利用正常腰骶神经根重建弛缓性膀胱功能的实验与临床研究
|
摘要
第一部分大鼠正常单根腰骶神经根切断动物模型的探讨
[研究目的]对大鼠的骶丛神经根结构进行解剖学研究,同时分析其对下肢各肌群的支配权重,并通过对不同的建模方法进行比较,探讨大鼠切断单根腰骶神经根的理想模型。
[研究方法]1、雄性SD大鼠10只,体重250-300g,由复旦大学动物实验中心提供,所有大鼠均采用活体处死后,咬除椎板暴露脊髓和神经根,进行解剖学的观察;2、另取SD大鼠10只,麻醉后在椎管外分别暴露出L4、L5、L6神经根,并分离出约0.5cm的一段,做刺激电极的安放位置。然后做大腿外侧纵切口,向下延伸至踝部,分别暴露股二头肌、胫前肌和小腿三头肌,将记录电极置于股二头肌肌腹,刺激电极分别置于L4、L5、L6神经根,记录复合肌肉动作电位最大波幅,同样方法分别记录小腿三头肌和胫前肌的相应数据;3、SD大鼠9只,每3只为一组,分别采用椎管外和椎管内暴露和切断神经根的方法,另取3只在椎管外暴露并切断所有L4、L5、L6神经根,以检测切断方法的可靠性。
[结果]1、对10只大鼠的骶丛分别进行解剖发现,大鼠的骶丛组成主要可以分成三种类型:(1)L4、L5为主型,L6参与一小支,共有7只,(2)L4、L5型,L6不参与,共有2只,(3)L4、L5、L6共同参与型,共有1只,三种类型中,L4均为部分参与(与人类相似,其另一分支参与腰丛的组成)。2、通过对复合肌肉动作电位波幅分析,在小腿三头肌的支配中,L5的支配比重最大,其次是L4,而L6的支配比重变异较大,但也占有明显的地位;对胫前肌的支配中,主要为L4和L5神经根,其中L5的比重略大,而L6神经根的比重很小;而在股二头肌的支配中,仍为L5的比重最大,其次为L4,L6的比重最小,但与其他两根的差异不是非常明显。2、椎管内暴露法手术难度大,易损伤脊髓及马尾,并且出血较多,大鼠死亡率高,椎管外法相对简单、损伤小,并且切断可靠。
[结论]大鼠骶丛神经根结构与人类有一定相似性,可以作为切断单根腰骶神经根对下肢功能影响的动物模型,而在椎管外暴露并切断神经根的方法是一种简单有效的方法。
第二部分大鼠正常单根腰骶神经根切断对下肢功能影响的实验研究
[研究目的]对SD大鼠切断单根正常腰骶神经根切断对下肢功能影响的动物模型进行研究,以探讨临床利用正常腰骶神经根重建脊髓损伤后弛缓性膀胱功能的可行性。
[研究方法]分别建立单根L4、L5、L6神经根切断动物模型,以不切断骶丛神经根的大鼠作为对照,术前、术后及4、8、12周后分别检测下肢神经电生理,同时在4、8、12周时对实验组和对照组分别做坐骨神经功能指数测定及行为学观察,最后在12周后将大鼠处死取材,进行肌肉湿重、组织形态学及电镜观察,以评价对下肢运动功能的影响。
[结果]4组大鼠术前及术后坐骨神经功能指数、复合肌肉动作电位等均无显著差异,说明4组大鼠术前具有一致性,并且神经根切除术后其坐骨神经段仍具有正常功能,而术后4周时,复合肌肉动作电位显示B、C两组坐骨神经功能显著低于A、D两组,主要表现在平均潜伏期的延长,而术后8周和12周时,其平均潜伏期逐渐恢复,4组无显著性差异;坐骨神经功能指数在术前、术后4周、术后8周、术后12周时A组对照组均大于其余3组,但其差异并不显著,并且其差异随着时间的延长而逐渐变小,由于坐骨神经指数是坐骨神经和下肢运动功能的重要参考,因此该结果提示,在各组神经根切断后,坐骨神经和下肢功能受到一定影响,但影响并不显著,而且随着时间的延长,影响也逐渐变小;而术后肌肉湿重显示各实验组肌肉均小于对照组,但差异也并不显著,仅有个别样本出现显著下降;术后组织形态学及结缔组织百分比、电镜检测均发现,从总体而言,A-D各组均无显著性差异,仅有个别实验组样本肌细胞出现明显退变。
[结论]在SD大鼠实验中,我们认为,利用单根正常骶丛神经根作为动力神经进行移位修复手术是安全可行的,该方法可以用于膀胱功能重建手术,同时,该动力神经也可以用于下肢其他功能的重建。鉴于SD大鼠和人类存在一定的差异性,该方法用于临床时,需在病人完全知情同意的情况下谨慎进行。
第三部分利用正常单根腰骶神经根重建弛缓性膀胱的临床研究
[研究目的]在动物实验成功的基础上,研究对临床脊髓损伤后呈弛缓性膀胱而下肢运动功能正常的患者,利用其支配下肢运动功能的正常腰骶神经根,建立体神经—脊髓中枢—膀胱人工反射弧来重建膀胱功能。
[研究方法]对29例脊髓损伤后下肢运动功能存在而膀胱功能障碍的病人,利用其支配正常运动功能的腰骶神经根,通过椎管内神经根切断吻合的方法,并对比手术前后肌力、肌电图、排尿情况、尿流动力学等进行对比研究。
[结果]除1例病人由于椎板外粘连严重,同时咬除椎板后出血较多,仅做椎板减压和硬膜外松解外,其余28例均成功进行膀胱人工反射弧重建手术。术后第二天所有病人均检查下肢相关肌力,发现仅6例病人相关肌力轻微下降约半级,其余均无明显变化,而术后两周检查肌电图显示,3例使用L4作为动力神经的患者手术后肌电图腓总神经波幅都有降低;1例使用L5作为动力神经的患者术后肌电图也显示腓总神经波幅降低;而24例使用S1作为动力神经的患者中,有6例患者其胫神经波幅较术前下降,3例患者其胫神经、腓总神经波幅均下降,其余15例患者均表现为手术侧腓总神经最大波幅下降,另外一例仅行椎板减压及马尾神经松解病人肌电图无明显改变。术后长期排尿情况随访,20例病人排尿情况得到不同程度改善,排尿量明显增加,而残余尿均可控制在50ml以内,在其他9例患者中,除1例失访之外,在改善不明显的病人中,有3例病人虽然仍用腹压排尿,但感觉排尿所需力量较术前减小,不过残余尿都大于100ml,所以其效果仍属于较差,另外3例病人自觉排尿情况没有任何改善,因此对治疗效果并不满意。还有2例病人由于随访时间过短,排尿情况尚无改善。
[结论]总体来看,利用单根支配下肢运动功能的正常腰骶神经根重建弛缓性膀胱功能,不仅是安全的,而且疗效也是比较好的。
第四部分腰骶神经根间代偿机制的初步研究:猕猴下肢肌肉神经根支配分布规律的实验研究
[研究目的]研究猕猴腰骶丛神经根对下肢肌肉支配的分布规律,从而探讨其神经根间的代偿机制,以作为人类神经根间代偿机制的参考。
[研究方法]通过对猕猴腰骶丛神经根进行解剖学研究,并分别对下肢各个主要肌肉相对每个神经根的复合肌肉动作电位波幅进行检测,从而分析腰骶神经根对每块肌肉的支配权重。
[结果]刺激腰骶神经根可于其支配的肌肉记录到复合肌肉动作电位,其波幅和时限反映的是所测的神经纤维数量和同步兴奋的程度,它与兴奋的神经纤维数量成正比,通过波幅的大小,可大致估计出执行功能的神经和肌肉的总量。因此通过本文所得到的数据可以分析猕猴L3-S1神经根对下肢肌肉支配的分布规律,从数据中我们可以看出,在下肢的几组肌肉都有显著的神经根重点支配,股四头肌以L4为首,股二头肌以L6为首,腓肠肌以L7为首,胫前肌以L5为首,趾长伸肌以L6为首,这些神经根在相应的肌肉中其波幅居于最高,但其相邻的神经根也有一定的支配比重,而间隔一个神经根的话,其虽然也有支配,但支配比重会明显下降。
[结论]猕猴腰丛是由L3-L5组成,而骶丛是由L5-S1组成。猕猴下肢每组肌肉均有显著的重点神经根支配,而其相邻神经根都有一定的支配比重,因此通常每块肌肉都有三根以上的神经根参与支配,因此如果一根腰骶神经根被切断,对其产生代偿作用的主要是与其相邻的神经根,而相隔神经根的代偿作用很小,其代偿机制可能主要是神经根间交互支配产生的。
Investigation of severing one nerve root of the sacral plexus in animal model:an experimental study in rats
Purpose:To observe the structure of sacral plexus in SD rats,and analysis weight of every nerve root dominating to the muscle of lower limbs.Then compare different methods of modeling, and find which one is better.
Methods:1.Ten SD rats, weighing from 250g to 300g,which were provided by animal experiment center of Fu Dan university.All of rats were dissected after put to death.2. Ten SD rats,being exposed the L4,L5 and L6 nerve root to pace the stimulating electrode,then the recording electrodes were located in the triceps surae muscle, anterior tibialis muscle and biceps femoris after being exposed to record the compound muscle action potentials.3. Nine SD rats,being severed the nerve root of sacral plexus in the spinal canal,or out the spinal canal.Then study which method was better and dependable.
Results:1.Three types of sacral plexus were found:(1)mainly composed of L4 and L5,with a little branch of L6.(2)Composed of L4 and L5.(3)composed of L4,L5 and L6.2. Analysis the CMAP, the triceps surae muscle was chiefly dominated by L5,then L4 and L6, anterior tibialis muscle was chiefly dominated by L4 and L5,with little dominated by L6, biceps femoris was chiefly dominated by L5,then L4 and L6.3. Severed the nerve root of sacral plexus out the spinal canal was a batter method.
Conclusion:Consider the similarity between the sacral plexus of rat and of human, the model of rat was feasible to study the influence of severed one nerve root of sacral plexus, and to expose and sever the nerve root, the method of operating out the spinal canal was a batter method.
The effect on lower extremity function of severing one nerve root of the sacral plexus: an experimental study in rats
Purpose:Recovery of bladder function is important in patients with conus medullaris injury. The effects of severing the S1 nerve root, to recover atonic bladder function, on motor function of the lower extremities require investigation.
Methods:Forty adult male Sprague-Dawley (SD) rats were randomized into groups of 10 rats by severing the right L4, L5 and L6 nerve root, respectively, (groups B, C and D; control group A). Pre-and 4-week,8-week and 12-week postoperative electromyograms (EMGs) of the lower extremities were compared. Sciatic Functional Index (SFI), muscle weight, histological examination, and ultrastructure of the target muscle and motor end plate (MEP) were examined.
Results:Relative to controls, effects were apparent in EMG at four weeks after L4 or L5, but not L6, was severed, and declined at 8 and 12 weeks. In SFI, there was a small decrease at 4 weeks, but the change was not significant or persistent. Similar results were found for muscle wet weight, except for several samples. By electron microscopy, histological examination and analysis of fiber components, we also observed significant degeneration in only a few muscle samples.
Conclusion:Severance of one of the normal sacral plexus nerve roots in SD rats was feasible and did not markedly impact on lower limb motor function.
Severing normal lumb and sacral anterior nerve root to reconstruct the atonic bladder function:clinical observation
Purpose:At the base of animal experiment,to reconstruct function of bladder for patient with bladder dysfunction and normal function of the lower extremities by using normal lumb and sacral nerve root.
Methods:In 29 patients with bladder dysfunction due to spinal cord injury and preservation of motor function of the lower extremities, the central end of normal lumb and sacral nerve root on the unaffected spinal segment was anastomosed with the peripheral end of S2 (or S3) anterior nerve root that dominates the bladder to establish a new artificial bladder reflex arc in an attempt to recover the bladder function. Differences in motor function and electromyogram of the involved parts of the lower extremities were observed. After the operation the bladder funtion was followed up,which include rinary output, residual urine, urinary tract infection and life quality.
Results:Six patients who had normal lumb and sacral nerve root severed subjectively reported a sensation of slightly decreased strength of the lower leg after operation. Postoperative physical examination showed that ankle plantar flexor muscle strength(MRC scale) decreased by 0.5 degree. Electromyogram of lower limb showed that sixteen amplitudes of common peroneal nerve, six amplitudes of tibial nerve, three mplitudes of common peroneal nerve and tibial nerve were decreased. Twenty patients had improvements of bladder functions with more volume of micturition and less residual urine. Other nine patients had no obviously improvement.
Conclusion:Severing normal lumb and sacral anterior root can reconstruct the atonic bladder function safely and efficiently.
Primary study of the mechanism of compensation between lumbar or sacral roots:an experiment in macaques to study the nerve domination rule of muscles in lower limbs
Purpose:To observe the structure of sacral plexus in macaque, and analysis weight of every nerve root dominating to the muscle of lower limbs.Then investigate mechanism of compensation between the nerve roots.
Methods:the macaques were dissected to observe the structure of sacral plexus, and then four macaques were exposed the L3,L4,L5,L6,L7 and S1 nerve root to pace the stimulating electrode, then the recording electrodes were located in the quadriceps femoris muscle, biceps femoris, triceps surae muscle, anterior tibialis muscle and long extensor muscle of toes to record the compound muscle action potentials
Results:Analysis weight of every nerve root dominating to the muscle of lower limbs by CMAP. We found that each muscle was dominated by a intensive nerve root. The quadriceps femoris muscle was dominated mainly by L4. The biceps femoris was dominated mainly by L6. The triceps surae muscle was dominated mainly by L7. The anterior tibialis muscle was dominated mainly by L5. The long extensor muscle of toes was dominated mainly by L6. However the nerve roots neighboring also participate in the domination.
Conclusion:lumbar plexus of macaques were composed by L3-L5,and the sacral poexus were composed by L5-L7. Each muscle was dominated by a intensive nerve root. But the nerve roots neighboring also participate in the domination, the number of which were two and more.
[研究目的]对大鼠的骶丛神经根结构进行解剖学研究,同时分析其对下肢各肌群的支配权重,并通过对不同的建模方法进行比较,探讨大鼠切断单根腰骶神经根的理想模型。
[研究方法]1、雄性SD大鼠10只,体重250-300g,由复旦大学动物实验中心提供,所有大鼠均采用活体处死后,咬除椎板暴露脊髓和神经根,进行解剖学的观察;2、另取SD大鼠10只,麻醉后在椎管外分别暴露出L4、L5、L6神经根,并分离出约0.5cm的一段,做刺激电极的安放位置。然后做大腿外侧纵切口,向下延伸至踝部,分别暴露股二头肌、胫前肌和小腿三头肌,将记录电极置于股二头肌肌腹,刺激电极分别置于L4、L5、L6神经根,记录复合肌肉动作电位最大波幅,同样方法分别记录小腿三头肌和胫前肌的相应数据;3、SD大鼠9只,每3只为一组,分别采用椎管外和椎管内暴露和切断神经根的方法,另取3只在椎管外暴露并切断所有L4、L5、L6神经根,以检测切断方法的可靠性。
[结果]1、对10只大鼠的骶丛分别进行解剖发现,大鼠的骶丛组成主要可以分成三种类型:(1)L4、L5为主型,L6参与一小支,共有7只,(2)L4、L5型,L6不参与,共有2只,(3)L4、L5、L6共同参与型,共有1只,三种类型中,L4均为部分参与(与人类相似,其另一分支参与腰丛的组成)。2、通过对复合肌肉动作电位波幅分析,在小腿三头肌的支配中,L5的支配比重最大,其次是L4,而L6的支配比重变异较大,但也占有明显的地位;对胫前肌的支配中,主要为L4和L5神经根,其中L5的比重略大,而L6神经根的比重很小;而在股二头肌的支配中,仍为L5的比重最大,其次为L4,L6的比重最小,但与其他两根的差异不是非常明显。2、椎管内暴露法手术难度大,易损伤脊髓及马尾,并且出血较多,大鼠死亡率高,椎管外法相对简单、损伤小,并且切断可靠。
[结论]大鼠骶丛神经根结构与人类有一定相似性,可以作为切断单根腰骶神经根对下肢功能影响的动物模型,而在椎管外暴露并切断神经根的方法是一种简单有效的方法。
第二部分大鼠正常单根腰骶神经根切断对下肢功能影响的实验研究
[研究目的]对SD大鼠切断单根正常腰骶神经根切断对下肢功能影响的动物模型进行研究,以探讨临床利用正常腰骶神经根重建脊髓损伤后弛缓性膀胱功能的可行性。
[研究方法]分别建立单根L4、L5、L6神经根切断动物模型,以不切断骶丛神经根的大鼠作为对照,术前、术后及4、8、12周后分别检测下肢神经电生理,同时在4、8、12周时对实验组和对照组分别做坐骨神经功能指数测定及行为学观察,最后在12周后将大鼠处死取材,进行肌肉湿重、组织形态学及电镜观察,以评价对下肢运动功能的影响。
[结果]4组大鼠术前及术后坐骨神经功能指数、复合肌肉动作电位等均无显著差异,说明4组大鼠术前具有一致性,并且神经根切除术后其坐骨神经段仍具有正常功能,而术后4周时,复合肌肉动作电位显示B、C两组坐骨神经功能显著低于A、D两组,主要表现在平均潜伏期的延长,而术后8周和12周时,其平均潜伏期逐渐恢复,4组无显著性差异;坐骨神经功能指数在术前、术后4周、术后8周、术后12周时A组对照组均大于其余3组,但其差异并不显著,并且其差异随着时间的延长而逐渐变小,由于坐骨神经指数是坐骨神经和下肢运动功能的重要参考,因此该结果提示,在各组神经根切断后,坐骨神经和下肢功能受到一定影响,但影响并不显著,而且随着时间的延长,影响也逐渐变小;而术后肌肉湿重显示各实验组肌肉均小于对照组,但差异也并不显著,仅有个别样本出现显著下降;术后组织形态学及结缔组织百分比、电镜检测均发现,从总体而言,A-D各组均无显著性差异,仅有个别实验组样本肌细胞出现明显退变。
[结论]在SD大鼠实验中,我们认为,利用单根正常骶丛神经根作为动力神经进行移位修复手术是安全可行的,该方法可以用于膀胱功能重建手术,同时,该动力神经也可以用于下肢其他功能的重建。鉴于SD大鼠和人类存在一定的差异性,该方法用于临床时,需在病人完全知情同意的情况下谨慎进行。
第三部分利用正常单根腰骶神经根重建弛缓性膀胱的临床研究
[研究目的]在动物实验成功的基础上,研究对临床脊髓损伤后呈弛缓性膀胱而下肢运动功能正常的患者,利用其支配下肢运动功能的正常腰骶神经根,建立体神经—脊髓中枢—膀胱人工反射弧来重建膀胱功能。
[研究方法]对29例脊髓损伤后下肢运动功能存在而膀胱功能障碍的病人,利用其支配正常运动功能的腰骶神经根,通过椎管内神经根切断吻合的方法,并对比手术前后肌力、肌电图、排尿情况、尿流动力学等进行对比研究。
[结果]除1例病人由于椎板外粘连严重,同时咬除椎板后出血较多,仅做椎板减压和硬膜外松解外,其余28例均成功进行膀胱人工反射弧重建手术。术后第二天所有病人均检查下肢相关肌力,发现仅6例病人相关肌力轻微下降约半级,其余均无明显变化,而术后两周检查肌电图显示,3例使用L4作为动力神经的患者手术后肌电图腓总神经波幅都有降低;1例使用L5作为动力神经的患者术后肌电图也显示腓总神经波幅降低;而24例使用S1作为动力神经的患者中,有6例患者其胫神经波幅较术前下降,3例患者其胫神经、腓总神经波幅均下降,其余15例患者均表现为手术侧腓总神经最大波幅下降,另外一例仅行椎板减压及马尾神经松解病人肌电图无明显改变。术后长期排尿情况随访,20例病人排尿情况得到不同程度改善,排尿量明显增加,而残余尿均可控制在50ml以内,在其他9例患者中,除1例失访之外,在改善不明显的病人中,有3例病人虽然仍用腹压排尿,但感觉排尿所需力量较术前减小,不过残余尿都大于100ml,所以其效果仍属于较差,另外3例病人自觉排尿情况没有任何改善,因此对治疗效果并不满意。还有2例病人由于随访时间过短,排尿情况尚无改善。
[结论]总体来看,利用单根支配下肢运动功能的正常腰骶神经根重建弛缓性膀胱功能,不仅是安全的,而且疗效也是比较好的。
第四部分腰骶神经根间代偿机制的初步研究:猕猴下肢肌肉神经根支配分布规律的实验研究
[研究目的]研究猕猴腰骶丛神经根对下肢肌肉支配的分布规律,从而探讨其神经根间的代偿机制,以作为人类神经根间代偿机制的参考。
[研究方法]通过对猕猴腰骶丛神经根进行解剖学研究,并分别对下肢各个主要肌肉相对每个神经根的复合肌肉动作电位波幅进行检测,从而分析腰骶神经根对每块肌肉的支配权重。
[结果]刺激腰骶神经根可于其支配的肌肉记录到复合肌肉动作电位,其波幅和时限反映的是所测的神经纤维数量和同步兴奋的程度,它与兴奋的神经纤维数量成正比,通过波幅的大小,可大致估计出执行功能的神经和肌肉的总量。因此通过本文所得到的数据可以分析猕猴L3-S1神经根对下肢肌肉支配的分布规律,从数据中我们可以看出,在下肢的几组肌肉都有显著的神经根重点支配,股四头肌以L4为首,股二头肌以L6为首,腓肠肌以L7为首,胫前肌以L5为首,趾长伸肌以L6为首,这些神经根在相应的肌肉中其波幅居于最高,但其相邻的神经根也有一定的支配比重,而间隔一个神经根的话,其虽然也有支配,但支配比重会明显下降。
[结论]猕猴腰丛是由L3-L5组成,而骶丛是由L5-S1组成。猕猴下肢每组肌肉均有显著的重点神经根支配,而其相邻神经根都有一定的支配比重,因此通常每块肌肉都有三根以上的神经根参与支配,因此如果一根腰骶神经根被切断,对其产生代偿作用的主要是与其相邻的神经根,而相隔神经根的代偿作用很小,其代偿机制可能主要是神经根间交互支配产生的。
Investigation of severing one nerve root of the sacral plexus in animal model:an experimental study in rats
Purpose:To observe the structure of sacral plexus in SD rats,and analysis weight of every nerve root dominating to the muscle of lower limbs.Then compare different methods of modeling, and find which one is better.
Methods:1.Ten SD rats, weighing from 250g to 300g,which were provided by animal experiment center of Fu Dan university.All of rats were dissected after put to death.2. Ten SD rats,being exposed the L4,L5 and L6 nerve root to pace the stimulating electrode,then the recording electrodes were located in the triceps surae muscle, anterior tibialis muscle and biceps femoris after being exposed to record the compound muscle action potentials.3. Nine SD rats,being severed the nerve root of sacral plexus in the spinal canal,or out the spinal canal.Then study which method was better and dependable.
Results:1.Three types of sacral plexus were found:(1)mainly composed of L4 and L5,with a little branch of L6.(2)Composed of L4 and L5.(3)composed of L4,L5 and L6.2. Analysis the CMAP, the triceps surae muscle was chiefly dominated by L5,then L4 and L6, anterior tibialis muscle was chiefly dominated by L4 and L5,with little dominated by L6, biceps femoris was chiefly dominated by L5,then L4 and L6.3. Severed the nerve root of sacral plexus out the spinal canal was a batter method.
Conclusion:Consider the similarity between the sacral plexus of rat and of human, the model of rat was feasible to study the influence of severed one nerve root of sacral plexus, and to expose and sever the nerve root, the method of operating out the spinal canal was a batter method.
The effect on lower extremity function of severing one nerve root of the sacral plexus: an experimental study in rats
Purpose:Recovery of bladder function is important in patients with conus medullaris injury. The effects of severing the S1 nerve root, to recover atonic bladder function, on motor function of the lower extremities require investigation.
Methods:Forty adult male Sprague-Dawley (SD) rats were randomized into groups of 10 rats by severing the right L4, L5 and L6 nerve root, respectively, (groups B, C and D; control group A). Pre-and 4-week,8-week and 12-week postoperative electromyograms (EMGs) of the lower extremities were compared. Sciatic Functional Index (SFI), muscle weight, histological examination, and ultrastructure of the target muscle and motor end plate (MEP) were examined.
Results:Relative to controls, effects were apparent in EMG at four weeks after L4 or L5, but not L6, was severed, and declined at 8 and 12 weeks. In SFI, there was a small decrease at 4 weeks, but the change was not significant or persistent. Similar results were found for muscle wet weight, except for several samples. By electron microscopy, histological examination and analysis of fiber components, we also observed significant degeneration in only a few muscle samples.
Conclusion:Severance of one of the normal sacral plexus nerve roots in SD rats was feasible and did not markedly impact on lower limb motor function.
Severing normal lumb and sacral anterior nerve root to reconstruct the atonic bladder function:clinical observation
Purpose:At the base of animal experiment,to reconstruct function of bladder for patient with bladder dysfunction and normal function of the lower extremities by using normal lumb and sacral nerve root.
Methods:In 29 patients with bladder dysfunction due to spinal cord injury and preservation of motor function of the lower extremities, the central end of normal lumb and sacral nerve root on the unaffected spinal segment was anastomosed with the peripheral end of S2 (or S3) anterior nerve root that dominates the bladder to establish a new artificial bladder reflex arc in an attempt to recover the bladder function. Differences in motor function and electromyogram of the involved parts of the lower extremities were observed. After the operation the bladder funtion was followed up,which include rinary output, residual urine, urinary tract infection and life quality.
Results:Six patients who had normal lumb and sacral nerve root severed subjectively reported a sensation of slightly decreased strength of the lower leg after operation. Postoperative physical examination showed that ankle plantar flexor muscle strength(MRC scale) decreased by 0.5 degree. Electromyogram of lower limb showed that sixteen amplitudes of common peroneal nerve, six amplitudes of tibial nerve, three mplitudes of common peroneal nerve and tibial nerve were decreased. Twenty patients had improvements of bladder functions with more volume of micturition and less residual urine. Other nine patients had no obviously improvement.
Conclusion:Severing normal lumb and sacral anterior root can reconstruct the atonic bladder function safely and efficiently.
Primary study of the mechanism of compensation between lumbar or sacral roots:an experiment in macaques to study the nerve domination rule of muscles in lower limbs
Purpose:To observe the structure of sacral plexus in macaque, and analysis weight of every nerve root dominating to the muscle of lower limbs.Then investigate mechanism of compensation between the nerve roots.
Methods:the macaques were dissected to observe the structure of sacral plexus, and then four macaques were exposed the L3,L4,L5,L6,L7 and S1 nerve root to pace the stimulating electrode, then the recording electrodes were located in the quadriceps femoris muscle, biceps femoris, triceps surae muscle, anterior tibialis muscle and long extensor muscle of toes to record the compound muscle action potentials
Results:Analysis weight of every nerve root dominating to the muscle of lower limbs by CMAP. We found that each muscle was dominated by a intensive nerve root. The quadriceps femoris muscle was dominated mainly by L4. The biceps femoris was dominated mainly by L6. The triceps surae muscle was dominated mainly by L7. The anterior tibialis muscle was dominated mainly by L5. The long extensor muscle of toes was dominated mainly by L6. However the nerve roots neighboring also participate in the domination.
Conclusion:lumbar plexus of macaques were composed by L3-L5,and the sacral poexus were composed by L5-L7. Each muscle was dominated by a intensive nerve root. But the nerve roots neighboring also participate in the domination, the number of which were two and more.
引文
1、May L, Day R, Warren S. Perceptions of patient education in spinal cord injury rehabilitation. Disabil Rehabil,2006,28(17):1041-1049.
2、黎鳌,盛志勇,王正国.现代战伤外科学.北京:人民军医出版社,1998:856.
3、郭友仁.唐山大地震截瘫15年康复工作回顾.伤残医学杂志,1994,2(4):282-284.
4、Tanagho EA, Schmidt RA. Electrical stimulation in the clinical management of the neurogenic bladder. J Urol 1988:140:1331-1339
5、Selzman AA, Hampel N. Urologic complications of spinal cord injury. Urol Clin North Am 1993:20:453-464
6. Brindley GS, Polkey CE, Rushton DN, Cardozo L. Sacral anterior root stimulators for bladder control in paraplegia:the first 50 cases. J Neurol Neurosurg Psychiatry 1986:49:1104-1114
7. Zheng XY, Hou CL, Zhong HB, Xu RS, Chen AM, Xu Z, Wang JH. Reconstructed bladder innervation below the level of spinal cord injury:the knee-tendon to bladder artificial reflex arc. J Spinal Cord Med.2009;32(1):79-85
8. Lin H, Hou C, Zhen X, Xu Z. Clinical study of reconstructed bladder innervation below the level of spinal cord injury to produce urination by Achilles tendon-to-bladder reflex contractions. J Neurosurg Spine.2009 May;10(5):452-7.
9.徐瑞生,侯春林,张世民,等.“膝腱-脊髓-膀胱”反射弧的形态学观察.中国脊柱脊髓杂志,2002,12(4):273-276.
10.徐瑞生,侯春林,张世民,等.“膝腱-脊髓-膀胱”反射弧重建膀胱功能的解剖与临床.中国矫形外科杂志,2002,10(9):869-871.
11.侯春林,王诗波,陈爱民,等.利用跟腱反射建立人工膀胱反射弧的临床研究.解放军医学杂志,2003,28(8):668-669.
12. Zheng XY, Hou CL, Zhong HB, Xu RS, Chen AM, Xu Z, Wang JH. Reconstructed bladder innervation below the level of spinal cord injury:the knee-tendon to bladder artificial reflex arc. J Spinal Cord Med.2009;32(1):79-85
13. Lin H, Hou C, Zhen X, Xu Z. Clinical study of reconstructed bladder innervation below the level of spinal cord injury to produce urination by Achilles tendon-to-bladder reflex contractions. J Neurosurg Spine.2009 May; 10(5):452-7.
14.赵定麟.现代脊柱外科学.上海:世界图书出版公司,2006:201.
15. Chuang DC,Chang PL, Cheng SY. Root reconstruction for bladder reinnervation:an experimental study in rats. Microsurgery.1991,12(4):237-245.
16. Xiao CG, Godec CJ. A possible new reflex pathway for micturition after spinal cord injury. Paraplegia,1994,32(5):300-307.
17.侯春林,衷鸿宾,刘明轩.脊髓损伤后膀胱人工反射弧建立的实验研究.中国修复重建外科杂志.2000,14(1):10-13.
18. Sievert KD, Xiao CG, Hennenlotter J, et al. Voluntary micturition after intradural nerve anastomosis. Urologe A,2005,44(7):756-761.
19.侯春林,钟贵彬,谢庆平,等.人工反射弧重建脊髓损伤后弛缓性膀胱排尿功能的临床初步报告.中华显微外科杂志,2006,29(2):92-94.
20. X Zheng, C Hou, A Chen, J Li, Z Xu and J Wang. Optimal timing of operation for repairing atonic bladder after medullary cone injury:an experimental study in rats. Spinal Cord. Houndsmills:Aug 2008. Vol.46, Iss.8; p.574-581.
21. Gu Y, Xu J, Chen L, Wang H, Hu S. Long term outcome of contralateral C7 transfer: a report of 32 cases. Chin Med J (Engl).2002;115(6):866-8.
22. Xu L, Gu Y, Xu J, Lin S, Chen L, Lu J. Contralateral C7 transfer via the prespinal and retropharyngeal route to repair brachial plexus root avulsion:a preliminary report. Neurosurgery.2008:63(3):553-558.
23. Fumio A, Butler M, Blomberg H, et al. Variation in rat sciatic nerve anatomy: implications for a rat model of neuropathic pain. J Peripher Nerv Syst,2000,5:19-21.
1、Baydin A, Cokluk C, Aydin K. A New Minimally Invasive Experimental Spinal Cord Injury Model in Rabbits. Minim Invasive Neurosurg,2007,50(3) 170-172.
2、Lim JH, Jung CS, Byeon YE, et al. Establishment of a canine spinal cord injury model induced by epidural balloon compression. J Vet Sci,2007,8(1):89-94.
3、Kasahara K, Nakagawa T, Kubota T. Neuronal loss and expression of neurotrophic factors in a model of rat chronic compressive spinal cord injury. Spine,2006,31(18):2059-2066.
4、Lee M, Lee ES, Kim YS, Choi BH, et al. Ischemic injury-specific gene expression in the rat spinal cord injury model using hypoxia-inducible system. Spine,2005,30(24):2729-2734.
5、Liu L, Chi LT, Tu ZQ, et al. Observation and establishment of an animal model of tractive spinal cord injury in rats. Chin J Traumatol,2004,7(6):372-377.
6、徐建广 顾玉东.大鼠坐骨神经显微解剖及其意义[J].上海医学,1999,22(3):154-156.
7、Fumio A, Butler M, Blomberg H, et al. Variation in rat sciatic nerve anatomy: implications for a rat model of neuropathic pain. J Peripher Nerv Syst,2000,5:19-21.
8、曹学成.大鼠坐骨神经的解剖学研究[J].中国实验动物学杂志,2002,12(4):213-214.
9、江曦 陈爱民 张志凌 侯春林 鹿楠.SD 大鼠坐骨神经结构及其支配肌群的探讨[J].生物骨科材料与临床研究,2009,6(4):5-7.
10、卢能祖,曾庆杏,李曾宴,等.实用肌电图学[M].北京:人民卫生出版社,2000:194-206,420-7.
11、顾玉东,沈丽英,沈尊理,等.臂丛神经根支配功能的电生理研究中华外科杂志,1996,34(1):40-3.
12、徐峰,傅中国,张殿英,等.腰神经根与其支配肌群的电生理定位实验.中国临床康复杂志.2006,7(26):16-18.
1、Bain J, Mackinnon S, Hunter DA. Functional evaluation of complete sciatic, peroneal, and posterior tibial nerve lesions in the rat[J]. Plast Reconstr Surg,1989,83(1):129-138.
2、Cortez R, Levi AD. Acute spinal cord injury. Curr Treat Options Neurol,2007,9(2):115-125.
3、Benevento BT, Sipski ML. Neurogenic bladder, neurogenic bowel, and sexual dysfunction in people with spinal cord injury. Phys Ther, 2002,82(6):601-612.
4、Patrick GM, Mahony JF, Disney AP. The prognosis for end-stage renal failure in spinal cord injury and spina bifida-Australia and New Zealand, 1970-1991. Aust N Z J Med,1994,24(1):36-40.
5、Frankel HL, Coll JR, Charlifue SW, et al. Long-term survival in spinal cord injury:a fifty year investigation. Spinal Cord,1998,36(4): 266-274.
6、Samson G, Cardenas DD. Neurogenic bladder in spinal cord injury.Phys Med Rehabil Clin N Am,2007,18(2):255-274
7、侯春林.脊髓损伤后膀胱功能重建.解放军医学杂志,2003,28(8):663-665.
8、X Zheng, C Hou, A Chen, J Li, Z Xu and J Wang. Optimal timing of operation for repairing atonic bladder after medullary cone injury:an experimental study in rats. Spinal Cord. Houndsmills:Aug 2008. Vol. 46, Iss.8; p.574-581.
9、王金武,侯春林,卢宁,等.利用腹壁反射重建膀胱反射弧的远期功能性研究.中华显微外科杂志,2002,25(4):280-284.
10、Haodong Lin,Chunlin Hou, Aimin Chen, Zhen Xu.Innervation of Reconstructed Bladder Above the Level of Spinal Cord Injury or Inducing Micturition by Contractions of the Abdomen-to-Bladder Reflex Arc. Neurosurgery,2010,28(5).
11、钟贵彬,侯春林,王诗波,等.建立人工膀胱反射弧治疗脊髓损伤后弛缓性膀胱的实验研究.中国修复重建外科杂志,2006,20(8):812-815.
12、Lin H, Hou C, Zhong G, Xie Q, and Wang S. Reconstruction of reflex pathways to the atonic bladder after conus medullaris injury: preliminary clinical results. Microsurg 2008:229-435.
13、侯春林,钟贵彬,谢庆平,等.人工反射弧重建脊髓损伤后弛缓性膀胱排尿功能的临床初步报告.中华显微外科杂志,2006,29(2):92-94.
14、Gu Y, Xu J, Chen L, Wang H, Hu S. Long term outcome of contralateral C7 transfer:a report of 32 cases. Chin Med J (Engl). 2002;115(6):866-8.
15、Xu L, Gu Y, Xu J, Lin S, Chen L, Lu J. Contralateral C7 transfer via the prespinal and retropharyngeal route to repair brachial plexus root avulsion:a preliminary report. Neurosurgery.2008;63(3):553-558.
16、杨安峰,王平.大鼠的解剖和组织.北京:科学出版社,1985:177-180.
1. Bain J, Mackinnon S, Hunter DA. Functional evaluation of complete sciatic, peroneal, and posteriortibial nerve lesions in the rat[J]. Plast Reconstr Surg,1989,83(1):129-138.
2. Cortez R, Levi AD. Acute spinal cord injury. Curr Treat Options Neurol,2007,9(2):115-125.
3. Benevento BT, Sipski ML. Neurogenic bladder, neurogenic bowel, and sexual dysfunction in people with spinal cord injury. Phys Ther, 2002,82(6):601-612.
4. Patrick GM, Mahony JF, Disney AP. The prognosis for end-stage renal failure in spinal cord injury and spina bifida-Australia and New Zealand,1970-1991. Aust N Z J Med,1994,24(1):36-40.
5. Frankel HL, Coll JR, Charlifue SW, et al. Long-term survival in spinal cord injury:a fifty year investigation. Spinal Cord,1998,36(4): 266-274.
6. Samson G, Cardenas DD. Neurogenic bladder in spinal cord injury.Phys Med Rehabil Clin N Am,2007,18(2):255-274
7.侯春林.脊髓损伤后膀胱功能重建.解放军医学杂志,2003,28(8):663-665.
8. X Zheng, C Hou, A Chen, J Li, Z Xu and J Wang. Optimal timing of operation for repairing atonic bladder after medullary cone injury:an experimental study in rats. Spinal Cord. Houndsmills:Aug 2008. Vol. 46, Iss.8; p.574-581.
9.王金武,侯春林,卢宁,等.利用腹壁反射重建膀胱反射弧的远期功能性研究.中华显微外科杂志,2002,25(4):280-284.
10.Haodong Lin,Chunlin Hou, Aimin Chen, Zhen Xu.Innervation of Reconstructed Bladder Above the Level of Spinal Cord Injury or Inducing Micturition by Contractions of the Abdomen-to-Bladder Reflex Arc. Neurosurgery,2010,28(5).
11.钟贵彬,侯春林,王诗波,等.建立人工膀胱反射弧治疗脊髓损伤后弛缓性膀胱的实验研究.中国修复重建外科杂志,2006,20(8):812-815.
12. Lin H, Hou C, Zhong G, Xie Q, and Wang S. Reconstruction of reflex pathways to the atonic bladder after conus medullaris injury: preliminary clinical results. Microsurg 2008:229-435.
13.侯春林,钟贵彬,谢庆平,等.人工反射弧重建脊髓损伤后弛缓性膀胱排尿功能的临床初步报告.中华显微外科杂志,2006,29(2):92-94.
14.Gu Y, Xu J, Chen L, Wang H, Hu S. Long term outcome of contralateral C7 transfer:a report of 32 cases. Chin Med J (Engl). 2002;115(6):866-8.
15.Xu L, Gu Y, Xu J, Lin S, Chen L, Lu J. Contralateral C7 transfer via the prespinal and retropharyngeal route to repair brachial plexus root avulsion:a preliminary report. Neurosurgery.2008;63(3):553-558.
16.杨安峰,王平.大鼠的解剖和组织.北京:科学出版社,1985:177-180.
17.胥少汀,葛宝丰,徐印坎.实用骨科学.北京:人民军医出版社,2003:603.
1、Gu YD. Functional motor innervation of brachial plexs roots. Anintra operative electrophysiological study. J Hand Surg(Br),1997,22:258-260.
2、叶智彰,彭燕章,张耀平.猕猴解剖[M].北京:科学出版社,1985.
3、钟品仁.哺乳类实验动物[M].人民卫生出版社,北京.1983.314-334.
4、魏振年.猕猴的生殖生理及科研应用[J].动物学杂志,1988,23(6):46-50.
5、Chan AW S, Chong KY, M ar t inovich C, et al. Transgenic monkeys produced by ret roviral genet ransfer intro mature oocytes[J]. Science,2001,291 (5502):309-312.
6、Wooley DP, Smith RA, Czajak S, et al. Direct demonst ration of ret roviral recombination in a rhesusmonkey[J]. Journal of Virology.1997,71:9650-9653.
7、郭常安,胡有谷,卜光颜.猕猴腰椎观察[J].上海实验动物科学,2002,(2):83-88.
8、卢能祖,曾庆杏,李曾宴,等.实用肌电图学[M].北京:人民卫生出版社,2000:194-206,420-7.
9、顾玉东,沈丽英,沈尊理等.臂丛神经根支配功能的电生理研究中华外科杂志,1996,34(1):40-3.
10、徐峰,傅中国,张殿英等.腰神经根与其支配肌群的电生理定位实验.中国临床康复杂志.2006,7(26):16-18.
1.侯春林.脊髓损伤后膀胱功能重建.北京:人民军医出版社,2006:7-11.
2.黎鳌,盛志勇,王正国.现代战伤外科学.北京:人民军医出版社,1998:856.
3.张宪郁,徐皓.骨髓间充质干细胞在脊髓损伤治疗中的应用.脊柱外科杂志,2006,4(6):373-376.
4. Benevento BT, Sipski ML. Neurogenic bladder, neurogenic bowel, and sexual dysfunction in people with spinal cord injury. Physical Therapy,2002, 82(6):601-612.
5.刘根林,李建军.脊髓损伤继发肾积水的病理生理与治疗.中国康复理论与实践,2006,12(12):1026-1028.
6.史玲美,陈洁.脊髓损伤病人膀胱康复的护理体会.全科医学临床与教育,2006,4(3):261-262.
7.侯春林.脊髓损伤后膀胱功能重建.北京:人民军医出版社,2006:28-29.
8.郭友仁.唐山大地震截瘫15年康复工作回顾.伤残医学杂志,1994,2(4):282-284.
9. Frankel HL, Coll JR, Charlifue SW, et al. Long-term survival in spinal cord injury:a fifty year investigation. Spinal Cord,1999,36:266-274.
10. Brindley GS. The first 500 patients with sacral anterior root stimulator implants:general description. Paraplegia,1994,32 (12):795-805.
11. Gasparini ME, Schmidt RA, Tanagho EA. Selective sacral rhizotomy of the reflex neuropathic bladder:a report on 17 patients with long-term follow-up. J Urol,1992, 148:1207-1210.
12.张世民,侯春林.选择性骶神经前后根组合切断恢复脊髓损伤后膀胱功能的实验研究.中国修复重建外科杂志,2001,15(2):69-73.
13. Lapides J, Diokno AC, Silber SJ, et al. Clean intermittent self-catheterization in the treatment of urinary tract disease. J Urol,1972;107:458-463.
14. Yamamoto M, Yasukawa M, Yoshii M, et al. Clean intermittent catheterization in the management of spina bifida:a review of 113 cases. Hinyokika Kiyo,1997, 37:117-121.
15. Lightner, DJ. Contemporary urologic management of patients with spinal cord injury. Mayo Clin Proc,1998,73:434-438.
16. Polliack T, Bluvshtein V, Philo O, et al.Clinical and economic consequences of volume-or time-dependent intermittent catheterization in patients with spinal cord lesions and neuropathic bladder. Spinal Cord,2005,43(10):615-619.
17. Oh SJ, Ku JH, Jeon HG, et al. Health-related quality of life of patients using clean intermittent catheterization for neurogenic bladder secondary to spinal cord injury. Urology,2005,65(2):306-310.
18. Ku JH, Jung TY, Lee JK, et al. Influence of bladder management on epididymo-orchitis in patients with spinal cord injury:clean intermittent catheterization is a risk factor for epididymo-orchitis. Spinal Cord,2006, 44(3):165-169.
19. Chang SM, Hou CL, Dong DQ, et al. Urologic status of 74 spinal cord injury patients from the 1976 Tangshan earthquake, and managed for over 20 years using the Crede maneuver.Spinal Cord,2000,38(9):552
20. De Groat WC. Anatomy and physiciology of micturition and continence. J Urol Clin Nor Am,1996,23:221-230.
21. Wein AJ. Pharmacologic treatment of incontinence. J Am Geriatr Soc,1990, 38(3):317-325.
22. Swierzewski SJ, Gormley EA, Belville WD, et al. The effect of terazosin on bladder function in the spinal cord injured patient.J Urol,1994,151(4):951-954.
23. Ukhal MI, Malomuzh OI, Strashnyi VV, et al.The use of the alpha 1-adrenoblocker doxazosin in the pharmacotherapy of disorders of urine outflow of spastic origin. LikSprava,1998, (8):118-121.
24.郑樱,刘根林,郝春霞,等.阿夫唑嗪用于脊髓损伤患者膀胱训练的疗效观察中国康复理论与实践,2004,10(11):706-707.
25.刘明轩,侯春林,邱实Baclofen与异搏停治疗脊髓损伤后痉挛性膀胱的对比研究.中国脊柱脊髓杂志,2000,10(2):87-89.
26.李志,梁忆,彭阿钦,等.力奥来素对脊髓不全损伤患者排尿障碍的作用.临床骨科杂志,2005,8(2):161-162.
27. Vaidyanathan S, Soni BM, Sett P, et al.Flawed trial of micturition in cervical spinal cord injury patients:guidelines for trial of voiding in men with tetraplegia. Spinal Cord,2003,41(12):667-672.
28. Denys P, Even-Schneider A, Remy-Neris O, et al.Intrathecal therapy for Bladder hyperreflexia.Neurochirurgie,2003,49:395-398.
29. Ninkovic M, Stenzl A, Schwabegger A, et al. Free neurovascular transfer of latisstmus dorsi muscle for the treatment of bladder acontractility:Ⅱ. Clinical results. J Urol,2003,169:1379-1383.
30. Stenzl A, Ninkovic M, Willleit J, et al. Free neurovascular transfer of latissimus dorsi muscle to the bladder.Ⅰ.Experimental studies. J Urol,1997,157:1103-1108.
31. Stenzl A, Ninkovic M. Restoring voluntary urinary voiding using a latissimus dorsi muscle free flap for bladder reconstruction. Micro surgery,2001,21(6):235-240.
32. Ninkovic M, Kronberger P, Harpf C, et al. Free vated latissimis dorsi muscle (LDM) flap for reconstruction of thickness abdominal defects. Plast reconstr surg,1997, 100:402-407.
33. Von Heyden B, Anthony JP, Kaula N, et al. The latissimus dorsi muscle for detrusor assistance:functional recovery after nerve division and repair. J Urol,1994, 151:1081-1087.
34.赵继懋,张玉海,王金铭.膀胱腹直肌间置术治疗无反射性膀胱.中国脊柱脊髓杂志,2000,10(2):84-85.
35. Carlsson CA, Sundin T. Reconstruction of severed ventral roots innervating the urinarybladder. An experimental study in cats. Scand J Urol Nephrol,1968, 2(3):199-210.
36. Sundin T, Carlsson CA. Reconstruction of severed dorsal roots innervating the urinary bladder.An experimental study in cats. Ⅱ Regeneration studies. Scand J Urol Nephrol,1972,6(2):185-196.
37. Chuang DC, Chang PL, Cheng SY. Root reconstruction for bladder reinnervation:an experimental study in rats. Microsurgery,1991,12 (4):237-245.
38. Xiao CG, Godec CJ. A possible new reflex pathway for micturition after spinal cord injury.Paraplegia,1994,32(5):300-307.
39.刘智,胥少汀.修复马尾神经恢复膀胱功能的实验观察.中华外科杂志,1995,33(12):719-722.
40. Xiao CG, De Groat WC, Godec CJ, et al. "Skin-CNS-bladder" reflex pathway for micturitionafter spinal cord injury and its underlying mechanisms. J Urol,1999,162(3):936-942.
41.侯春林,衷鸿宾,刘明轩.脊髓损伤后膀胱人工反射弧建立的实验研究.中国修复重建外科杂志,2000,14(1):10-13.
42.王金武,侯春林,卢宁, 等.利用腹壁反射重建膀胱反射弧的远期功能性研究.中华显微外科杂志,2002,25(4):280-284.
43.王金武,侯春林,钟慈声,等.利用腹壁反射建立人工膀胱反射弧的实验形态学研究.解放军医学杂志,2003,28(8):666-667.
44.王金武,侯春林,李继峰,等.利用腹壁反射建立人工膀胱反射弧的HRP逆行示踪研究.中华创伤骨科杂志,2004,6(4):414-417.
45.唐颖,杜全印,王爱民.建立脊髓损伤犬腹壁膀胱人工反射弧的实验.中国临床康复,2005,9(25):216-218.
46.钟贵彬,侯春林,王诗波,等.建立人工膀胱反射弧治疗脊髓损伤后弛缓性膀胱的实验研究.中国修复重建外科杂志,2006,20(8):812-815.
47. Haodong Lin, Chunlin Hou, and Xianyou Zhen. Bypassing Spinal Cord Injury:Surgical Reconstruction of Afferent and Efferent Pathways to the Urinary Bladder after Conus Medullaris Injury in a Rat Model. J Reconstr Microsurg 2008;24:575-582.
48. Sievert KD, Xiao CG, Hennenlotter J, et al. Voluntary micturition after intradural nerveanastomosis.Urologe A,2005,44(7):756-761.
49.侯春林,钟贵彬,谢庆平,等.人工反射弧重建脊髓损伤后弛缓性膀胱排尿功能的临床初步报告.中华显微外科杂志,2006,29(2):92-94.
50.张少成,瞿创予,张雪松,等.神经移植术治疗截瘫神经性膀胱的尿动力学观察.中华泌尿外科杂志,2001,22(4):220-222.
51. Livshits A, Catz A, Folman Y, et al.Reinnervation of the neurogenic bladder in the late period of the spinal cord trauma. Spinal Cord,2004,42(4):211-217.
52. Guillotreau J, Game X, Castel-Lacanal E, et al. Laparoscopic cystectomy and transileal ureterostomy for neurogenic vesicosphincteric disorders. Evaluation of morbidity Prog Urol,2007,17(2):208-212.
53. Hubert J, Feuillu B, Beis JM, et al.Laparoscopic robotic-assisted ileal conduit urinary diversion in a quadriplegic woman. Urology,2003,62(6):1121.
54. X Zheng, C Hou, A Chen, J Li, Z Xu and J Wang. Optimal timing of operation for repairing atonic bladder after medullary cone injury:an experimental study in rats. Spinal Cord. Houndsmills:Aug 2008. Vol.46, Iss.8; p.574-581.
2、黎鳌,盛志勇,王正国.现代战伤外科学.北京:人民军医出版社,1998:856.
3、郭友仁.唐山大地震截瘫15年康复工作回顾.伤残医学杂志,1994,2(4):282-284.
4、Tanagho EA, Schmidt RA. Electrical stimulation in the clinical management of the neurogenic bladder. J Urol 1988:140:1331-1339
5、Selzman AA, Hampel N. Urologic complications of spinal cord injury. Urol Clin North Am 1993:20:453-464
6. Brindley GS, Polkey CE, Rushton DN, Cardozo L. Sacral anterior root stimulators for bladder control in paraplegia:the first 50 cases. J Neurol Neurosurg Psychiatry 1986:49:1104-1114
7. Zheng XY, Hou CL, Zhong HB, Xu RS, Chen AM, Xu Z, Wang JH. Reconstructed bladder innervation below the level of spinal cord injury:the knee-tendon to bladder artificial reflex arc. J Spinal Cord Med.2009;32(1):79-85
8. Lin H, Hou C, Zhen X, Xu Z. Clinical study of reconstructed bladder innervation below the level of spinal cord injury to produce urination by Achilles tendon-to-bladder reflex contractions. J Neurosurg Spine.2009 May;10(5):452-7.
9.徐瑞生,侯春林,张世民,等.“膝腱-脊髓-膀胱”反射弧的形态学观察.中国脊柱脊髓杂志,2002,12(4):273-276.
10.徐瑞生,侯春林,张世民,等.“膝腱-脊髓-膀胱”反射弧重建膀胱功能的解剖与临床.中国矫形外科杂志,2002,10(9):869-871.
11.侯春林,王诗波,陈爱民,等.利用跟腱反射建立人工膀胱反射弧的临床研究.解放军医学杂志,2003,28(8):668-669.
12. Zheng XY, Hou CL, Zhong HB, Xu RS, Chen AM, Xu Z, Wang JH. Reconstructed bladder innervation below the level of spinal cord injury:the knee-tendon to bladder artificial reflex arc. J Spinal Cord Med.2009;32(1):79-85
13. Lin H, Hou C, Zhen X, Xu Z. Clinical study of reconstructed bladder innervation below the level of spinal cord injury to produce urination by Achilles tendon-to-bladder reflex contractions. J Neurosurg Spine.2009 May; 10(5):452-7.
14.赵定麟.现代脊柱外科学.上海:世界图书出版公司,2006:201.
15. Chuang DC,Chang PL, Cheng SY. Root reconstruction for bladder reinnervation:an experimental study in rats. Microsurgery.1991,12(4):237-245.
16. Xiao CG, Godec CJ. A possible new reflex pathway for micturition after spinal cord injury. Paraplegia,1994,32(5):300-307.
17.侯春林,衷鸿宾,刘明轩.脊髓损伤后膀胱人工反射弧建立的实验研究.中国修复重建外科杂志.2000,14(1):10-13.
18. Sievert KD, Xiao CG, Hennenlotter J, et al. Voluntary micturition after intradural nerve anastomosis. Urologe A,2005,44(7):756-761.
19.侯春林,钟贵彬,谢庆平,等.人工反射弧重建脊髓损伤后弛缓性膀胱排尿功能的临床初步报告.中华显微外科杂志,2006,29(2):92-94.
20. X Zheng, C Hou, A Chen, J Li, Z Xu and J Wang. Optimal timing of operation for repairing atonic bladder after medullary cone injury:an experimental study in rats. Spinal Cord. Houndsmills:Aug 2008. Vol.46, Iss.8; p.574-581.
21. Gu Y, Xu J, Chen L, Wang H, Hu S. Long term outcome of contralateral C7 transfer: a report of 32 cases. Chin Med J (Engl).2002;115(6):866-8.
22. Xu L, Gu Y, Xu J, Lin S, Chen L, Lu J. Contralateral C7 transfer via the prespinal and retropharyngeal route to repair brachial plexus root avulsion:a preliminary report. Neurosurgery.2008:63(3):553-558.
23. Fumio A, Butler M, Blomberg H, et al. Variation in rat sciatic nerve anatomy: implications for a rat model of neuropathic pain. J Peripher Nerv Syst,2000,5:19-21.
1、Baydin A, Cokluk C, Aydin K. A New Minimally Invasive Experimental Spinal Cord Injury Model in Rabbits. Minim Invasive Neurosurg,2007,50(3) 170-172.
2、Lim JH, Jung CS, Byeon YE, et al. Establishment of a canine spinal cord injury model induced by epidural balloon compression. J Vet Sci,2007,8(1):89-94.
3、Kasahara K, Nakagawa T, Kubota T. Neuronal loss and expression of neurotrophic factors in a model of rat chronic compressive spinal cord injury. Spine,2006,31(18):2059-2066.
4、Lee M, Lee ES, Kim YS, Choi BH, et al. Ischemic injury-specific gene expression in the rat spinal cord injury model using hypoxia-inducible system. Spine,2005,30(24):2729-2734.
5、Liu L, Chi LT, Tu ZQ, et al. Observation and establishment of an animal model of tractive spinal cord injury in rats. Chin J Traumatol,2004,7(6):372-377.
6、徐建广 顾玉东.大鼠坐骨神经显微解剖及其意义[J].上海医学,1999,22(3):154-156.
7、Fumio A, Butler M, Blomberg H, et al. Variation in rat sciatic nerve anatomy: implications for a rat model of neuropathic pain. J Peripher Nerv Syst,2000,5:19-21.
8、曹学成.大鼠坐骨神经的解剖学研究[J].中国实验动物学杂志,2002,12(4):213-214.
9、江曦 陈爱民 张志凌 侯春林 鹿楠.SD 大鼠坐骨神经结构及其支配肌群的探讨[J].生物骨科材料与临床研究,2009,6(4):5-7.
10、卢能祖,曾庆杏,李曾宴,等.实用肌电图学[M].北京:人民卫生出版社,2000:194-206,420-7.
11、顾玉东,沈丽英,沈尊理,等.臂丛神经根支配功能的电生理研究中华外科杂志,1996,34(1):40-3.
12、徐峰,傅中国,张殿英,等.腰神经根与其支配肌群的电生理定位实验.中国临床康复杂志.2006,7(26):16-18.
1、Bain J, Mackinnon S, Hunter DA. Functional evaluation of complete sciatic, peroneal, and posterior tibial nerve lesions in the rat[J]. Plast Reconstr Surg,1989,83(1):129-138.
2、Cortez R, Levi AD. Acute spinal cord injury. Curr Treat Options Neurol,2007,9(2):115-125.
3、Benevento BT, Sipski ML. Neurogenic bladder, neurogenic bowel, and sexual dysfunction in people with spinal cord injury. Phys Ther, 2002,82(6):601-612.
4、Patrick GM, Mahony JF, Disney AP. The prognosis for end-stage renal failure in spinal cord injury and spina bifida-Australia and New Zealand, 1970-1991. Aust N Z J Med,1994,24(1):36-40.
5、Frankel HL, Coll JR, Charlifue SW, et al. Long-term survival in spinal cord injury:a fifty year investigation. Spinal Cord,1998,36(4): 266-274.
6、Samson G, Cardenas DD. Neurogenic bladder in spinal cord injury.Phys Med Rehabil Clin N Am,2007,18(2):255-274
7、侯春林.脊髓损伤后膀胱功能重建.解放军医学杂志,2003,28(8):663-665.
8、X Zheng, C Hou, A Chen, J Li, Z Xu and J Wang. Optimal timing of operation for repairing atonic bladder after medullary cone injury:an experimental study in rats. Spinal Cord. Houndsmills:Aug 2008. Vol. 46, Iss.8; p.574-581.
9、王金武,侯春林,卢宁,等.利用腹壁反射重建膀胱反射弧的远期功能性研究.中华显微外科杂志,2002,25(4):280-284.
10、Haodong Lin,Chunlin Hou, Aimin Chen, Zhen Xu.Innervation of Reconstructed Bladder Above the Level of Spinal Cord Injury or Inducing Micturition by Contractions of the Abdomen-to-Bladder Reflex Arc. Neurosurgery,2010,28(5).
11、钟贵彬,侯春林,王诗波,等.建立人工膀胱反射弧治疗脊髓损伤后弛缓性膀胱的实验研究.中国修复重建外科杂志,2006,20(8):812-815.
12、Lin H, Hou C, Zhong G, Xie Q, and Wang S. Reconstruction of reflex pathways to the atonic bladder after conus medullaris injury: preliminary clinical results. Microsurg 2008:229-435.
13、侯春林,钟贵彬,谢庆平,等.人工反射弧重建脊髓损伤后弛缓性膀胱排尿功能的临床初步报告.中华显微外科杂志,2006,29(2):92-94.
14、Gu Y, Xu J, Chen L, Wang H, Hu S. Long term outcome of contralateral C7 transfer:a report of 32 cases. Chin Med J (Engl). 2002;115(6):866-8.
15、Xu L, Gu Y, Xu J, Lin S, Chen L, Lu J. Contralateral C7 transfer via the prespinal and retropharyngeal route to repair brachial plexus root avulsion:a preliminary report. Neurosurgery.2008;63(3):553-558.
16、杨安峰,王平.大鼠的解剖和组织.北京:科学出版社,1985:177-180.
1. Bain J, Mackinnon S, Hunter DA. Functional evaluation of complete sciatic, peroneal, and posteriortibial nerve lesions in the rat[J]. Plast Reconstr Surg,1989,83(1):129-138.
2. Cortez R, Levi AD. Acute spinal cord injury. Curr Treat Options Neurol,2007,9(2):115-125.
3. Benevento BT, Sipski ML. Neurogenic bladder, neurogenic bowel, and sexual dysfunction in people with spinal cord injury. Phys Ther, 2002,82(6):601-612.
4. Patrick GM, Mahony JF, Disney AP. The prognosis for end-stage renal failure in spinal cord injury and spina bifida-Australia and New Zealand,1970-1991. Aust N Z J Med,1994,24(1):36-40.
5. Frankel HL, Coll JR, Charlifue SW, et al. Long-term survival in spinal cord injury:a fifty year investigation. Spinal Cord,1998,36(4): 266-274.
6. Samson G, Cardenas DD. Neurogenic bladder in spinal cord injury.Phys Med Rehabil Clin N Am,2007,18(2):255-274
7.侯春林.脊髓损伤后膀胱功能重建.解放军医学杂志,2003,28(8):663-665.
8. X Zheng, C Hou, A Chen, J Li, Z Xu and J Wang. Optimal timing of operation for repairing atonic bladder after medullary cone injury:an experimental study in rats. Spinal Cord. Houndsmills:Aug 2008. Vol. 46, Iss.8; p.574-581.
9.王金武,侯春林,卢宁,等.利用腹壁反射重建膀胱反射弧的远期功能性研究.中华显微外科杂志,2002,25(4):280-284.
10.Haodong Lin,Chunlin Hou, Aimin Chen, Zhen Xu.Innervation of Reconstructed Bladder Above the Level of Spinal Cord Injury or Inducing Micturition by Contractions of the Abdomen-to-Bladder Reflex Arc. Neurosurgery,2010,28(5).
11.钟贵彬,侯春林,王诗波,等.建立人工膀胱反射弧治疗脊髓损伤后弛缓性膀胱的实验研究.中国修复重建外科杂志,2006,20(8):812-815.
12. Lin H, Hou C, Zhong G, Xie Q, and Wang S. Reconstruction of reflex pathways to the atonic bladder after conus medullaris injury: preliminary clinical results. Microsurg 2008:229-435.
13.侯春林,钟贵彬,谢庆平,等.人工反射弧重建脊髓损伤后弛缓性膀胱排尿功能的临床初步报告.中华显微外科杂志,2006,29(2):92-94.
14.Gu Y, Xu J, Chen L, Wang H, Hu S. Long term outcome of contralateral C7 transfer:a report of 32 cases. Chin Med J (Engl). 2002;115(6):866-8.
15.Xu L, Gu Y, Xu J, Lin S, Chen L, Lu J. Contralateral C7 transfer via the prespinal and retropharyngeal route to repair brachial plexus root avulsion:a preliminary report. Neurosurgery.2008;63(3):553-558.
16.杨安峰,王平.大鼠的解剖和组织.北京:科学出版社,1985:177-180.
17.胥少汀,葛宝丰,徐印坎.实用骨科学.北京:人民军医出版社,2003:603.
1、Gu YD. Functional motor innervation of brachial plexs roots. Anintra operative electrophysiological study. J Hand Surg(Br),1997,22:258-260.
2、叶智彰,彭燕章,张耀平.猕猴解剖[M].北京:科学出版社,1985.
3、钟品仁.哺乳类实验动物[M].人民卫生出版社,北京.1983.314-334.
4、魏振年.猕猴的生殖生理及科研应用[J].动物学杂志,1988,23(6):46-50.
5、Chan AW S, Chong KY, M ar t inovich C, et al. Transgenic monkeys produced by ret roviral genet ransfer intro mature oocytes[J]. Science,2001,291 (5502):309-312.
6、Wooley DP, Smith RA, Czajak S, et al. Direct demonst ration of ret roviral recombination in a rhesusmonkey[J]. Journal of Virology.1997,71:9650-9653.
7、郭常安,胡有谷,卜光颜.猕猴腰椎观察[J].上海实验动物科学,2002,(2):83-88.
8、卢能祖,曾庆杏,李曾宴,等.实用肌电图学[M].北京:人民卫生出版社,2000:194-206,420-7.
9、顾玉东,沈丽英,沈尊理等.臂丛神经根支配功能的电生理研究中华外科杂志,1996,34(1):40-3.
10、徐峰,傅中国,张殿英等.腰神经根与其支配肌群的电生理定位实验.中国临床康复杂志.2006,7(26):16-18.
1.侯春林.脊髓损伤后膀胱功能重建.北京:人民军医出版社,2006:7-11.
2.黎鳌,盛志勇,王正国.现代战伤外科学.北京:人民军医出版社,1998:856.
3.张宪郁,徐皓.骨髓间充质干细胞在脊髓损伤治疗中的应用.脊柱外科杂志,2006,4(6):373-376.
4. Benevento BT, Sipski ML. Neurogenic bladder, neurogenic bowel, and sexual dysfunction in people with spinal cord injury. Physical Therapy,2002, 82(6):601-612.
5.刘根林,李建军.脊髓损伤继发肾积水的病理生理与治疗.中国康复理论与实践,2006,12(12):1026-1028.
6.史玲美,陈洁.脊髓损伤病人膀胱康复的护理体会.全科医学临床与教育,2006,4(3):261-262.
7.侯春林.脊髓损伤后膀胱功能重建.北京:人民军医出版社,2006:28-29.
8.郭友仁.唐山大地震截瘫15年康复工作回顾.伤残医学杂志,1994,2(4):282-284.
9. Frankel HL, Coll JR, Charlifue SW, et al. Long-term survival in spinal cord injury:a fifty year investigation. Spinal Cord,1999,36:266-274.
10. Brindley GS. The first 500 patients with sacral anterior root stimulator implants:general description. Paraplegia,1994,32 (12):795-805.
11. Gasparini ME, Schmidt RA, Tanagho EA. Selective sacral rhizotomy of the reflex neuropathic bladder:a report on 17 patients with long-term follow-up. J Urol,1992, 148:1207-1210.
12.张世民,侯春林.选择性骶神经前后根组合切断恢复脊髓损伤后膀胱功能的实验研究.中国修复重建外科杂志,2001,15(2):69-73.
13. Lapides J, Diokno AC, Silber SJ, et al. Clean intermittent self-catheterization in the treatment of urinary tract disease. J Urol,1972;107:458-463.
14. Yamamoto M, Yasukawa M, Yoshii M, et al. Clean intermittent catheterization in the management of spina bifida:a review of 113 cases. Hinyokika Kiyo,1997, 37:117-121.
15. Lightner, DJ. Contemporary urologic management of patients with spinal cord injury. Mayo Clin Proc,1998,73:434-438.
16. Polliack T, Bluvshtein V, Philo O, et al.Clinical and economic consequences of volume-or time-dependent intermittent catheterization in patients with spinal cord lesions and neuropathic bladder. Spinal Cord,2005,43(10):615-619.
17. Oh SJ, Ku JH, Jeon HG, et al. Health-related quality of life of patients using clean intermittent catheterization for neurogenic bladder secondary to spinal cord injury. Urology,2005,65(2):306-310.
18. Ku JH, Jung TY, Lee JK, et al. Influence of bladder management on epididymo-orchitis in patients with spinal cord injury:clean intermittent catheterization is a risk factor for epididymo-orchitis. Spinal Cord,2006, 44(3):165-169.
19. Chang SM, Hou CL, Dong DQ, et al. Urologic status of 74 spinal cord injury patients from the 1976 Tangshan earthquake, and managed for over 20 years using the Crede maneuver.Spinal Cord,2000,38(9):552
20. De Groat WC. Anatomy and physiciology of micturition and continence. J Urol Clin Nor Am,1996,23:221-230.
21. Wein AJ. Pharmacologic treatment of incontinence. J Am Geriatr Soc,1990, 38(3):317-325.
22. Swierzewski SJ, Gormley EA, Belville WD, et al. The effect of terazosin on bladder function in the spinal cord injured patient.J Urol,1994,151(4):951-954.
23. Ukhal MI, Malomuzh OI, Strashnyi VV, et al.The use of the alpha 1-adrenoblocker doxazosin in the pharmacotherapy of disorders of urine outflow of spastic origin. LikSprava,1998, (8):118-121.
24.郑樱,刘根林,郝春霞,等.阿夫唑嗪用于脊髓损伤患者膀胱训练的疗效观察中国康复理论与实践,2004,10(11):706-707.
25.刘明轩,侯春林,邱实Baclofen与异搏停治疗脊髓损伤后痉挛性膀胱的对比研究.中国脊柱脊髓杂志,2000,10(2):87-89.
26.李志,梁忆,彭阿钦,等.力奥来素对脊髓不全损伤患者排尿障碍的作用.临床骨科杂志,2005,8(2):161-162.
27. Vaidyanathan S, Soni BM, Sett P, et al.Flawed trial of micturition in cervical spinal cord injury patients:guidelines for trial of voiding in men with tetraplegia. Spinal Cord,2003,41(12):667-672.
28. Denys P, Even-Schneider A, Remy-Neris O, et al.Intrathecal therapy for Bladder hyperreflexia.Neurochirurgie,2003,49:395-398.
29. Ninkovic M, Stenzl A, Schwabegger A, et al. Free neurovascular transfer of latisstmus dorsi muscle for the treatment of bladder acontractility:Ⅱ. Clinical results. J Urol,2003,169:1379-1383.
30. Stenzl A, Ninkovic M, Willleit J, et al. Free neurovascular transfer of latissimus dorsi muscle to the bladder.Ⅰ.Experimental studies. J Urol,1997,157:1103-1108.
31. Stenzl A, Ninkovic M. Restoring voluntary urinary voiding using a latissimus dorsi muscle free flap for bladder reconstruction. Micro surgery,2001,21(6):235-240.
32. Ninkovic M, Kronberger P, Harpf C, et al. Free vated latissimis dorsi muscle (LDM) flap for reconstruction of thickness abdominal defects. Plast reconstr surg,1997, 100:402-407.
33. Von Heyden B, Anthony JP, Kaula N, et al. The latissimus dorsi muscle for detrusor assistance:functional recovery after nerve division and repair. J Urol,1994, 151:1081-1087.
34.赵继懋,张玉海,王金铭.膀胱腹直肌间置术治疗无反射性膀胱.中国脊柱脊髓杂志,2000,10(2):84-85.
35. Carlsson CA, Sundin T. Reconstruction of severed ventral roots innervating the urinarybladder. An experimental study in cats. Scand J Urol Nephrol,1968, 2(3):199-210.
36. Sundin T, Carlsson CA. Reconstruction of severed dorsal roots innervating the urinary bladder.An experimental study in cats. Ⅱ Regeneration studies. Scand J Urol Nephrol,1972,6(2):185-196.
37. Chuang DC, Chang PL, Cheng SY. Root reconstruction for bladder reinnervation:an experimental study in rats. Microsurgery,1991,12 (4):237-245.
38. Xiao CG, Godec CJ. A possible new reflex pathway for micturition after spinal cord injury.Paraplegia,1994,32(5):300-307.
39.刘智,胥少汀.修复马尾神经恢复膀胱功能的实验观察.中华外科杂志,1995,33(12):719-722.
40. Xiao CG, De Groat WC, Godec CJ, et al. "Skin-CNS-bladder" reflex pathway for micturitionafter spinal cord injury and its underlying mechanisms. J Urol,1999,162(3):936-942.
41.侯春林,衷鸿宾,刘明轩.脊髓损伤后膀胱人工反射弧建立的实验研究.中国修复重建外科杂志,2000,14(1):10-13.
42.王金武,侯春林,卢宁, 等.利用腹壁反射重建膀胱反射弧的远期功能性研究.中华显微外科杂志,2002,25(4):280-284.
43.王金武,侯春林,钟慈声,等.利用腹壁反射建立人工膀胱反射弧的实验形态学研究.解放军医学杂志,2003,28(8):666-667.
44.王金武,侯春林,李继峰,等.利用腹壁反射建立人工膀胱反射弧的HRP逆行示踪研究.中华创伤骨科杂志,2004,6(4):414-417.
45.唐颖,杜全印,王爱民.建立脊髓损伤犬腹壁膀胱人工反射弧的实验.中国临床康复,2005,9(25):216-218.
46.钟贵彬,侯春林,王诗波,等.建立人工膀胱反射弧治疗脊髓损伤后弛缓性膀胱的实验研究.中国修复重建外科杂志,2006,20(8):812-815.
47. Haodong Lin, Chunlin Hou, and Xianyou Zhen. Bypassing Spinal Cord Injury:Surgical Reconstruction of Afferent and Efferent Pathways to the Urinary Bladder after Conus Medullaris Injury in a Rat Model. J Reconstr Microsurg 2008;24:575-582.
48. Sievert KD, Xiao CG, Hennenlotter J, et al. Voluntary micturition after intradural nerveanastomosis.Urologe A,2005,44(7):756-761.
49.侯春林,钟贵彬,谢庆平,等.人工反射弧重建脊髓损伤后弛缓性膀胱排尿功能的临床初步报告.中华显微外科杂志,2006,29(2):92-94.
50.张少成,瞿创予,张雪松,等.神经移植术治疗截瘫神经性膀胱的尿动力学观察.中华泌尿外科杂志,2001,22(4):220-222.
51. Livshits A, Catz A, Folman Y, et al.Reinnervation of the neurogenic bladder in the late period of the spinal cord trauma. Spinal Cord,2004,42(4):211-217.
52. Guillotreau J, Game X, Castel-Lacanal E, et al. Laparoscopic cystectomy and transileal ureterostomy for neurogenic vesicosphincteric disorders. Evaluation of morbidity Prog Urol,2007,17(2):208-212.
53. Hubert J, Feuillu B, Beis JM, et al.Laparoscopic robotic-assisted ileal conduit urinary diversion in a quadriplegic woman. Urology,2003,62(6):1121.
54. X Zheng, C Hou, A Chen, J Li, Z Xu and J Wang. Optimal timing of operation for repairing atonic bladder after medullary cone injury:an experimental study in rats. Spinal Cord. Houndsmills:Aug 2008. Vol.46, Iss.8; p.574-581.