process. We hypothesize that perivascular cells of tendon capillaries are progenitors for functional tendon cells and are characterized by expression of marker genes and proteins typical for mesenchymal stem cells and functional tendon cells. Immunohistochemical characterization of biopsies derived from intact human supraspinatus tendons was performed. From these biopsies perivascular cells were isolated, cultured, and characterized using RT-PCR and Western blotting. We have shown for the first time that perivascular cells within tendon tissue express both tendon- and stem/precursor cell-like characteristics. These findings were confirmed by results from in vitro studies focusing on cultured perivascular cells isolated from human supraspinatus tendon biopsies. The results suggest that the perivascular niche may be considered a source for tendon precursor cells. This study provides further information about the molecular nature and localization of tendon precursor cells, which is the basis for developing novel strategies towards tendon healing and facilitated regeneration. H. Tempfer and A. Wagner have contributed equally to this paper.