聚己内酯/壳聚糖神经导管复合骨髓间充质干细胞促进大鼠坐骨神经损伤修复的研究

目的:观察聚己内酯/壳聚糖神经导管复合骨髓间充质干细胞修复大鼠坐骨神经缺损的效果。方法:将24只SD大鼠随机分为4组,制备右侧坐骨神经5mm缺损模型,A组聚己内酯/壳聚糖神经导管复合骨髓间充质干细胞移植组;B组聚己内酯神经导管复合骨髓间充质干细胞移植组;C组壳聚糖神经导管复合骨髓间充质干细胞移植组;D组自体神经移植组。术后每2周进行坐骨神经功能指数检测,12周时行电生理、腓肠肌湿重恢复率、组织学观察和免疫组织化学检测。结果:坐骨神经功能指数显示,A组运动功能恢复速度较B、C组快,但比D组慢。A组电生理和腓肠肌湿重恢复率的检测结果与C、D组相比无统计学意义(P0.05),但优于B组(P0.05)。组织学观察,A组再生神经纤维排列密集。S-100免疫组织化学结果表明A组有大量雪旺细胞增生。结论:聚己内酯/壳聚糖神经导管复合骨髓间充质干细胞能够促进周围神经损伤修复,效果与壳聚糖神经导管、自体神经相同,优于聚己内酯神经导管。     

三维取向PLGA神经导管促进坐骨神经再生的实验研究

目的:探讨应用改进静电纺丝技术一次成型制备三维(3D)取向聚乳酸与聚羟基乙酸共聚物(PLGA)纳米神经导管的可行性,检测其对坐骨神经再生的促进作用。方法:应用改进的静电纺丝技术制备无缝取向PLGA纳米神经导管,通过扫描电镜和透射电镜检测支架的纳米结构;分别制备取向和非取向纳米纤维支架修复13mm坐骨神经缺损模型。36只成年SD大鼠随机分为3组(每组12只),A组:非取向PLGA神经导管组(阴性对照);B组:取向PLGA神经导管组,C组:自体神经移植组(阳性对照),于术后3月通过大体观察、行走足印分析、腓肠肌萎缩率、电生理检测、组织形态学检测、透射电镜检测及图像分析,评价无缝取向PLGA纳米神经导管修复坐骨神经缺损的效果。结果:神经导管修复神经缺损三月后,大体观察显示神经导管结构完整,无坍塌和断裂;各组再生神经均有通过神经导管长入远端。B组与C组的腓肠肌萎缩率和神经电传导速度无统计学差异(P0.05),均优于A组。B组与C组再生神经纤维数量及成熟程度均要明显优于A组。结论:无缝取向PLGA纳米神经导管能够诱导并促进神经再生,提高坐骨神经再生的质量,有望成为自体神经移植的替代物。     

嗅鞘细胞复合PLGA导管修复周围神经缺损的研究

探讨嗅鞘细胞(OECs)复合聚乳酸-聚羟基乙酸共聚物(PLGA)导管对大鼠坐骨神经缺损的修复作用。方法:SD大鼠80只,随机分成4组,切除右侧部分神经干造成10mm的神经缺损。OECs PLGA组用充满细胞外基质凝胶和OECs悬液(CM-DiI预标记)的PLGA导管桥接坐骨神经缺损;OECs 硅胶管组用含相同内容物的硅胶管桥接;PLGA组和硅胶管组则分别用充满细胞外基质凝胶和DMEM/F12培养基的PLGA导管和硅胶管桥接。术后每周进行感觉运动功能检测,8周时行腓肠肌湿重恢复率、乙酰胆碱脂酶(AChE)染色、电生理和组织形态学分析等检测,同时移植细胞的两组每周进行细胞示踪观察。结果:移植细胞沿神经纵轴分布;除坐骨神经功能指数(SFI)指标外,OECs PLGA组的各项再生功能指标均优于其它三组。结论:OECs复合PLGA导管能够促进再生神经的成熟和靶组织功能的恢复,二者联合移植是一种有效的周围神经缺损修复方法。     

三维取向PLGA神经导管促进坐骨神经再生的实验研究

目的：探讨应用改进静电纺丝技术一次成型制备三维（3D）取向聚乳酸与聚羟基乙酸共聚物（PLGA）纳米神经导管的可行性,检测其对坐骨神经再生的促进作用。方法：应用改进的静电纺丝技术制备无缝取向PLGA纳米神经导管,通过扫描电镜和透射电镜检测支架的纳米结构;分别制备取向和非取向纳米纤维支架修复13mm坐骨神经缺损模型。36只成年SD大鼠随机分为3组（每组12只）,A组：非取向PLGA神经导管组（阴性对照）;B组：取向PLGA神经导管组,C组：自体神经移植组（阳性对照）,于术后3月通过大体观察、行走足印分析、腓肠肌萎缩率、电生理检测、组织形态学检测、透射电镜检测及图像分析,评价无缝取向PLGA纳米神经导管修复坐骨神经缺损的效果。结果：神经导管修复神经缺损三月后,大体观察显示神经导管结构完整,无坍塌和断裂;各组再生神经均有通过神经导管长入远端。B组与C组的腓肠肌萎缩率和神经电传导速度无统计学差异（P〈0.05）,均优于A组。B组与C组再生神经纤维数量及成熟程度均要明显优于A组。结论：无缝取向PLGA纳米神经导管能够诱导并促进神经再生,提高坐骨神经再生的质量,有望成为自体神经移植的替代物。     

骨髓间充质干细胞和内皮祖细胞移植促进血流重建的比较

目的:比较骨髓间充质细胞(Bone Marrow Mesenchymal Stem Cells,BM/MSC)和骨髓源内皮祖细胞(Bone Marrow Endothelialprogenitor cells,BM/EPC)移植促进血流重建的效果,为进一步优化骨髓干细胞移植治疗肢体缺血提供理论基础。方法:获取Lewis大鼠骨髓单个核细胞,在体外培养分化为MSC和EPC。采用Lewis大鼠建立单侧后肢缺血模型。在模型建立后3天,将0.8mlD-Hanks液注入大鼠缺血侧后肢,为对照组(n=6);将8×106个骨髓MSC植入大鼠缺血侧后肢,为MSC组(n=6);将体外培养的8×106个EPC植入大鼠缺血侧后肢,为EPC组(n=6)。细胞移植后3周行缺血大鼠后肢动脉造影,检测缺血侧后肢侧支血管数;获取缺血侧后肢腓肠肌,分别行CD31和α-SMA免疫组化染色,计算毛细血管密度和小动脉密度。结果:MSC组与EPC组侧支血管数无显著性差异,二者均高于对照组;EPC组毛细血管密度明显高于MSC组,二者均高于对照组;MSC组与EPC组小动脉密度无显著性差异,二者均高于对照组。结论:骨髓间充质干细胞移植和内皮祖细胞移植均能够明显促进血流重建,而且骨髓间充质干细胞在治疗肢体缺血性疾病中的优势应该受到重视。     

内皮祖细胞移植加速鼠颈动脉内皮修复预防再狭窄的研究

目的：以安慰机组作对照,观察EPCs自体移植防治再狭窄的疗效以及该作用与血管再内皮化是否相关。方法：共30只雄性SD大鼠纳入实验,随机均分为假手术组、安慰剂组和EPCs移植组。造模前3周时取血3毫升,M199培养基培养传代,行EPCs鉴定,移植组在球囊损伤后即予尾静脉注射1×10^6个EPCs自体移植。4周后观察再狭窄和再内皮化程度。结果：与安慰剂组相比,EPCs自体移植组再内皮化程度提高,再狭窄程度减轻;EPCs移植组内膜／中膜比值与再内皮化率呈线性负相关。结论：EPCs体外扩增自体移植可预防再狭窄;其机制与加速再内皮化有关。     

HRP法对异种神经移植后再生纤维恢复的形态学研究

目的用辣根过氧化酶(HRP)逆行追踪技术探讨异种神经移植后神经纤维的再生.方法将多次冻融处理后的兔胫神经移植于大鼠坐骨神经,术后第2、4、6、8和10周,将HRP注人大鼠坐骨神经吻合部远侧端.结果移植术后第4周起在L4～5脊神经节见到HRP标记细胞,从第6周在腰段脊髓前角内见到标记细胞,其数量随术后存活期延长而增多.术后4周在移植神经内见少量再生神经纤维,6周后再生神经纤维穿过异种移植神经进入大鼠坐骨神经远侧端.结论自移植术后4周起,移植神经内已有再生纤维并部分恢复了轴浆流,证实了用HRP法可反映移植后神经纤维的再生情况.     

骨髓间充质干细胞与施万细胞联合移植对大鼠周围神经 损伤端侧吻合的修复效果研究

目的:探究骨髓间充质干细胞(MSCs)与施万细胞(SCs)联合移植对大鼠周围神经损伤端侧吻合的修复效果。方法:选取SD雌性大鼠60只均制作成坐骨神经损伤端侧吻合模型,并将其随机分为联合移植组、MSCs组和SCs组,分别对吻合端进行骨髓间充质干细胞与SCs联合移植、MSCs移植、SCs移植。观察分析三组大鼠的神经电生理学指标和腓神经功能指数(PFI)和神经传导速度(NCV)。结果:三组大鼠的PFI和NCV均有所改善,且联合移植组的PFI和NCV均优于其他两组,并随着时间推移损伤坐骨神经功能恢复越来越好。结论:MSCs与SCs均具有促进大鼠周围神经身上修复的功能,且两种细胞联合移植效果更加明显。     

不同移植物对兔前叉韧带重建术后血运变化的影响

目的：比较自体和同种异体半肌腱重建兔前叉韧带对血管生成的影响。方法：选择48 只骨骼发育成熟的新西兰种属兔作为 研究对象,将其随机分为自体组(A 组)和异体组(B 组),每组24 只,分别接受半肌腱重建前叉韧带手术。从手术日期开始,分别记 录手术后第3 周、第6 周、第12 周和第24 周重建韧带的血管生成情况同时对血管生成数量进行定量。结果：手术后两组实验兔 关节均无肿胀,关节囊无炎性反应发生。在手术后第3 周,两组血管生成无明显差异(P>0.05);术后第6 周和第12周,自体移植组 新生血管数量明显高于异体移植组(P<0.05);术后第24 周,异体组新生血管数量明显高于自体组(P<0.05)。结论：在兔前叉韧带的 重建过程中,异体移植物重建的血管生成速度和数量明显慢于自体移植物,提示在临床上选择自体移植物对术后恢复更理想.     

阿尔茨海默氏病大鼠海马内植入神经干细胞后效果观察

目的：观察神经干细胞植入阿尔茨海默氏病（AD）大鼠海马内的存活和增殖情况,以及对学习记忆能力的影响一方法：从新生大鼠海马齿状回分离、培养神经干细胞,经Hoechst33258标记后植入AD模型大鼠海马,2周和4周后,行Y迷宫实验检测大鼠的学习记忆能力,然后取脑进行荧光观察和PCNA免疫组织化学染色。结果：与AD组相比,2周移植组和4周移植组大鼠的学习能力和记忆能力有明显提高一移植的神经干细胞能在海马存活,与周围组织建立良好的整合,还可沿海马CAl区迁移,而且在海马CAl区内可见许多PCNA阳性细胞：结论：新生大鼠海马齿状回神经干细胞移植到AD大鼠海马内能够存活、增殖,并能改善AD大鼠的学习能力和记忆能力。     

Combined Wharton’s jelly derived mesenchymal stem cells and nerve guidance conduit: A potential promising therapy for peripheral nerve injuries

BackgroundPeripheral nerve injuries represent a clinical problem with insufficient or unsatisfactory treatment options. Functional outcome with nerve guidance conduits was unsatisfactory in nerve defects with increased gap size. So, cell therapy may benefit as a tool for optimizing the regeneration process. The aim of the present study was to evaluate the impact of combination of cell therapy and nerve guidance conduits on the nerve regeneration and on the expression of the factors aiding the regeneration in a rat model of sciatic nerve injury.Methods and resultsSixty Wistar rats were randomly divided into four groups: Group I: normal control group; Group II: sciatic nerve injury (SNI) with a 10 mm long sciatic nerve gap; Group III: SNI with using a nerve conduit (NC) for nerve gap bridging; and Group IV: SNI with using a NC associated with Wharton’s jelly derived mesenchymal stem cells (WJ-MSCs). The results showed that the combination therapy NC + WJ-MSCs caused much better beneficial effects than NC alone evidenced by increasing sciatic nerve index and pin-prick score. The histopathological analysis found that the use of the NC combined with WJ[HYPHEN]MSCs resulted in a structure of the sciatic nerve comparable to the normal one with better nerve regeneration when compared with NC only. There was no differentiation of WJ-MSCs into nerve structure. Lastly, there was an upregulation of expression for netrin-1, ninjurin, BDNF, GDNF, VEGF and angiopoitin-1 rat genes in NC + WJ-MSCs group than NC alone.ConclusionThe addition of WJ-MSCs to the nerve guidance conduits seems to bring significant advantage for nerve regeneration, basically by increasing the expression of neurotrophic and angiogenic factors establishing more favorable environment for nerve regeneration.     

Physical properties and biocompatibility of a porous chitosan-based fiber-reinforced conduit for nerve regeneration

Porous fiber-reinforced chitosan nerve conduits were fabricated from chitosan yarns and a chitosan solution by combining an industrial braiding method with a mold casting/lyophilization technique. The conduits were permeable to molecules ranging in molecular size from 180 Da (glucose) to 66,200 Da (BSA). The compressive load of the reinforced conduits was significantly higher than that of a non-reinforced control conduit at equal levels of strain. The tensile strength of the reinforced conduits was also increased from 0.41 ± 0.17 to 3.69 ± 0.64 MPa. An in vitro cytotoxicity test showed the conduits were not cytotoxic to Neuro-2a cells. Preliminary in vivo implantation testing indicated that the conduits were compatible with the surrounding tissue. Aijun Wang and Qiang Ao contributed equally to this work.     

A prospective clinical evaluation of autogenous vein grafts used as a nerve conduit for distal sensory nerve defects of 3 cm or less

The purpose of this study was to determine the efficacy of autogenous vein grafts as nerve grafts (AVNC) for bridging of small peripheral sensory nerve gaps as compared with direct repair and with conventional nerve grafting techniques (ANG). Patients with painful neuroma or segmental nerve injury of 3 cm were chosen as the test group. Those amenable to direct repair were classified as controls. Between 1982 to 1988, a total of 22 patients were enrolled in this study. A total of 34 nerves were repaired, 15 with a venous nerve conduit, 4 with a sural nerve graft, and 15 with direct repair. Significant symptom relief and satisfactory sensory function return were uniformly observed. The two-point discrimination measurements indicated superiority of direct repair and probably of conventional nerve grafting. However, the universally favorable patient acceptance and the return of measurable two-point discrimination indicates the effectiveness of autogenous vein grafts as nerve conduits when selectively applied to bridge a small nerve gap (less than or equal to 3 cm) on nonessential peripheral sensory nerves.     

神经导管研究与进展

随着机械化程度的提高和交通事业的发展,周围神经损伤发生率大幅度的上升。虽然通过手术的方法可以进行端对端的缝合,但是神经恢复的效果仍然不理想,特别是存在神经短距离缺损时,神经导管可为神经的修复提供一个合适的微环境,使得神经纤维能够再生并顺利到达远端。本文介绍了受损神经恢复效果的评价标准,神经导管材料的研究进展,神经生长因子对神经再生的影响因素及作用机理,和神经导管的制备方法,且在总结前人研究的基础上,给出适合于神经导管支架所需的材料和结构要求。     

神经刺激仪经肌间沟定位臂丛神经分支行臂丛麻醉效果分析

目的：比较神经刺激仪经肌间沟定位臂丛神经分支行肌间沟臂丛神经阻滞麻醉的效果及安全性。方法：选择拟行肌间沟臂丛神经阻滞的上肢手术的患者80例,ASAI或II级,随机均分为A组和B组,每组40例患者。两组均给予1％的利多卡因＋0．375％耐乐品20mL。记录完成操作所需时间、感觉神经阻滞起效时间、感觉神经阻滞完善时间、运动神经阻滞起效时间、运动神经阻滞完善时间;评价手术区域麻醉效果（优、良、差、失败）;观察并记录并发症。结果：A组完成操作所需时间（5．01±1．40）min,明显长于B组（2．83＋O．87）min（P〈0．01）。A组感觉阻滞起效时间（4．48±1．36）min,明显短于B组（7．0±2．06）min（P〈0．01）;A组运动阻滞起效时间（4．88＋±1．18）min,明显短于B组（7．0±1．67）min（P〈0．01）。A组感觉阻滞完善时间（11．73±3．62）短于B组（13．33±3．02）min（P=0．033）。A组运动阻滞完善时间（11．18±2．73）短于B组（12．41±2．48）min（P=0．038）;麻醉效果优等率A组为87．5％,B组为67．5％,差异有统计学意义x^2=4．588,P=0．032;优良率A组为97．5％,B组为90．0％,差异无统计学意义x2=1．920,P=0．166;A组、B组均未出现严重麻醉并发症。结论：A组行肌间沟臂丛神经阻滞比B组阻滞操作时间长,但神经阻滞麻醉效果好,神经阻滞完善率高。     

Use new PLGL-RGD-NGF nerve conduits for promoting peripheral nerve regeneration

ABSTRACT: BACKGROUND: Nerve conduits provide a promising strategy for peripheral nerve injury repair. However, the efficiency of nerve conduits to enhance nerve regeneration and functional recovery is often inferior to that of autografts. Nerve conduits require additional factors such as cell adhesion molecules and neurotrophic factors to provide a more conducive microenvironment for nerve regeneration. METHODS: In the present study, poly{(lactic acid)-co-[(glycolic acid)-alt-(L-lysine)]} (PLGL) was modified by grafting Gly-Arg-Gly-Asp-Gly (RGD peptide) and nerve growth factor (NGF) for fabricating new PLGL-RGD-NGF nerve conduits to promote nerve regeneration and functional recovery. PLGL-RGD-NGF nerve conduits were tested in the rat sciatic nerve transection model. Rat sciatic nerves were cut off to form a 10 mm defect and repaired with the nerve conduits. All of the 32 Wistar rats were randomly divided into 4 groups: group PLGL-RGD-NGF, group PLGL-RGD, group PLGL and group autograft. At 3 months after surgery, the regenerated rat sciatic nerve was evaluated by footprint analysis, electrophysiology, and histologic assessment. Experimental data were processed using the statistical software SPSS 10.0. RESULTS: The sciatic function index value of groups PLGL-RGD-NGF and autograft was significantly higher than those of groups PLGL-RGD and PLGL. The nerve conduction velocities of groups PLGL-RGD-NGF and autograft were significantly faster than those of groups PLGL-RGD and PLGL. The regenerated nerves of groups PLGL-RGD-NGF and autograft were more mature than those of groups PLGL-RGD and PLGL. There was no significant difference between groups PLGL-RGD-NGF and autograft. CONCLUSIONS: PLGL-RGD-NGF nerve conduits are more effective in regenerating nerves than both PLGL-RGD nerve conduits and PLGL nerve conduits. The effect is as good as that of an autograft. This work established the platform for further development of the use of PLGL-RGD-NGF nerve conduits for clinical nerve repair.     

Autogenous vein graft repair of digital nerve defects in the finger: a retrospective clinical study

Twenty-two digital nerve repairs were performed in the finger using autogenous vein grafts. Eighty-two percent of the repairs were available for follow-up. Results of sensibility return were assessed using moving two-point discrimination, Semmes-Weinstein monofilaments, and vibratory testing. Two-point discrimination averaged 4.6 mm for 11 acute digital nerve repairs using vein conduits 1 to 3 cm in length. Delayed digital nerve repair with vein conduits yielded poor results. Semmes-Weinstein values demonstrated comparable levels of return of slowly adapting fiber/receptors to the quickly adapting fiber/receptors, as evidenced by moving two-point discrimination tests. Vibratory sensibility was present in all. A review of previous experiences with end-to-end digital neurorrhaphies and digital nerve grafting suggests that repair of 1- to 3-cm gaps in digital nerves with segments of autologous vein grafts appears to give comparable results to nerve grafting. Further laboratory and clinical research is necessary to better define the role of interpositional vein conduits for repair of peripheral nerves.     

A novel basic fibroblast growth factor delivery system fabricated with heparin-incorporated fibrin–fibronectin matrices for repairing rat sciatic nerve disruptions

Autologous nerve grafts are widely used in bridging critical gaps of peripheral nerves, but they remain associated with high morbidity of the donor site and lack of full recovery. As an alternative, we have focused on chitosan nerve conduits filled with a heparin-incorporated fibrin–fibronectin matrix serving as delivery systems for basic fibroblast growth factor (bFGF). The artificial nerve conduits were used for repairing sciatic nerve defects of 10 mm in adult rats. Three months post-operation, the conduction velocity recovery index (CVRI) and the muscle restoration rate (MRR) in animals of the experimental group were 32 ± 4.1 and 77.4 ± 7.9%, respectively, which were significantly higher than those of the PBS control group (17.8 ± 1.9 and 66.7 ± 6.5%), and similar to those of the autograft group (38.4 ± 3.9 and 81.3 ± 7.8%). These results were also consistent with the densities of regenerated axons in the three groups, which were demonstrated by histomorphological analysis.