OBJECTIVE: To characterize the contractile activity that occurs in the bladder during the filling phase of the micturition cycle (non-micturition contractions, NMCs), which generate transient rises in intravesical pressure not associated with urine flow. MATERIALS AND METHODS: The experiments were conducted using anaesthetized (chloral hydrate) and un-anaesthetized rats. In un-anaesthetized rats bladder contractile activity was measured using an intravesical cannula implanted under full surgical anaesthesia 3 days previously. In the anaesthetized rats the bladder was exteriorized and a cannula inserted through the dome. In these experiments electrical activity within the detrusor was also measured with a suction electrode on the bladder surface. For each rat, the experimental protocol involved filling the bladder at a constant rate (10 mL/h) to evoke micturition cycles, or infusion of a fixed volume and recording made under effective isovolumetric conditions. RESULTS: In both anaesthetized and un-anaesthetized rats there were transient rises in bladder pressure (0.5-3 cmH2O). In the anaesthetized rats the amplitude of the transients increased throughout the filling phase, with little change in frequency. The phasic NMCs generating these pressure transients were accompanied by electrical changes in the detrusor. In the middle phase of bladder filling the slow pressure changes were accompanied by slow waves of electrical activity which changed in the pressure cycles immediately before micturition to high-frequency low-amplitude signals. In the un-anaesthetized rats there was a period immediately after voiding where there was no activity. As filling proceeded, low-amplitude low-frequency NMCs appeared that gradually increased in frequency and amplitude during the filling phase. However, the frequency of the transients decreased immediately before micturition despite an increase in amplitude. Similar responses were seen during isovolumetric recording. CONCLUSION: The present results show the presence of NMCs in the rat bladder, identify volume-dependent changes in the pattern of this activity during the micturition cycle, and show that NMCs are accompanied by electrical changes in the detrusor. The physiological significance of NMCs is not known but it might be linked to the generation of afferent discharge from mechanoreceptors in the wall, so contributing to sensations related to bladder volume.
OBJECTIVE: To characterize the contractile activity that occurs in the bladder during the filling phase of the micturition cycle (non-micturition contractions, NMCs), which generate transient rises in intravesical pressure not associated with urine flow. MATERIALS AND METHODS: The experiments were conducted using anaesthetized (chloral hydrate) and un-anaesthetized rats. In un-anaesthetized rats bladder contractile activity was measured using an intravesical cannula implanted under full surgical anaesthesia 3 days previously. In the anaesthetized rats the bladder was exteriorized and a cannula inserted through the dome. In these experiments electrical activity within the detrusor was also measured with a suction electrode on the bladder surface. For each rat, the experimental protocol involved filling the bladder at a constant rate (10 mL/h) to evoke micturition cycles, or infusion of a fixed volume and recording made under effective isovolumetric conditions. RESULTS: In both anaesthetized and un-anaesthetized rats there were transient rises in bladder pressure (0.5-3 cmH2O). In the anaesthetized rats the amplitude of the transients increased throughout the filling phase, with little change in frequency. The phasic NMCs generating these pressure transients were accompanied by electrical changes in the detrusor. In the middle phase of bladder filling the slow pressure changes were accompanied by slow waves of electrical activity which changed in the pressure cycles immediately before micturition to high-frequency low-amplitude signals. In the un-anaesthetized rats there was a period immediately after voiding where there was no activity. As filling proceeded, low-amplitude low-frequency NMCs appeared that gradually increased in frequency and amplitude during the filling phase. However, the frequency of the transients decreased immediately before micturition despite an increase in amplitude. Similar responses were seen during isovolumetric recording. CONCLUSION: The present results show the presence of NMCs in the rat bladder, identify volume-dependent changes in the pattern of this activity during the micturition cycle, and show that NMCs are accompanied by electrical changes in the detrusor. The physiological significance of NMCs is not known but it might be linked to the generation of afferent discharge from mechanoreceptors in the wall, so contributing to sensations related to bladder volume.
Authors: J I Gillespie; C Rouget; S Palea; C Granato; L Birder; C Korstanje Journal: Naunyn Schmiedebergs Arch Pharmacol Date: 2015-05-26 Impact factor: 3.000
Authors: Robert W Hamill; John D Tompkins; Beatrice M Girard; Richard T Kershen; Rodney L Parsons; Margaret A Vizzard Journal: Dev Neurobiol Date: 2012-06 Impact factor: 3.964
Authors: C Granato; C Korstanje; V Guilloteau; C Rouget; S Palea; J I Gillespie Journal: Naunyn Schmiedebergs Arch Pharmacol Date: 2015-06-11 Impact factor: 3.000
Authors: Simon Studeny; Bopaiah P Cheppudira; Susan Meyers; Elena M Balestreire; Gerard Apodaca; Lori A Birder; Karen M Braas; James A Waschek; Victor May; Margaret A Vizzard Journal: J Mol Neurosci Date: 2008-06-17 Impact factor: 3.444
Authors: Bopaiah P Cheppudira; Beatrice M Girard; Susan E Malley; Abbey Dattilio; Kristin C Schutz; Victor May; Margaret A Vizzard Journal: Am J Physiol Renal Physiol Date: 2009-07-22
Authors: Kavirach Tantiwongse; Thomas M Fandel; Guifang Wang; Benjamin N Breyer; Thomas J Walsh; Anthony J Bella; Tom F Lue Journal: BJU Int Date: 2008-07-01 Impact factor: 5.588