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。     

植入血管束的血管化人工神经导管对受损神经功能恢复影响的实验研究

目的:研究植入血管束的血管化人工神经导管修复SD大鼠长段坐骨神经缺损对神经功能恢复的影响。方法:将18只成年雌性SD大鼠制成14mm的大鼠坐骨神经缺损模型后,随机分为3组(每组12条神经),分别采用不同的修复方法。A组:自体神经移植组(自体组);B组:普通PGLA神经导管移植组(导管组);C组:植入自体血管束的普通PGLA神经导管移植组(血管化导管组)。观察术后大鼠后肢皮肤溃疡面积;检测术后6周、12周时步态变化和肌电图。结果:术后各组SD大鼠均出现后肢溃疡,血管化导管组SD大鼠后肢溃疡愈合较导管组早2周。血管化导管组步态检测SFI明显优于导管组,与自体神经移植组无明显差异。肌电图检测表明血管化导管组无论是神经传导速度,还是动作电位振幅均明显大于导管组(P<0.05),与自体神经移植组无明显差异(P>0.05)。结论:植入血管束的血管化人工神经导管能有效地促进受损神经的功能恢复。     

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(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。     

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。     

黄豆芽是观察导管的好材料

导管是植物体内运输水分和无机盐的结构,由于导管侧壁加厚形式的不同,因而形成了五种不同类型的导管。它们是环纹导管、螺纹导管、梯纹导管、网纹导管和孔纹导管。这五种不同类型的导管并不一定同时存在于某一个植物体内。所以要同时观察到五种不同类型的导管比较困难。我们在教学实践中用黄豆芽作材料观察导管,取得了很好的效果。     

人工神经导管原材料选择与功能设计的研究进展

人工神经导管（nerve guidance conduits,NGCs）作为一种合成的神经移植物,为神经再生提供结构与营养支持。理想的神经导管对生物相容性、机械强度、拓扑结构和导电性等均有较高要求,因此需对神经导管的设计不断改进并建立更完善的周围神经再生策略,以期满足临床需求。虽然NGCs在周围神经损伤的治疗中已经取得一定进展,但其对长距离神经离断伤的结构与功能修复仍不理想。本文分别从原材料选择、结构设计、治疗因子搭载及自供电元件集成4个方面对神经导管的设计进行综述,归纳总结NGCs在周围神经损伤治疗中的研究进展,以期推动NGCs的迭代更新与临床转化。     

不同喂食方法对产后野生中华鲟的摄食促进

2006年1月13日~7月15日,研究了不同喂食方法对产后野生雌性中华鲟(Acipenser sinensis)的摄食促进效果。研究表明,经人工繁殖后的中华鲟身体较虚弱,在人工环境下无主动摄食行为。野生中华鲟对投洒的人工配合饲料及天然饲料均无摄食反应,水下直接喂食天然饲料的效果依赖于中华鲟主动摄食能力的恢复,而采用导管喂食方法可以实现中华鲟的被动摄食,摄食量由76g逐步增加至382g,20d后开始出现主动摄食行为,日食量逐步上升至1822g并趋于稳定。导管喂食过程中健康状况也逐步得到改善,胸围和腹围开始提高,主动摄食后健康状况得到彻底改善。实验表明产后野生中华鲟的体能恢复有望在水族馆较好的环境条件中得以实现。     

B超声引导下肋锁间隙与喙突入路连续臂丛神经阻滞对Barton骨折术后镇痛效果比较

目的:比较超声引导下肋锁间隙与喙突两种入路连续臂丛神经阻滞对Barton骨折手术患者术后的镇痛效果。方法:选择择期行Barton骨折手术患者60例,随机分为肋锁间隙入路连续臂丛神经阻滞组(A组,n=30)和喙突入路连续锁骨下臂丛神经阻滞组(B组,n=30)。两组均在超声引导下进行臂丛神经阻滞,同时留置神经阻滞导管,麻醉后2小时经神经阻滞导管连接无线电子镇痛泵。记录手术过程中神经深度、麻醉操作时间,并评估麻醉效果;记录术后第一次追加药物时间;记录麻醉后6 h、12 h、18 h、24 h、36 h、48 h静息及运动状态VAS评分;记录术后第一天和第二天镇痛泵有效按压次数及补救镇痛情况;记录患者满意度及并发症发生情况。结果:与B组相比,A组神经深度明显减浅(P<0.05),麻醉操作时间显著缩短(P<0.05),术后第一次追加药物时间延长(P<0.05),麻醉后12 h、18 h、24 h、36 h静息及运动状态VAS评分较低(P<0.05),术后第一天有效按压次数明显减少(P<0.05),患者满意度评分高(P<0.05),误穿血管发生率明显减少(P<0.05)。结论:超声引导下肋锁间隙入路与喙突入路连续锁骨下臂丛神经阻滞均可安全有效用于Barton骨折手术术后镇痛;但肋锁间隙连续臂丛神经阻滞术后镇痛效果更好,且具有神经阻滞深度浅、操作时间更短、阻滞效果更好、患者满意度更高及并发症更少等优点。     

几种观察导管的方法

我們在准备实驗中,为了使同学能清楚地了解各种导管类型,采用了如下新鮮材料,經过处理,制成临时装片,下仅能清楚看到导管的加厚,而且也可以看到篩管和伴胞。利用这种方法,我們感到既簡单又方便,其效果胜过我們自己做的永久制片。現将我們制作的过程介紹如下:     

A nanofibrous PHBV tube with Schwann cell as artificial nerve graft contributing to Rat sciatic nerve regeneration across a 30-mm defect bridge

Abstract

A nanofibrous PHBV nerve conduit has been used to evaluate its efficiency based on the promotion of nerve regeneration in rats. The designed conduits were investigated by physical, mechanical and microscopic analyses. The conduits were implanted into a 30-mm gap in the sciatic nerves of the rats. Four months after surgery, the regenerated nerves were evaluated by macroscopic assessments and histology. This polymeric conduit had sufficiently high mechanical properties to serve as a nerve guide. The results demonstrated that in the nanofibrous graft with cells, the sciatic nerve trunk had been reconstructed with restoration of nerve continuity and formatted nerve fibers with myelination. For the grafts especially the nanofibrous conduits with cells, muscle cells of gastrocnemius on the operated side were uniform in their size and structures. This study proves the feasibility of artificial conduit with Schwann cells for nerve regeneration by bridging a longer defect in a rat model.     

Engineering a prokaryotic apocytochrome c as an efficient substrate for Saccharomyces cerevisiae cytochrome c heme lyase

In spite of the extensive research using induced pluripotent stem (iPS) cells, the therapeutic potential of iPS cells in the treatment of peripheral nerve injury is largely unknown. In this study, we repaired peripheral nerve gaps in mice using tissue-engineered bioabsorbable nerve conduits coated with iPS cell-derived neurospheres. The secondary neurospheres derived from mouse iPS cells were suspended in each conduit (4000,000 cells per conduit) and cultured in the conduit in three-dimensional (3D) culture for 14 days. We then implanted them in the mouse sciatic nerve gaps (5 mm) (iPS group; n=10). The nerve conduit alone was implanted in the control group (n=10). After 4, 8 and 12 weeks, motor and sensory functional recovery in mice were significantly better in the iPS group. At 12 weeks, all the nerve conduits remained structurally stable without any collapse and histological analysis indicated axonal regeneration in the nerve conduits of both groups. However, the iPS group showed significantly more vigorous axonal regeneration. The bioabsorbable nerve conduits created by 3D-culture of iPS cell-derived neurospheres promoted regeneration of peripheral nerves and functional recovery in vivo. The combination of iPS cell technology and bioabsorbable nerve conduits shows potential as a future tool for the treatment of peripheral nerve defects.     

Nerve conduit based on HAP/PDLLA/PRGD for peripheral nerve regeneration with sustained release of valproic acid

The nerve conduits have been developed for nerve defect repair. However, no artificial conduits have obtained comparable results to autografts to bridge the large gaps. A possible reason for this poor performance may be a lack of sustainable neurotrophic support for axonal regrowth. Previous studies suggested nanocomposite conduits can be used as a carrier for valproic acid (VPA), a common drug that can produce effects similar to the neurotrophic factors. Here, we developed the novel bioabsorbable conduits based on hydroxyapatite/poly d -l -lactic acid (PDLLA)/poly{(lactic acid)-co-[(glycolic acid)-alt-(l -lysine)]} with sustained release of VPA. Firstly, the sustained release of VPA in this conduit was examined by high-performance liquid chromatography. Then Schwann cells were treated with the conduit extracts. The cell metabolic activity and proliferation were assayed by 3-[4,5-dimethyl-2-thiazolyl]-2,5-diphenyl-2-tetrazolium bromide and bromodeoxyuridine staining. A 10-mm segment of rat sciatic nerve was resected and then repaired, respectively, using the VPA conduit (Group A), the PDLLA conduit (Group B), or the autografts (Group C). Nerve conduction velocities (NCVs), compound muscle action potentials (CMAPs), and histological staining were assayed following the surgery. The cell metabolic activity and proliferation were significantly increased (p < .05) by the extracts from VPA-conduit extract compared to others. NCVs and CMAPs were significantly higher in Groups A and C than Group B (p < .05). The nerve density of Groups A and C was higher than Group B. There was no significant difference between Groups A and C. Taken together, this study suggested the sustained-release VPA conduit promoted peripheral nerve regeneration that was comparable to the autografts. It holds potential for future use in nerve regeneration.     

Drug-delivering nerve conduit improves regeneration in a critical-sized gap

Autologous nerve grafts are the current “gold standard” for repairing large nerve gaps. However, they cause morbidity at the donor nerve site and only a limited amount of nerve can be harvested. Nerve conduits are a promising alternative to autografts and can act as guidance cues for the regenerating axons, without the need to harvest donor nerve. Separately, it has been shown that localized delivery of GDNF can enhance axon growth and motor recovery. FK506, an FDA approved small molecule, has also been shown to enhance peripheral nerve regeneration. This paper describes the design of a novel hole-based drug delivery apparatus integrated with a polytetrafluoroethylene (PTFE) nerve conduit for controlled local delivery of a protein such as GDNF or a small molecule such as FK506. The PTFE devices were tested in a diffusion chamber, and the bioactivity of the released media was evaluated by measuring neurite growth of dorsal root ganglions (DRGs) exposed to the released drugs. The drug delivering nerve guide was able to release bioactive concentrations of FK506 or GDNF. Following these tests, optimized drug releasing nerve conduits were implanted across 10 mm sciatic nerve gaps in a BL6 yellow fluorescent protein (YFP) mouse model, where they demonstrated significant improvement in muscle mass, compound muscle action potential, and axon myelination in vivo as compared with nerve conduits without the drug. The drug delivery nerve guide could release drug for extended periods of time and enhance axon growth in vitro and in vivo.     

Vascular tissue engineering: the next generation

It is the ultimate goal of tissue engineering: an autologous tissue engineered vascular graft (TEVG) that is immunologically compatible, nonthrombogenic, and can grow and remodel. Currently, native vessels are the preferred vascular conduit for procedures such as coronary artery bypass (CABG) or peripheral bypass surgery. However, in many cases these are damaged, have already been harvested, or are simply unusable. The use of synthetic conduits is severely limited in smaller diameter vessels due to increased incidence of thrombosis, infection, and graft failure. Current research has therefore energetically pursued the development of a TEVG that can incorporate into a patient's circulatory system, mimic the vasoreactivity and biomechanics of the native vasculature, and maintain long-term patency.     

Behavioral evaluation of regenerated rat sciatic nerve by a nanofibrous PHBV conduit filled with Schwann cells as artificial nerve graft

Abstract

The aim of this study is to develop a nanofibrous polymeric nerve conduit with Schwann cells (SCs) and to evaluate its efficiency on the promotion of functional and locomotive activities in rats. The conduits were implanted into a 30-mm gap in the sciatic nerves of the rats. Four months after surgery, the rats were monitored and evaluated by behavioral analyses such as toe out angle, toe spreading analysis, walking track analysis, extensor postural thrust, open-field analysis, swimming test and nociceptive function, four months post surgery. Four months post-operatively, the results from behavioral analyses demonstrated that in the grafted groups especially in the grafted group with SCs, the rat sciatic nerve trunk had been reconstructed with functional recovery such as walking, swimming and recovery of nociceptive function. This study proves the feasibility of artificial conduit with SCs for nerve regeneration by bridging a longer defect in the rat model.     

Development of a bioartificial nerve graft. II. Nerve regeneration in vitro

A promising alternative for the repair of peripheral nerve injuries is the bioartificial nerve graft, or BNG, comprised of a tubular conduit preseeded with Schwann cells, which are an effective substrate for enhancing nerve regeneration. The physical properties of the conduit, porosity and wall thickness, as well as the Schwann cell seeding density, were tested for their effect on axon growth using rat dorsal root ganglia. These parameters can influence the amount of nutrients and growth factors made available to the neural tissue. Results show that a greater wall thickness and lower porosities have a detrimental effect on the growth of the axons. Over a four week period, axons extended 3.2 mm for the optimum case (DeltaR = 0.82 mm, epsilon = 0.75) compared to 1.8 and 1.6 mm for a lower porosity (0.55) and a greater wall thickness (1.4 mm), respectively. A maximum in the growth rate occurs at a porosity of 75% for Schwann cell seeded conduits but not for unseeded ones. When compared to mass transfer predictions, the results suggest that, at higher porosities, more growth factors diffuse out of the conduit, while at low porosities there is competition for nutrients. Increasing the Schwann cell seeding density enhances growth but also leads to an increase in the number of axons along the length of the conduit. This is indicative of branching of the axons, which requires additional resources to maintain and can lead to painful neuroma formation. Wall thickness and porosity were found not to have any significant effect on the axon number sprouting from the dorsal root ganglia and the mean diameter (p > 0.05). Considerations need to be made, not just on the polymer used, but also on its porosity, wall thickness, and Schwann cell seeding density. These parameters can be adjusted to create a bioartificial nerve graft that provides the optimal environment for nerve growth.