Fogg Ryan W, Ghatas Mina P, McCormack Brendan, Shields Michael, Matthew Ashley N, Grob Gabrielle, Araia Nat, Burkett Linda, Speich John E, Klausner Adam P
Department of Surgery, Division of Urology, Virginia Commonwealth University Health System, Richmond, Virginia, USA.
Department of Obstetrics & Gynecology, Virginia Commonwealth University Health System, Richmond, Virginia, USA.
Neurourol Urodyn. 2025 Feb;44(2):504-511. doi: 10.1002/nau.25661. Epub 2025 Jan 13.
Observable autonomous rhythmic changes in intravesical pressure, termed bladder wall micromotion, is a phenomenon that has been linked to urinary urgency, the key symptom in overactive bladder (OAB). However, the mechanism through which micromotion drives urinary urgency is poorly understood. In addition, micromotion is inherently difficult to study in human urodynamics due to challenges distinguishing it from normal cyclic physiologic processes such as pulse rate, breathing, rectal contractions, and ureteral jetting. Therefore, the goal of this study was to create a reproducible model of micromotion using an ex-vivo perfused porcine bladder, as well as to describe the relationship between micromotion and afferent nerve signaling.
Porcine bladders were reanimated using ex-vivo perfusion with a physiologic buffer. The pelvic nerve adjacent to the bladder was dissected, grasped with micro-hook electrodes and electroneurogram (ENG) signals were recorded at 20 kHz. Bladders were catheterized and intravesical pressure measurements were taken using a Laborie XT Urodynamics system. Bladders were filled to a fixed volume of 300 mL and control measurements were recorded. The bladders were then washed with 0.001 M carbachol (CCh) solution and refilled to 300 mL to induce micromotion, which was detected as rhythmic changes in intravesical pressure. ENG amplitude was calculated in μV, and nerve firing rate was calculated as number of spikes above baseline threshold per minute.
Micromotion was induced by carbachol in 12/25 (48.4%) of trials as rhythmic changes in intravesical pressure after the instillation of carbachol but not in any control period. A fast Fourier transform (FFT) algorithm showed average peak dominant frequency component amplitude was significantly higher during the carbachol period when compared to the control period (0.47 vs. 0.01 cm-HO, p < 0.0001). Peak waveform frequency (1.13 vs. 1.54 cycles/min, p > 0.05) did not differ between control and carbachol periods. With regard to afferent nerve signaling, normalized average amplitude (0.66 ± 0.24 vs. 0.05 ± 0.08 μV) and firing rate (0.68 ± 0.28 vs. 0.18 ± 0.22 spike/min) for all bladders was significantly greater in the carbachol period when compared to the control period (p < 0.001).
Micromotion can be induced using instillation of carbachol in a perfused ex-vivo porcine bladder. Increased afferent nerve firing is observed during periods of micromotion. Thus, micromotion may drive afferent nerve signaling and may potentially contribute to urinary urgency, detrusor overactivity, and OAB. The development of an experimental ex-vivo porcine model for micromotion provides a reproducible method to study bladder micromotion and its potential role in the pathophysiology of urinary urgency and voiding dysfunction.
膀胱内压的可观察到的自主性节律变化,即膀胱壁微运动,是一种与尿急相关的现象,尿急是膀胱过度活动症(OAB)的关键症状。然而,微运动驱动尿急的机制尚不清楚。此外,由于难以将其与诸如脉搏率、呼吸、直肠收缩和输尿管喷射等正常周期性生理过程区分开来,在人体尿动力学中对微运动进行研究具有内在的困难。因此,本研究的目的是使用离体灌注的猪膀胱创建一个可重复的微运动模型,并描述微运动与传入神经信号之间的关系。
使用生理缓冲液对猪膀胱进行离体灌注使其复苏。解剖膀胱附近的盆神经,用微型钩状电极抓取并以20kHz记录神经电图(ENG)信号。将膀胱插管,使用Laborie XT尿动力学系统进行膀胱内压测量。将膀胱充盈至固定体积300mL并记录对照测量值。然后用0.001M卡巴胆碱(CCh)溶液冲洗膀胱,并重新充盈至300mL以诱导微运动,微运动被检测为膀胱内压的节律性变化。ENG振幅以μV计算,神经放电率计算为每分钟高于基线阈值的尖峰数量。
在12/25(48.4%)的试验中,卡巴胆碱诱导了微运动,表现为滴注卡巴胆碱后膀胱内压的节律性变化,而在任何对照期均未出现。快速傅里叶变换(FFT)算法显示,与对照期相比,卡巴胆碱期平均峰值主导频率成分振幅显著更高(0.47对0.01cm-HO,p<0.0001)。对照期和卡巴胆碱期的峰值波形频率(1.13对1.54次/分钟,p>0.05)无差异。关于传入神经信号,与对照期相比,所有膀胱在卡巴胆碱期的归一化平均振幅(0.66±0.24对0.05±0.08μV)和放电率(0.68±0.28对0.18±0.22次/分钟)均显著更高(p<0.001)。
在离体灌注的猪膀胱中滴注卡巴胆碱可诱导微运动。在微运动期间观察到传入神经放电增加。因此,微运动可能驱动传入神经信号,并可能导致尿急、逼尿肌过度活动和OAB。一种用于微运动的实验性离体猪模型的开发提供了一种可重复的方法来研究膀胱微运动及其在尿急和排尿功能障碍病理生理学中的潜在作用。
