富血小板血浆诱导骨髓间充质干细胞结合化学萃取去细胞神经修复坐骨神经缺损

背景：周围神经损伤早期许旺细胞尚未大量分裂增殖,此时由于解剖连续性的中断,通过轴浆逆向运输提供的营养因子骤减,缺乏神经营养因子支持的神经元有可能死亡,从而使周围神经不能再生或再生乏力。 目的：观察植入经富血小板血浆诱导的骨髓间充质干细胞结合去细胞神经修复坐骨神经缺损的效果。 方法：取新西兰大耳白兔制备坐骨神经缺损模型,随机抽签法分成4组：去细胞神经组,移植同种异体去细胞神经;骨髓间充质干细胞组,移植同种异体骨髓间充质干细胞结合化学萃取的同种异体去细胞神经：经诱导骨髓间充质干细胞组,移植经富血小板血浆诱导的同种异体骨髓间充质干细胞结合化学萃取的同种异体去细胞神经;自体神经组,移植自体神经。术后进行形态学观察与靶肌肉肌湿质量恢复率、运动神经传导速度、轴突直径和髓鞘厚度的检测。 结果与结论：经富血小板血浆诱导的骨髓间充质干细胞结合化学萃取的去细胞神经移植修复神经的靶肌肉肌湿质量恢复率、运动神经传导速度、轴突直径和髓鞘厚度及形态学观察明显优于移植单纯化学萃取的去细胞神经与骨髓间充质干细胞结合化学萃取的去细胞神经的效果,而与移植自体神经修复结果相似。说明经诱导后的骨髓间充质干细胞在体内具有许旺细胞的部分功能,可作为组织工程化外周神经的种子细胞,用于周围神经缺损的修复。     

无细胞神经支架复合骨髓间充质干细胞构建组织工程人工神经修复坐骨神经缺损*☆

背景：作者已经成功制备了无细胞神经移植物,并且复合骨髓间充质干细胞构建组织工程人工神经桥接大鼠坐骨神经缺损。 目的：无细胞神经移植物复合骨髓间充质干细胞构建组织工程人工神经修复大鼠坐骨神经缺损后运动功能的恢复。 方法：成年雄性SD大鼠构建大鼠坐骨神经15 mm缺损模型,分别应用组织工程人工神经、组织工程神经支架或自行神经桥接坐骨神经缺损。桥接后20周再生神经电生理学测定,手术侧胫骨前肌湿质量、腓肠肌组织学及透视电镜分析。 结果与结论：桥接20周后,组织工程人工神经与自体神经移植组胫骨前肌湿质量比较,差异无显著性意义(P > 0.05),神经干传导速度为(30.56±2.15)m/s。结果提示,无细胞神经移植物复合骨髓间充质干细胞构建的组织工程人工神经桥接大鼠坐骨神经缺损后,可以促进再生神经运动功能的恢复。     

HRP逆行示踪评价复合骨髓间充质干细胞的无细胞神经移植物

背景：作者前期将无细胞神经移植物与骨髓间充质干细胞复合培养,成功构建了组织工程人工神经。 目的：应用辣根过氧化物酶(HRP)神经逆行示踪技术对无细胞神经移植物复合骨髓间充质干细胞构建的神经移植复合体桥接大鼠坐骨神经缺损后运动神经元的保护作用进行评价。 方法：成年清洁级健康雄性SD大鼠,随机分成3组：①实验组：采用复合骨髓间充质干细胞的无细胞神经移植物桥接大鼠坐骨神经缺损。②空白对照组：采用无细胞神经移植物桥接大鼠坐骨神经缺损。③自体神经对照组：采用自体神经移植桥接大鼠坐骨神经缺损。术后12周应用辣根过氧化物酶神经逆行示踪技术对脊髓前角运动神经元的再生进行评价。 结果与结论：术后12周脊髓前角运动神经元再生评价结果显示：实验组优于无细胞神经移植物组,而与自体神经移植物组相比差异无显著性意义。证实无细胞神经移植物复合骨髓间充质干细胞构建组织工程人工神经修复大鼠坐骨神经缺损,对大鼠脊髓运动神经元具有保护作用,可能达到与自体神经移植相似的效果。 关键词：无细胞神经移植物;骨髓间充质干细胞;辣根过氧化物酶;神经移植;大鼠     

无细胞神经移植物复合骨髓间充质干细胞修复大鼠坐骨神经缺损

背景：作者前期试验已成功制备了天然可生物降解的无细胞神经移植物并证明其可促进周围神经再生。 目的：无细胞神经移植物复合骨髓间充质干细胞构建组织工程人工神经并观察其修复大鼠坐骨神经缺损促进运动功能恢复的效果。 设计、时间及地点：随机对照动物实验，于2008-06/2009-02在辽宁医学院附属第一医院医学组织工程实验室完成。 材料：180~200 g成年健康雄性Wistar大鼠，用于制备无细胞神经移植物，100~120 g成年健康雄性Wistar大鼠，用于制备骨髓间充质干细胞，将骨髓间充质干细胞植入并与无细胞神经支架联合培养构建组织工程人工神经。 方法：180~200 g成年健康雄性SD大鼠60只构建坐骨神经15 mm缺损模型，随机分成3组，每组20只。①实验组采用组织工程人工神经桥接大鼠坐骨神经缺损。②空白对照组采用组织工程神经支架桥接大鼠坐骨神经缺损。③自体神经对照组采用自体神经移植桥接大鼠坐骨神经缺损。 主要观察指标：术后12周通过大体观察、电生理检测、组织学和小腿三头肌湿质量等方法分析评价运动功能恢复情况。 结果：①术后12周，实验组大鼠手术侧足趾可以分开，并且可以支撑着地；实验组大鼠再生神经传导速度与自体神经对照组相比，差异无显著性意义。②术后12周，实验组组织化学染色可见腓肠肌内有呈AchE阳性的运动终板整齐地排列于腓肠肌的中上部形成终板带，经结合镀银染色后可见再生的神经束及发出的分支与运动终板相连。③实验组与自体神经对照组胫骨前肌湿质量比差异无显著性意义。 结论：无细胞神经移植物复合骨髓间充质干细胞桥接大鼠坐骨神经缺损具有促进其运动功能恢复的作用。     

同种异体神经复合体修复兔周围神经缺损

背景：应用种植许旺细胞的去细胞同种异体神经复合体修复周围神经缺损,探索其对神经再生及功能恢复有更好的促进作用,并且免疫原性非常小。 目的：用种植胎兔许旺细胞的去细胞同种异体神经复合体修复兔缺损的坐骨神经,观察移植神经周围免疫细胞的变化及功能恢复。 　 方法：48只新西兰白兔随机分成实验组和对照组。两组动物均切除一段坐骨神经,造成2.0 cm长的缺损,实验组用种植胎兔许旺细胞的同种异体神经复合体修复坐骨神经;对照组仅用去细胞同种异体神经修复。移植后1,4,8周光镜观察移植段坐骨神经周围肌肉组织中免疫细胞的浸润情况,计数每个高倍视野免疫细胞的数量。移植后4,8,16周大体观察兔的足部溃疡形成及愈合情况,大体观察神经愈合情况;肌电图检查桥接段坐骨神经的传导速度。 结果与结论：手术区局部均未出现明显的排斥反应,实验组足部溃疡愈合情况优于对照组。移植后1周移植段坐骨神经周围肌肉组织中有大量淋巴细胞及巨噬细胞浸润,实验组明显多于对照组(P < 0.05);移植后4周,浸润的免疫细胞两组均较1周后明显减少,实验组减少更明显。移植后8周,浸润的免疫细胞更加减少,但两组间比较差异无显著性意义(P > 0.05)。移植后4周时,两组均未见明显的神经传导,8,16周神经传导速度实验组均优于对照组(P < 0.05)。提示,种植许旺细胞的去细胞同种异体神经复合体免疫原性非常小,对神经再生及功能恢复有更好的促进作用。     

无细胞神经移植物复合骨髓间充质干细胞构建组织工程人工神经修复坐骨神经缺损

背景：作者前期已经成功将无细胞神经移植物复合骨髓间充质干细胞构建组织工程人工神经,并证明可以促进周围神经再生。 目的：构建组织工程人工神经,观察和验证桥接大鼠坐骨神经缺损后的神经功能恢复情况。 方法：成年雄性SD大鼠60只构建大鼠坐骨神经15 mm缺损模型。随机分成3组,每组20只。桥接大鼠坐骨神经缺损,实验组采用组织工程人工神经,空白对照组采用无细胞组织工程神经支架,自体神经对照组采用自体神经移植。桥接后12周通过大体观察、胫骨前肌湿质量、组织学等方法分析坐骨神经组织学及功能恢复情况。 结果与结论：桥接术后12周：实验组大鼠肢体可以支撑着地,钳夹大鼠手术侧足底皮肤出现逃避反射,足底皮肤s-100蛋白染色呈阳性反应。实验组与自体神经移植组胫骨前肌湿质量比差异无显著性意义(P > 0.05)。实验组辣根过氧化物酶逆行示踪实验显示脊髓、后根神经节均可见数量不等的辣根过氧化物酶标记阳性细胞。实验组移植物与自体神经移植组有髓神经纤维数、髓鞘厚度、神经组织面积比较差异无显著性意义。实验结果验证了无细胞神经移植物复合骨髓间充质干细胞构建组织工程人工神经修复大鼠坐骨神经缺损,可以促进神经组织学的修复重建和功能的恢复。     

化学去细胞同种异体神经移植修复大鼠骶1神经缺损★

背景：自体神经移植是修复周围神经损伤中最常用的方法。 目的：探讨化学去细胞神经修复大鼠骶1神经缺损的效果，以期寻找修复周围神经缺损较为理想的方法和材料。 方法：取SD大鼠骶1神经，采用化学去细胞法处理大鼠骶1神经的免疫原性成分，使其成为去细胞神经。将Wistar大鼠右侧骶1神经制成1 cm缺损模型，用SD大鼠去细胞同种异体神经移植修复大鼠骶1神经的缺损。 结果与结论：与术前相比，术后8周逼尿肌漏尿点降低，膀胱最大容积和膀胱顺应性升高(P < 0.05)。神经纤维细丝蛋白染色结果显示，右侧经同种异体神经移植修复的神经吻合口断端被染成绿色，神经纤维排列整齐分布均一，再生神经轴突长入远端神经。左侧正常神经形态均一，神经纤维排列整齐分布均一未见轴突长入远端神经。结果表明，化学去细胞同种异体神经的抗原性明显降低，可修复高等哺乳类动物的周围神经损伤。     

骨骼肌卫星细胞异体移植对周围神经缺损后再生的影响

背景：有研究表明肌卫星细胞不仅在体外具有较强的增殖能力及适应能力,而且在异体内免疫原性低,免疫排斥反应低,移植后存活时间长。因此设想肌卫星细胞异体移植在促进缺损神经再生等方面可能具有良好的研究和应用前景。 目的：探讨骨骼肌卫星细胞移植对周围神经缺损后再生修复的影响。 方法：将16只Wistar大鼠随机分成移植组与对照组,每组8只,均切断右后肢坐骨神经,并通过生物可降解膜包裹缺损神经断端形成神经再生室。用微量注射器抽取已配制成的肌干细胞悬液0.2 mL注入移植组的神经再生室内。对照组注入等量的生理盐水。术后4,8和12周进行大鼠行步态测定,并用锇酸染色法制片观察缺损神经再生情况。观测大鼠坐骨神经功能指数、腓肠肌湿质量恢复率、再生的有髓神经纤维数量和直径及髓鞘厚度的变化。 结果与结论：大鼠经肌卫星细胞移植后腓肠肌湿质量残存率、再生的有髓神经纤维数目、直径及髓鞘厚度等项检测指标与对照组相比均差异有显著性意义(P < 0.05)。术后8和12周,移植组坐骨神经功能指数恢复情况明显优于对照组(P < 0.05)。实验结果提示在神经再生室中加入肌卫星细胞能促进缺损神经纤维的再生及其结构的成熟。 关键词：肌卫星细胞;生物可降解膜;异体;细胞移植;周围神经缺损;神经再生     

1102/异种神经脱细胞移植物桥接大鼠坐骨神经缺损

目的　探讨异种神经脱细胞移植物桥接大鼠坐骨神经缺损后的神经再生及其再生过程中免疫排斥反应。 方法　用脱细胞兔周围神经作为移植物桥接大鼠坐骨神经1cm缺损;术后3、5、8、11、15天检测血液中淋巴细胞占白细胞百分比;3个月后取移植物及腓肠肌,用甲苯胺蓝、乙酰胆碱酯酶(AchE)、琥珀酸脱氢酶(SDH)组化染色,光、电镜观察神经再生及腓肠肌运动终板的恢复情况。　 结果　术后大鼠血液中淋巴细胞占白细胞的百分比与正常大鼠相比较无显著性差异,3个月后大鼠术侧下肢足趾能分开,行走时后蹬动作有力,针刺足底有逃避反应,桥接物内见有大量再生的坐骨神经纤维,腓肠肌肌纤维上见有呈AchE阳性的运动终板和神经纤维。　 结论　异种神经脱细胞移植物桥接大鼠坐骨神经缺损具有促进其再生的作用。     

去细胞同种异体神经种植许旺细胞的体外实验：组织工程化人工神经应用的可行性

目的：许旺细胞作为种子细胞在组织工程化人工神经制备中的作用已被学术界所接受。胎兔的神经系统已发育完善，而免疫系统尚未成熟，探讨将胎兔许旺细胞植入去细胞同种异体神经桥接体制备组织工程化人工神经修复周围神经缺损的可行性。 方法：实验于2005-03/2006-03在河北医科大学第三医院完成。①实验材料：SPF级怀孕28 d的新西兰白兔2只、成年新西兰白兔1只。②实验过程：包括胎兔许旺细胞培养、去细胞神经桥接体的制备以及许旺细胞与去细胞神经桥接体的体外种植3个步骤。使用双酶消化法培养许旺细胞并将其种植于经3% TritonX-100作用96 h后的同种异体神经中。③实验评估：分别于培养的1，3，5 d通过石蜡切片苏木精-伊红染色观察许旺细胞在桥接体中的生长情况。 结果：①采用双差速贴壁法去除绝大部分成纤维细胞后在细胞培养的初期使用阿糖胞苷抑制成纤维细胞生长，后期培养液中加入神经生长因子促进许旺细胞生长能获取大量许旺细胞且纯度可达90%以上。②用3%Triton X-100作用96 h可去除周围神经中的细胞和髓鞘而保留完整的神经基底膜管和纤维支架结构，并且对神经基底膜主要成分－层粘连蛋白无明显影响。③采用胎兔坐骨神经培养的许旺细胞能在用成年兔坐骨神经制备的去细胞桥神经接体中生长良好，并且有迁移成行的特性。 结论：种植许旺细胞重新细胞化的去细胞同种异体神经将可能成为一种理想的组织工程化人工神经。     

Synergistic effects of ultrashort wave and bone marrow stromal cells on nerve regeneration with acellular nerve allografts

Acellular nerve allografts (ANA) possess bioactivity and neurite promoting factors in nerve tissue engineering. Previously we reported that low dose ultrashort wave (USW) radiation could enhance the rate and quality of peripheral nerve regeneration with ANA repairing sciatic nerve defects. Meanwhile, ANA implanted with bone marrow stromal cells (BMSCs) exhibited a similar result. Thus, it is interesting to know whether it might yield a synergistic effect when USW radiation is combined with BMSCs‐laden ANA. Here we investigated the effectiveness of ANA seeded with BMSCs, combined with USW therapy on repairing peripheral nerve injuries. Adult male Wistar rats were randomly divided into four groups: Dulbecco's modified Eagle's medium (DMEM) control group, BMSCs‐laden group, ultrashort wave (USW) group and BMSC + USW group. The regenerated nerves were assayed morphologically and functionally, and growth‐promoting factors in the regenerated tissues following USW administration or BMSCs integration were also detected. The results indicated that the combination therapy caused much better beneficial effects evidenced by increased myelinated nerve fiber number, myelin sheath thickness, axon diameter, sciatic function index, nerve conduction velocity, and restoration rate of tibialis anterior wet weight. Moreover, the mRNA levels of brain‐derived neurotrophic factor (BDNF) and vascular endothelial growth factor (VEGF) in the spinal cord and muscles were elevated significantly. In conclusion, we found a synergistic effect of USW radiation and BMSCs treatment on peripheral nerve regeneration, which may help establish novel strategies for repairing peripheral nerve defects. Synapse 67:637–647, 2013 . © 2013 Wiley Periodicals, Inc.     

Bridging sciatic nerve gap using tissue-engineered nerves constructed with neural tissue-committed stem cells derived from bone marrow

BACKGROUND: Schwann cells are the most commonly used cells for tissue-engineered nerves. However, autologous Schwann cells are of limited use in a clinical context, and allogeneic Schwann cells induce immunological rejections. Cells that do not induce immunological rejections and that are relatively easy to acquire are urgently needed for transplantation.OBJECTIVE: To bridge sciatic nerve defects using tissue engineered nerves constructed with neural tissue-committed stem cells (NTCSCs) derived from bone marrow; to observe morphology and function of rat nerves following bridging; to determine the effect of autologous nerve transplantation, which serves as the gold standard for evaluating efficacy of tissue-engineered nerves.DESIGN, TIME AND SETTING: This randomized, controlled, animal experiment was performed in the Anatomical laboratory and Biomedical Institute of the Second Military Medical University of Chinese PLA between September 2004 and April 2006.MATERIALS: Five Sprague Dawley rats, aged 1 month and weighing 100-150 g, were used for cell culture. Sixty Sprague Dawiey rats aged 3 months and weighing 220-250 g, were used to establish neurological defect models. Nestin, neuron-specific enolase (NSE), glial fibrillary acidic protein (GFAP), and S-100 antibodies were provided by Santa Cruz Biotechnology, Inc., USA. Acellular nerve grafts were derived from dogs.METHODS: All rats, each with 1-cm gap created in the right sciatic nerve, were randomly assigned to three groups. Each group comprised 20 rats. Autograft nerve transplantation group: the severed 1-cm length nerve segment was reverted, but with the two ends exchanged; the proximal segment was sutured to the distal sciatic nerve stump and the distal segment to the proximal stump. Blank nerve scaffold transplantation group: a 1-cm length acellular nerve graft was used to bridge the sciatic nerve gap. NTCSC engineered nerve transplantation group: a 1-cm length acellular nerve graft, in which NTCSCs were inoculated, was used to bridge the sciatic nerve gap.MAIN OUTCOME MEASURES: Following surgery, sciatic nerve functional index and electrophysiology functions were evaluated for nerve conduction function, including conduction latency, conduction velocity, and action potential peak. Horseradish peroxidase (HRP, 20%) was injected into the gastrocnemius muscle to retrogradely label the L4 and L5 nerve ganglions, as well as neurons in the anterior horn of the spinal cord, in the three groups. Positive expression of nestin, NSE, GFAP, and S-100 were determined using an immunofluorescence double-labeling method.RESULTS: NTCSCs differentiated into neuronal-like cells and glial-like cells within 12 weeks after NTCSC engineered nerve transplantation. HRP retrograde tracing displayed a large amount of HRP-labeted neurons in L4-5 nerve ganglions, as well as the anterior horn of the spinal cord, in both the autograft nerve transplantation and the NTCSC engineered nerve transplantation groups. However, few HRP-labeled neurons were detected in the blank nerve scaffold transplantation group. Nerve bridges in the autograft nerve transplantation and NTCSC engineered nerve transplantation groups exhibited similar morphology to normal nerves. Neither fractures or broken nerve bridges nor neuromas were found after bridging the sciatic nerve gap with NTCSCs-inoculated acellular nerve graft, indicating repair. Conduction latency, action potential, and conduction velocity in the NTCSC engineered nerve transplantation group were identical to the autograft nerve transplantation group (P>0.05), but significantly different from the blank nerve scaffold transplantation group (P<0.05). CONCLUSION: NTCSC tissue-engineered nerves were able to repair injured nerves and facilitated restoration of nerve conduction function, similar to autograff nerve transplantation.     

Sciatic nerve regeneration in rats induced by transplantation of in vitro differentiated bone-marrow stromal cells

Bone marrow stromal cells (MSCs) are multipotent stem cells that have the potential to differentiate into bone, cartilage, fat and muscle. We now demonstrate that MSCs can be induced to differentiate into cells with Schwann cell characteristics, capable of eliciting peripheral nervous system regeneration in adult rats. MSCs treated with beta-mercaptoethanol followed by retinoic acid and cultured in the presence of forskolin, basic-FGF, PDGF and heregulin, changed morphologically into cells resembling primary cultured Schwann cells and expressing p75, S-100, GFAP and O4. The MSCs were genetically engineered by transduction with retrovirus encoding green fluorescent protein (GFP), and then differentiated by treatment with factors described above. They were transplanted into the cut ends of sciatic nerves, which then responded with vigorous nerve fibre regeneration within 3 weeks of the operation. Myelination of regenerated fibers by GFP-expressing MSCs was recognized using confocal and immunoelectron microscopy. The results suggest that MSCs are able to differentiate into myelinating cells, capable of supporting nerve fibre re-growth, and they can therefore be applied to induce nerve regeneration.     

Sciatic nerve repair by acellular nerve xenografts implanted with BMSCs in rats xenograft combined with BMSCs

Acellular nerves possess the structural and biochemical features similar to those of naive endoneurial tubes, and have been proved bioactive for allogeneil graft in nerve tissue engineering. However, the source of allogenic donators is restricted in clinical treatment. To explore sufficient substitutes for acellular nerve allografts (ANA), we investigated the effectiveness of acellular nerve xenografts (ANX) combined with bone marrow stromal cells (BMSCs) on repairing peripheral nerve injuries. The acellular nerves derived from Sprague-Dawley rats and New Zealand rabbits were prepared, respectively, and BMSCs were implanted into the nerve scaffolds and cultured in vitro. All the grafts were employed to bridge 1 cm rat sciatic nerve gaps. Fifty Wistar rats were randomly divided into five groups (n = 10 per group): ANA group, ANX group, BMSCs-laden ANA group, BMSCs-laden ANX group, and autologous nerve graft group. At 8 weeks post-transplantation, electrophysiological study was performed and the regenerated nerves were assayed morphologically. Besides, growth-promoting factors in the regenerated tissues following the BMSCs integration were detected. The results indicated that compared with the acellular nerve control groups, nerve regeneration and functional rehabilitation for the xenogenic nerve transplantation integrated with BMSCs were advanced significantly, and the rehabilitation efficacy was comparable with that of the autografting. The expression of neurotrophic factors in the regenerated nerves, together with that of brain-derived neurotrophic factor (BDNF) in the spinal cord and muscles were elevated largely. In conclusion, ANX implanted with BMSCs could replace allografts to promote nerve regeneration effectively, which offers a reliable approach for repairing peripheral nerve defects.     

组织工程周围神经修复坐骨神经缺损应用研究

目的应用组织工程方法构建周围神经以修复坐骨神经缺损.方法体外培养的雪旺细胞(SC)与牛去细胞基质(BAM)、胎牛血清和培养液按一定的比例混合注入聚乳酸聚羟基己酸共聚物(PLGA)导管中,构建成组织工程周围神经.30只SD大鼠随机分为3组,实验组:使用组织工程周围神经修复坐骨神经缺损;对照组:用不含雪旺细胞的导管修复;自体神经组:自体神经移植.16周后通过免疫组化、电生理、透射电镜、辣根过氧化物酶(HRP)逆行示踪及坐骨神经功能指数(SFI)等方法检测神经再生及坐骨神经功能恢复情况.结果 PLGA导管至16周已基本吸收,再生神经已通过缺损区长至远端,组织工程周围神经的修复效果接近自体神经组,优于空白组.结论体外构建的组织工程周围神经可以修复周围神经缺损.     

A novel tissue engineered nerve graft constructed with autologous vein and nerve microtissue repairs a long-segment sciatic nerve defect

Veins are easy to obtain, have low immunogenicity, and induce a relatively weak inflammatory response. Therefore, veins have the potential to be used as conduits for nerve regeneration. However, because of the presence of venous valves and the great elasticity of the venous wall, the vein is not conducive to nerve regeneration. In this study, a novel tissue engineered nerve graft was constructed by combining normal dissected nerve microtissue with an autologous vein graft for repairing 10-mm peripheral nerve defects in rats. Compared with rats given the vein graft alone, rats given the tissue engineered nerve graft had an improved sciatic static index, and a higher amplitude and shorter latency of compound muscle action potentials. Furthermore, rats implanted with the microtissue graft had a higher density and thickness of myelinated nerve fibers and reduced gastrocnemius muscle atrophy compared with rats implanted with the vein alone. However, the tissue engineered nerve graft had a lower ability to repair the defect than autogenous nerve transplantation. In summary, although the tissue engineered nerve graft constructed with autologous vein and nerve microtissue is not as effective as autologous nerve transplantation for repairing long-segment sciatic nerve defects, it may nonetheless have therapeutic potential for the clinical repair of long sciatic nerve defects. This study was approved by the Experimental Animal Ethics Committee of Chinese PLA General Hospital (approval No. 2016-x9-07) on September 7, 2016.

Chinese Library Classification No. R456; R363; R741     

Combining chitin biological conduits with small autogenous nerves and platelet-rich plasma for the repair of sciatic nerve defects in rats

AimsPeripheral nerve defects are often difficult to recover from, and there is no optimal repair method. Therefore, it is important to explore new methods of repairing peripheral nerve defects. This study explored the efficacy of nerve grafts constructed from chitin biological conduits combined with small autogenous nerves (SANs) and platelet‐rich plasma (PRP) for repairing 10‐mm sciatic nerve defects in rats.MethodsTo prepare 10‐mm sciatic nerve defects, SANs were first harvested and PRP was extracted. The nerve grafts consisted of chitin biological conduits combined with SAN and PRP, and were used to repair rat sciatic nerve defects. These examinations, including measurements of axon growth efficiency, a gait analysis, electrophysiological tests, counts of regenerated myelinated fibers and observations of their morphology, histological evaluation of the gastrocnemius muscle, retrograde tracing with Fluor‐Gold (FG), and motor endplates (MEPs) distribution analysis, were conducted to evaluate the repair status.ResultsTwo weeks after nerve transplantation, the rate and number of regenerated axons in the PRP‐SAN group improved compared with those in the PRP, SAN, and Hollow groups. The PRP‐SAN group exhibited better recovery in terms of the sciatic functional index value, composite action potential intensity, myelinated nerve fiber density, myelin sheath thickness, and gastrectomy tissue at 12 weeks after transplantation, compared with the PRP and SAN groups. The results of FG retrograde tracing and MEPs analyses showed that numbers of FG‐positive sensory neurons and motor neurons as well as MEPs distribution density were higher in the PRP‐SAN group than in the PRP or SAN group.ConclusionsNerve grafts comprising chitin biological conduits combined with SANs and PRP significantly improved the repair of 10‐mm sciatic nerve defects in rats and may have therapeutic potential for repairing peripheral nerve defects in future applications.     

Repair of extended peripheral nerve lesions in rhesus monkeys using acellular allogenic nerve grafts implanted with autologous mesenchymal stem cells

Despite intensive efforts in the field of peripheral nerve injury and regeneration, it remains difficult in humans to achieve full functional recovery following extended peripheral nerve lesions. Optimizing repair of peripheral nerve injuries has been hindered by the lack of viable and reliable biologic or artificial nerve conduits for bridging extended gaps. In this study, we utilized chemically extracted acellular allogenic nerve segments implanted with autologous non-hematopoietic mesenchymal stem cells (MSCs) to repair a 40 mm defect in the rhesus monkey ulnar nerve. We found that severely damaged ulnar nerves were structurally and functionally repaired within 6 months following placement of the MSC seeded allografts in all animals studied (6 of 6, 100%). Furthermore, recovery with the MSC seeded allografts was similar to that observed with Schwann cell seeded allografts and autologous nerve grafts. The findings presented here are the first demonstration of the successful use of autologous MSCs, expanded in culture and implanted in a biological conduit, to repair a peripheral nerve gap in primates. Given the difficulty in isolating and purifying sufficient quantities of Schwann cells for peripheral nerve regeneration, the use of MSCs to seed acellular allogenic nerve grafts may prove to be a novel and promising therapeutic approach for repairing severe peripheral nerve injuries in humans.