大鼠逼尿肌活动不足模型通过圆锥髓质横断
Özet
我们提出了一种通过大鼠髓圆锥横断建立逼尿肌活动不足模型的方法。在这些动物中成功刺激了逼尿肌活动不足。该模型可用于研究尿路功能。
Abstract
所提出的协议的目标是通过圆锥髓质横断在大鼠中建立逼尿肌活动不足(DU)模型。在总共40只雌性Wistar大鼠(对照组:10只大鼠;试验组:30只大鼠)中,体重200-220 g,在试验组中,髓圆锥在L4\u2012L5水平进行横断。将所有大鼠在相同的环境条件下饲养和喂养六周。在测试组中,每天进行两次排尿,持续六周,并记录平均残余尿量。两组均行膀胱测量图。记录并计算膀胱的最大膀胱测量容量(MCC),逼尿肌开放压力(DOP)和膀胱顺应性。测试组在手术后,无论是在脊柱休克期间还是之后,都显示出明显的尿潴留。但对照组未见异常。与对照组相比,试验组的MCC和膀胱顺应性显著高于试验组(3.24 ± 2.261 mL vs 1.04 ± 0.571 mL;0.43 ± 0.578 mL/cmH 2 O 对比 0.032 ± 0.016 mL/cmH 2 O),而试验组的DOP低于对照组(20.28 ± 14.022 cmH 2 O与35 ± 13.258 cmH22这种通过圆锥髓质横断建立贫铀动物模型的方法为更好地了解DU的病理生理学提供了绝佳的机会。
Introduction
逼尿肌活动不足(DU)是一种典型的下尿路功能障碍,至今仍在研究中。尽管贫铀已由国际尿失禁协会(ICS)1定义,但使用许多不同的术语来指代这种疾病,例如“逼尿肌衰竭”、“收缩性膀胱”、“逼尿肌反射消失”2。根据国际尿失禁协会 (ICS) 在 2002 年的定义,DU 是一种力量和持续时间减少的收缩,导致膀胱排空时间延长,从而导致无法在正常时间内实现膀胱完全排空。
DU 可能影响 48% 的男性和 12% 的女性(>70 岁)3 伴有下尿路症状。它似乎是多因素的,并且没有有效的治疗方法。据悉,DU在神经源性膀胱功能障碍患者中普遍存在,如多发性硬化症4、糖尿病5、帕金森病6或脑卒中7。贫铀也可由医源性神经损伤引起,例如腹腔镜子宫切除术、前列腺切除术或其他小骨盆的手术干预8.由于缺乏合适的动物模型进行研究,贫铀的病理生理学变化和可用的治疗方法仍然令人困惑。
排尿反射由脊柱-球脊髓通路控制,该通路结合了脑桥排尿中心、骶副交感神经核和更高级的皮质中心9。排尿反射的激活和维持主要取决于感觉信号从膀胱到更高级的皮层中心的定期传输。可以推测感觉功能障碍会导致 DU。
大多数与下尿路功能障碍相关的实验动物研究都集中在膀胱过度活动症(OAB)模型10上。这些模型提供了对OAB病理生理学和预后的合理理解。然而,只有少数 DU 模型被报道,例如脊髓上损伤(局部病变、去脑和大脑中动脉闭塞)、脊髓横断或挫伤、全身性(例如环磷酰胺)或膀胱内给予刺激性或炎症性物质(例如酸、丙烯醛和脂多糖)11,12,13,14.在这些方法中,只有脊髓横断或挫伤法可用于建立DU13的动物模型。由于严重的创伤,涉及脑桥排尿中心和高级皮层中心损伤的尝试被放弃。因此,人们越来越注意在排尿反射中心找到一个准确的位置,以最小的副作用诱导贫铀。
如前所述,诱导贫铀的机制之一是损伤脊髓以损害排尿反射的信号通路。艾伦的减重方法是为了建立脊髓受伤的实验动物而开发的15。但是,没有关于该方法的进一步实验数据。此外,由于部分动物在没有DU的情况下恢复了中风后的脊柱功能,因此不能将其视为生成DU动物模型16的完美方法。
1987年,布雷格曼发现了一种横断脊髓的过程,以生成DU动物模型,并获得了实验数据17。然而,该方法并未应用于建立贫铀动物模型。当时,研究人员仍然对DU的发病机制感到困惑。由于脊髓中与OAB或DU诱导相关的位置彼此相邻,因此他们无法找到脊髓损伤的准确位置以诱导DU17。OAB和DU要么一起引入,要么通过这种方法单独引入。因此,这种方法虽然引入了DU,但它并不精确,不能用于理解DU的发生和处理。
如上所述,缺乏合适的贫铀动物模型是贫铀研究的主要障碍之一。 研究人员一直在寻找一种准确且可管理的模型,可以模拟贫铀的病理学。在过去20年中,即使是贫铀的治疗方案也没有显著改善。总的来说,非常需要描述建立DU动物模型的标准协议。
因此,在本文中,我们描述了一种通过圆锥髓质横断成功建立DU大鼠模型的方法。在L4-L5水平进行横断,以分离髓圆锥。记录并分析膀胱的最大膀胱容量(MCC),逼尿肌开口压力(DOP)和膀胱顺应性以验证方案。下面所述的协议以标准化的方式结合了可行性和可靠性,以建立贫铀动物模型,模拟贫铀的发生和处理。该协议可用作进一步研究DU的技术。
Protocol
Representative Results
Discussion
贫铀是男性和女性下尿路症状的常见原因。这是一个复杂的症状群,几乎没有治疗选择,可以显着降低受影响者的生活质量(Qol)18。尽管人们认为贫铀是多因素的,但对其发病机制的理解仍然很初步。研究表明,贫铀的发病机制可能与肌源性和神经源性因素有关。
在肌源性假说中,观察到患有贫铀的人可能比健康衰老的人经历更显着的逼尿肌收缩力下降。…
Açıklamalar
The authors have nothing to disclose.
Acknowledgements
没有。
Materials
| 0.9% saline | Wuhan Prosai Company | EY-C1178 | pump for urodynamic measurement |
| 10% chloral hydrate | Shandong Yulong Co., Ltd | H37022673 | 3mL/kg,administered intraperitoneally |
| Buprenorphine Hydrochloride Injection | Tianjin Pharmaceutical Research Institute Pharmaceutical Co. LTD | H12020275 | 0.05mg/kg subcutaneously 24h and 48h postoperation |
| Epidural Catheter | Shandong Xinghua Co, Ltd | VABR3L | for urodynamic measurement |
| Penicillin G | Alta Technology Co., Ltd | 1ST5637 | 50,000 unit/ml per animal |
| pentobarbital | Beijing solabo Technology Co., Ltd | NK-WF0001 | 40 mg/kg, administered intraperitoneally |
| Suture line(4-0) | ETHICON | VCP422H | suture the injury |
| Three-limb tube | Shandong Xinghua Co, Ltd | VAB3T | for urodynamic measurement |
| Trace infusion pump | Zhejiang Smith Medical Instrument Co., Ltd | 20162540335 | Pump the saline at a speed of 0.2ml/min for urodynamic measurement |
| Urodynamic measurement equipment | Medical Measurement SystemsB.V. | 08-0467 | urodynamic measurement equipment can not only help the diagnosis of dysuria, but also provide objective materials for treatment and therapeutic effect. It is the most commonly used examination method in clinical diagnosis and treatment of lower urinary tract functional diseases |
| Wistar Rats | HFK Biotechnology Co.Ltd,Beijing ,China | SCXK2012-0023 | 200-220g |
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