Repair of tendons in the hand

The physiologic processes by which tendons of the hand heal after injury differ from one part of the hand to another. Although definitive operation immediately after injury is advisable in many cases to avoid infection, factors other than infection may be more important and dictate delay.While early exercise to mobilize the tendon soon after repair would seem logical, actually the process of healing is such that during the third week the tendon is spontaneously freed from adherence to surrounding tissue. Motion earlier than that causes irritation at the point of suture of the two ends of the tendon and increases scar. After completion of the healing process, motion serves to increase the strength of the new tendon fibrils.     

GFP chimeric models exhibited a biphasic pattern of mesenchymal cell invasion in tendon healing

The healing of an injured musculoskeletal system requires an influx of mesenchymal cells that can differentiate into osteoblasts, fibroblasts, chondroblasts, and skeletal myoblasts. However, whether these mesenchymal cells arise from the circulation (bone marrow) or the injured tissues themselves has been controversial. To reveal the spatiotemporal characteristics of the reparative mesenchymal cells, we investigated the healing process after patellar tendon injury using two types of green fluorescent protein (GFP) chimeric rats; one expressing GFP in the circulating cells, and the other expressing it in the patellar tendon. We analyzed the behavior of GFP-positive cells after experimental tendon injury in both chimeric rats to clarify the origin of reparative cells. At 24 h after the injury, the wound contained circulation-derived cells but not tendon-derived cells. Tendon-derived cells first appeared in the wounded area at 3 days after the injury, and had significantly increased in number with time and had maintained a high level of proliferative activity until 7 days after the injury, whereas the circulation-derived cells had decreased in number and had been replaced by the tendon-derived cells. These findings suggest that circulation-derived and tendon-derived cells contribute to the healing of tendons in different periods as part of a biphasic process.     

Platelet-rich plasma enhances the initial mobilization of circulation-derived cells for tendon healing

Circulation-derived cells play a crucial role in the healing processes of tissue. In early phases of tendon healing processes, circulation-derived cells temporarily exist in the wounded area to initiate the healing process and decrease in number with time. We assumed that a delay of time-dependent decrease in circulation-derived cells could improve the healing of tendons. In this study, we injected platelet-rich plasma (PRP) containing various kinds of growth factors into the wounded area of the patellar tendon, and compared the effects on activation of circulation-derived cells and enhancement of tendon healing with a control group (no PRP injection). To follow the circulation-derived cells, we used a green fluorescent protein (GFP) chimeric rat expressing GFP in the circulating cells and bone marrow cells. In the PRP group, the numbers of GFP-positive cells and heat-shock protein (HSP47; collagen-specific molecular chaperone)-positive cells were significantly higher than in the control group at 3 and 7 days after injury. At the same time, the immunoreactivity for types I and III collagen was higher in the PRP group than in the control group at early phase of tendon healing. These findings suggest that locally injected PRP is useful as an activator of circulation-derived cells for enhancement of the initial tendon healing process.     

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。     

Absence of estrogen receptor beta leads to abnormal adipogenesis during early tendon healing by an up‐regulation of PPARγ signalling

Achilles tendon injury is one of the challenges of sports medicine, the aetiology of which remains unknown. For a long time, estrogen receptor β (ERβ) has been known as a regulating factor of the metabolism in many connective tissues, such as bone, muscle and cartilage, but little is known about its role in tendon. Recent studies have implicated ERβ as involved in the process of tendon healing. Tendon‐derived stem cells (TDSCs) are getting more and more attention in tendon physiological and pathological process. In this study, we investigated how ERβ played a role in Achilles tendon healing. Achilles tendon injury model was established to analyse how ERβ affected on healing process in vivo. Cell proliferation assay, Western blots, qRT‐PCR and immunocytochemistry were performed to investigate the effect of ERβ on TDSCs. Here, we showed that ERβ deletion in mice resulted in inferior gross appearance, histological scores and, most importantly, increased accumulation of adipocytes during the early tendon healing which involved activation of peroxisome proliferator‐activated receptor γ (PPARγ) signalling. Furthermore, in vitro results of ours confirmed that the abnormity might be the result of abnormal TDSC adipogenic differentiation which could be partially reversed by the treatment of ERβ agonist LY3201. These data revealed a role of ERβ in Achilles tendon healing for the first time, thereby providing a new target for clinical treatment of Achilles tendon injury.     

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。     

Inflammation and tendon healing

Tendons are extracellular matrix rich structures allowing the transmission of forces generated by skeletal muscles to bones in order to produce movements. Some intrinsic characteristics of tendons, namely hypovascularity and hypocellularity, may explain their slow rate of healing. A growing body of evidence suggests that the inflammatory process, essential for pathogen clearance and injury scavenging, may play opposite functions in tendon healing. For instance, inflammation can lead to degradation of intact collagen and to viable cell death, thereby increasing the functional deficit and recovery period. Paradoxically, many cellular and subcellular events occurring during the inflammatory response lead to the release of a plethora of growth factors that trigger the healing phase. Prostaglandins are implicated in the inflammatory process and may also contribute to the primary steps of tendon healing. Prolonged administration of non steroidal anti-inflammatory drugs (NSAIDs) is a common practice following musculoskeletal injuries. However, there is no clear consensus on the effect of NSAIDs on tendon healing. This review presents a contemporary vision of the inflammatory process following tendon injury and examines the roles of the constitutive and inducible COX-derived prostaglandins. The effect of COX inhibitors will be addressed and special attention will be taken to describe COX-independent effects of these pharmacological inhibitors. Together, this review is an attempt to guide readers toward a more conscientious use of NSAIDs following tendon injuries.     

Exosomes from tendon stem cells promote injury tendon healing through balancing synthesis and degradation of the tendon extracellular matrix

Tendon injuries are common musculoskeletal system disorders in clinical, but the regeneration ability of tendon is limited. Tendon stem cells (TSCs) have shown promising effect on tissue engineering and been used for the treatment of tendon injury. Exosomes that serve as genetic information carriers have been implicated in many diseases and physiological processes, but effect of exosomes from TSCs on tendon injury repair is unclear. The aim of this study is to make clear that the effect of exosomes from TSCs on tendon injury healing. Exosomes were harvested from conditioned culture media of TSCs by a sequential centrifugation process. Rat Achilles tendon tendinopathy model was established by collagenase‐I injection. This was followed by intra‐Achilles‐tendon injection with TSCs or exosomes. Tendon healing and matrix degradation were evaluated by histology analysis and biomechanical test at the post‐injury 5 weeks. In vitro, TSCs treated with interleukin 1 beta were added by conditioned medium including exosomes or not, or by exosomes or not. Tendon matrix related markers and tenogenesis related markers were measured by immunostaining and western blot. We found that TSCs injection and exosomes injection significantly decreased matrix metalloproteinases (MMP)‐3 expression, increased expression of tissue inhibitor of metalloproteinase‐3 (TIMP‐3) and Col‐1a1, and increased biomechanical properties of the ultimate stress and maximum loading. In vitro, conditioned medium with exosomes and exosomes also significantly decreased MMP‐3, and increased expression of tenomodulin, Col‐1a1 and TIMP‐3. Exosomes from TSCs could be an ideal therapeutic strategy in tendon injury healing for its balancing tendon extracellular matrix and promoting the tenogenesis of TSCs.     

Aspirin inhibits adipogenesis of tendon stem cells and lipids accumulation in rat injury tendon through regulating PTEN/PI3K/AKT signalling

Tendon injury repairs are big challenges in sports medicine, and fatty infiltration after tendon injury is very common and hampers tendon injury healing process. Tendon stem cells (TSCs), as precursors of tendon cells, have shown promising effect on injury tendon repair for their tenogenesis and tendon extracellular matrix formation. Adipocytes and lipids accumulation is a landmark event in pathological process of tendon injury, and this may induce tendon rupture in clinical practice. Based on this, it is important to inhibit TSCs adipogenesis and lipids infiltration to restore structure and function of injury tendon. Aspirin, as the representative of non‐steroidal anti‐inflammatory drugs (NSAIDs), has been widely used in tendon injury for its anti‐inflammatory and analgesic actions, but effect of aspirin on TSCs adipogenesis and fatty infiltration is still unclear. Under adipogenesis conditions, TSCs were treated with concentration gradient of aspirin. Oil red O staining was performed to observe changes of lipids accumulation. Next, we used RNA sequencing to compare profile changes of gene expression between induction group and aspirin‐treated group. Then, we verified the effect of filtrated signalling on TSCs adipogenesis. At last, we established rat tendon injury model and compared changes of biomechanical properties after aspirin treatment. The results showed that aspirin decreased lipids accumulation in injury tendon and inhibited TSCs adipogenesis. RNA sequencing filtrated PTEN/PI3K/AKT signalling as our target. After adding the signalling activators of VO‐Ohpic and IGF‐1, inhibited adipogenesis of TSCs was reversed. Still, aspirin promoted maximum loading, ultimate stress and breaking elongation of injury tendon. In conclusion, by down‐regulating PTEN/PI3K/AKT signalling, aspirin inhibited adipogenesis of TSCs and fatty infiltration in injury tendon, promoted biomechanical properties and decreased rupture risk of injury tendon. All these provided new therapeutic potential and medicine evidence of aspirin in treating tendon injury and tendinopathy.     

Single dose of inducible nitric oxide synthase inhibitor induces prolonged inflammatory cell accumulation and fibrosis around injured tendon and synovium

The aim of the current study was to investigate the effect of inhibition of nitric oxide (NO) production after injury on inflammatory cell accumulation and fibrosis around digital flexor tendon and synovium. A standard crush injury was applied to the flexor tendons of the middle digit of the hindpaw and the overlying muscle and synovium of female Wistar rats. Thirty animals received an intraperitoneal injection of either isotonic saline or N(G)-nitro-l-arginine methyl ester (L-NAME; 5 mg/kg) immediately following the crush injury, and five animals were then sacrificed at various intervals and the paws processed for histology. Another group of five animals was sacrificed after 3 days for nitrite determinations. The results showed that nitrite production and hence NO synthase activity is doubled at the acute phase of tendon wound healing, and we can prevent this by administering a single dose of L-NAME immediately after injury. The incidence and severity of fibrocellular adhesions between tendon and synovium was much more marked in animals treated with L-NAME. Treatment with L-NAME elicited a chronic inflammatory response characterised by a persistent and extraordinarily severe accumulation of large numbers of inflammatory cells in the subcutaneous tissues, in muscle and in tendon. These findings indicate that in the case of injured tendon and synovium, NO could act to protect the healing tissue from an uncontrolled inflammatory response.     

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。     

Neutralisation of TGF beta or binding of VLA-4 to fibronectin prevents rat tendon adhesion following transection

Following tendon injury, severe loss of function often occurs either as a result of obliteration of the synovial canal with fibrous scar tissue or from rupture of the repaired tendon. The role of cell engineering in tendon repair is to promote strong and rapid healing of tendon whilst at the same time facilitating rapid reconstitution of the synovial canal. Modification of the immediate inflammatory response around healing tendon has been found to be of value. Experimentally this has been achieved by neutralisation of transforming growth factor-beta over the first 3 days following injury, or by blockade of inflammatory cell binding to the CS-1 locus on fibronectin with an anti-VLA-4 antibody, or with the synthetic VLA-4 inhibitor, CS-1 peptide, in a rat model of tendon transection. It is concluded from this pilot study that the treatments described hold promise in improving outcomes of the common clinical problem of tendon injury in man.     

Biomechanics of tendon injury and repair

Many clinical and experimental studies have investigated how tendons repair in response to an injury. This body of work has led to a greater understanding of tendon healing mechanisms and subsequently to an improvement in their treatment. In this review paper, characterization of normal and healing tendons is first covered. In addition, the debate between intrinsic and extrinsic healing is examined, and the cellular and extracellular matrix response following a tendon injury is detailed. Next, clinical and experimental injury and repair methods utilizing animal models are discussed. Animal models have been utilized to study the effect of various activity levels, motions, injury methods, and injury locations on tendon injury and repair. Finally, current and future treatment modalities for improving tendon healing, such as tissue engineering, cell therapy, and gene therapy, are reviewed.     

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。     

Expression of nitric oxide synthase and transforming growth factor-beta in crush-injured tendon and synovium

This study examined the expression of inducible nitric oxide synthase (iNOS) and transforming growth factor-beta (TGF-beta) in macrophage infiltrates within crush-injured digital flexor tendon and synovium of control rats and rats treated with N(G)-nitro-1-arginine methyl ester (L-NAME) (5 mg/kg). Release of TGF-beta from organ cultures of tendon, muscle, and synovium, and the effects of L-NAME treatment (in vitro and in vivo), on adhesion of peritoneal macrophages to epitenon monolayers were also investigated. The results showed that during normal tendon healing the levels of TGF-beta are high at first and gradually decrease after 3 weeks of injury to slightly above control uninjured levels. However, when L-NAME was administered at the time of injury, the macrophage infiltrates were expressing high levels of TGF-beta even at 5 weeks after the injury, with no evidence of reduction. In the standard injury, iNOS activity was greatest at the acute phase of the inflammatory response and then gradually returned to normal. Treatment with L-NAME, however, resulted in inhibition of iNOS activity at 3 days and a reduction in the activity at the later time points examined after injury. We also found greatly increased levels of adhesion of peritoneal macrophages from L-NAME-treated rats to epitenon monolayers in vitro, which reflect a chronic imbalance in expression of TGF-beta, which is overexpressed, and nitric oxide, which is underexpressed. The results of the current study show that formation of nitric oxide is an important event in the course of tendon healing since its inhibition results in chronic inflammation and fibrosis due to an imbalance in TGF-beta expression in vivo.     

Systemic EP4 Inhibition Increases Adhesion Formation in a Murine Model of Flexor Tendon Repair

Flexor tendon injuries are a common clinical problem, and repairs are frequently complicated by post-operative adhesions forming between the tendon and surrounding soft tissue. Prostaglandin E2 and the EP4 receptor have been implicated in this process following tendon injury; thus, we hypothesized that inhibiting EP4 after tendon injury would attenuate adhesion formation. A model of flexor tendon laceration and repair was utilized in C57BL/6J female mice to evaluate the effects of EP4 inhibition on adhesion formation and matrix deposition during flexor tendon repair. Systemic EP4 antagonist or vehicle control was given by intraperitoneal injection during the late proliferative phase of healing, and outcomes were analyzed for range of motion, biomechanics, histology, and genetic changes. Repairs treated with an EP4 antagonist demonstrated significant decreases in range of motion with increased resistance to gliding within the first three weeks after injury, suggesting greater adhesion formation. Histologic analysis of the repair site revealed a more robust granulation zone in the EP4 antagonist treated repairs, with early polarization for type III collagen by picrosirius red staining, findings consistent with functional outcomes. RT-PCR analysis demonstrated accelerated peaks in F4/80 and type III collagen (Col3a1) expression in the antagonist group, along with decreases in type I collagen (Col1a1). Mmp9 expression was significantly increased after discontinuing the antagonist, consistent with its role in mediating adhesion formation. Mmp2, which contributes to repair site remodeling, increases steadily between 10 and 28 days post-repair in the EP4 antagonist group, consistent with the increased matrix and granulation zones requiring remodeling in these repairs. These findings suggest that systemic EP4 antagonism leads to increased adhesion formation and matrix deposition during flexor tendon healing. Counter to our hypothesis that EP4 antagonism would improve the healing phenotype, these results highlight the complex role of EP4 signaling during tendon repair.     

Mechanical property changes during neonatal development and healing using a multiple regression model

During neonatal development, tendons undergo a well orchestrated process whereby extensive structural and compositional changes occur in synchrony to produce a normal tissue. Conversely, during the repair response to injury, structural and compositional changes occur, but a mechanically inferior tendon is produced. As a result, developmental processes have been postulated as a potential paradigm for elucidation of mechanistic insight required to develop treatment modalities to improve adult tissue healing. The objective of this study was to compare and contrast normal development with injury during early and late developmental healing. Using backwards multiple linear regressions, quantitative and objective information was obtained into the structure-function relationships in tendon. Specifically, proteoglycans were shown to be significant predictors of modulus during early developmental healing but not during late developmental healing or normal development. Multiple independent parameters predicted percent relaxation during normal development, however, only biglycan and fibril diameter parameters predicted percent relaxation during early developmental healing. Lastly, multiple differential predictors were observed between early development and early developmental healing; however, no differential predictors were observed between late development and late developmental healing. This study presents a model through which objective analysis of how compositional and structural parameters that affect the development of mechanical parameters can be quantitatively measured. In addition, information from this study can be used to develop new treatment and therapies through which improved adult tendon healing can be obtained.     

The vasculature and its role in the damaged and healing tendon

Tendon pathology has many manifestations, from spontaneous rupture to chronic tendinitis or tendinosis; the etiology and pathology of each are very different, and poorly understood. Tendon is a comparatively poorly vascularised tissue that relies heavily upon synovial fluid diffusion to provide nutrition. During tendon injury, as with damage to any tissue, there is a requirement for cell infiltration from the blood system to provide the necessary reparative factors for tissue healing. We describe in this review the response of the vasculature to tendon damage in a number of forms, and how and when the revascularisation or neovascularisation process occurs. We also include a section on the revascularisation of tendon during its use as a tendon graft in both ligament reconstruction and tendon–tendon grafting.