OBJECTIVETo study the neurophysiologic of detrusor overactivity (DO) due to partial bladder outflow obstruction (PBOO).

METHODSTwenty four female Wistar rats with DO caused by PBOO were studied simultaneously with ten sham-operated rats. An electrophysiological multi-channel simultaneous recording system was used to record pelvic afferent fiber potentials as well as the pudendal nerve motor branch potentials, external urethral sphincter electromyogram (EUS EMG) and abdominal muscle EMG during filling cystometry. To test the effect of the unstable contraction in DO rats after the decentralization of the central nervous system, DO rats were studied the changes of the unstable contraction after transection of the spinal cord (T(8) level), pelvic nerve, the sympathetic trunk, and the pudendal nerve.

RESULTSThe incidence of DO was 62.5% in filling cystometry. During filling cystometry, there are two type of DO contraction according to the changes of pelvic afferent fiber signals, the relevant nerves and muscles responses: the small pressure of the unstable contraction (S-DO) and the big pressure of the unstable contraction (B-DO). For the B-DO, there were significant changes in the recordings of pelvic afferent fiber, the motor branch of the pudendal nerve, EUS EMG, and abdominal muscle EMG. While all these differences have not been recorded during S-DO. Both the filling-voiding cycle and the unstable contraction of B-DO were eliminated and the base line of bladder pressure increased after T(8) spinal cord transection. While the S-DO was not affected by such transection. When bladder relevant nerves were transected by the sequence of the pelvic nerve, the sympathetic trunk, and the pudendal nerve, the filling-voiding cycle was eliminated. The base line of bladder pressure increased significantly. No B-DO was recorded, but the S-DO still existed.

CONCLUSIONThere are some bladder-genic factors take part in the DO contractions induced by PBOO.

Animals ; Disease Models, Animal ; Female ; Pelvic Floor ; innervation ; Rats ; Rats, Wistar ; Urinary Bladder ; innervation ; Urinary Bladder Neck Obstruction ; complications ; physiopathology ; Urinary Bladder, Overactive ; etiology ; physiopathology

No abstract available.
Female ; Humans ; Hysterectomy/adverse effects/*methods ; Postoperative Complications/*prevention & control ; Urinary Bladder/*innervation/physiopathology ; Urodynamics/*physiology

OBJECTIVETo observe the effects on the lower limbs function after lumbar or sacral nerve root transferring to reconstruct urination function.

METHODSNine patients with bladder dysfunction and normal lower limb function after spinal cord injury were treated with anastomosis the S2 or S3 nerve root with the normal lumbar or sacral nerve root to reconstruct a new bladder artificial reflex arc. Then the alterations on the sensation and motor function of the lower limb after the surgery were observed.

RESULTSMyodynamia of the legs decreased slightly, and the decreasing about half grade of the myodynamia in the plantar flexion of the ankles were detected in 4 of 9 patients with S1 transferring. And the myodynamia recovered 3 months postoperatively. No obvious decreasing of the myodynamia appeared in the other cases.

CONCLUSIONNo obvious effects on the motor function can be found after the single lumbar or sacral nerve root transferring to reconstruct urination function.

Adult ; Exercise ; Female ; Follow-Up Studies ; Humans ; Lower Extremity ; innervation ; physiopathology ; Lumbosacral Region ; Male ; Middle Aged ; Reflex ; Rhizotomy ; Spinal Cord Injuries ; complications ; physiopathology ; Spinal Nerve Roots ; surgery ; Treatment Outcome ; Urinary Bladder ; innervation ; physiopathology ; Urinary Bladder, Neurogenic ; etiology ; physiopathology ; surgery

OBJECTIVE: This study was conducted to ascertain the correlation between preserved pelvic nerve networks and bladder function after laparoscopic nerve-sparing radical hysterectomy. METHODS: Between 2009 and 2011, 53 patients underwent total laparoscopic radical hysterectomies. They were categorized into groups A, B, and C based on the status of preserved pelvic nerve networks: complete preservation of the pelvic nerve plexus (group A, 27 cases); partial preservation (group B, 13 cases); and complete sacrifice (group C, 13 cases). To evaluate bladder function, urodynamic studies were conducted preoperatively and postoperatively at 1, 3, 6, and 12 months after surgery. RESULTS: No significant difference in sensory function was found between groups A and B. However, the sensory function of group C was significantly lower than that of the other groups. Group A had significantly better motor function than groups B and C. No significant difference in motor function was found between groups B and C. Results showed that the sensory nerve is distributed predominantly at the dorsal half of the pelvic nerve networks, but the motor nerve is predominantly distributed at the ventral half. CONCLUSION: Various types of total laparoscopic nerve-sparing radical hysterectomies can be tailored to patients with cervical carcinomas.
Adult ; Aged ; Female ; Humans ; Hypogastric Plexus/injuries ; Hysterectomy/adverse effects/*methods ; Laparoscopy/adverse effects/*methods ; Middle Aged ; Neoplasm Staging ; Pelvis/innervation ; Peripheral Nerve Injuries/etiology/*prevention & control ; Postoperative Period ; Urinary Bladder/*innervation/physiopathology ; Urodynamics ; Uterine Cervical Neoplasms/pathology/*surgery

OBJECTIVETo identify and separate the ventral root from dorsal root, which is the key for success of the artificial somatic-autonomic reflex pathway procedure for neurogenic bladder after spinal cord injury (SCI). Here we report the results of intra-operating room monitoring with 10 paralyzed patients.

METHODSTen male volunteers with complete suprasacral SCI underwent the artificial somatic-autonomic procedure under general anesthesia. Vastus medialis, tibialis anticus and gastrocnemius medialis of the left lower limb were monitored for electromyogram (EMG) activities resulted from L4, L5, and S1 stimulation respectively to differentiate the ventral root from dorsal root. A Laborie Urodynamics system was connected with a three channel urodynamic catheter inserted into the bladder. The L2 and L3 roots were stimulated separately while the intravesical pressure was monitored to evaluate the function of each root.

RESULTSThe thresholds of stimulation on ventral root were 0.02 ms duration, 0.2-0.4 mA, (mean 0.3 mA+/-0.07 mA), compared with 0.2-0.4 ms duration, 1.5-3 mA (mean 2.3 mA+/-0.5 mA) for dorsal root (P<0.01) to cause revoked potentials and EMG. Electrical stimulation on L4 roots resulted in the EMG being recorded mainly on vastus medialis, while stimulation on L5 or S1 roots caused electrical activities of tibialis anticus or gastrocnemius medialis respectively. The continuous stimulation for about 3-5 seconds on S2 or S3 ventral root (0.02 ms, 20 Hz, and 0.4 mA) could resulted in bladder detrusor contraction, but the strongest bladder contraction over 50 cm H2O was usually caused by stimulation on S3 ventral root in 7 of the 10 patients.

CONCLUSIONSIntra-operating room electrophysiological monitoring is of great help to identify and separate ventral root from dorsal root, and to select the appropriate sacral ventral root for best bladder reinnervation. Different parameters and thresholds on different roots are the most important factors to keep in mind to avoid damaging the roots and to assure the best results.

Adult ; Autonomic Pathways ; physiopathology ; Electric Stimulation Therapy ; methods ; Electromyography ; Electrophysiology ; methods ; Humans ; Male ; Muscle Contraction ; Muscle, Skeletal ; physiopathology ; Muscle, Smooth ; physiopathology ; Reflex ; Spinal Cord Injuries ; complications ; physiopathology ; Spinal Nerve Roots ; physiopathology ; surgery ; Thigh ; Urinary Bladder ; innervation ; physiopathology ; Urinary Bladder, Neurogenic ; etiology ; physiopathology ; surgery

Acetylcholine ; metabolism ; physiology ; Animals ; Cholinergic Agonists ; pharmacology ; Male ; Muscle Contraction ; drug effects ; physiology ; Muscle Relaxation ; drug effects ; physiology ; Muscle, Smooth ; drug effects ; pathology ; physiopathology ; Rabbits ; Random Allocation ; Receptors, Cholinergic ; physiology ; Synaptic Transmission ; drug effects ; Urinary Bladder ; drug effects ; innervation ; physiopathology

OBJECTIVETo establish an artificial somatic-autonomic reflex arc in rats and observe the following distributive changes of neural fibers in the bladder.

METHODSAdult Sprague-Dawley rats were randomly divided into three groups: control group, spinal cord injury (SCI) group, and reinnervation group. DiI retrograde tracing was used to verify establishment of the model and to investigate the transport function of the regenerated efferent axons in the new reflex arc. Choline acetyltransferase (ChAT) in the DiI-labeled neurons was detected by immunohistochemistry. Distribution of neural fibers in the bladder was observed by acetylcholine esterase staining.

RESULTSDiI-labeled neurons distributed mainly in the left ventral horn from L3 to L5, and some of them were also ChAT-positive. The neural fibers in the bladder detrusor reduced remarkably in the SCI group compared with the control (P < 0.05). After establishment of the somatic-autonomic reflex arc in the reinnervation group, the number of ipsilateral fibers in the bladder increased markedly compared with the SCI group (P < 0.05), though still much less than that in the control (P < 0.05).

CONCLUSIONThe efferent branches of the somatic nerves may grow and replace the parasympathetic preganglionic axons through axonal regeneration. Acetylcholine is still the major neurotransmitter of the new reflex arc. The controllability of detrusor may be promoted when it is reinnervated by the pelvic ganglia efferent somatic motor fibers from the postganglionic axons.

Acetylcholinesterase ; biosynthesis ; Anastomosis, Surgical ; Animals ; Autonomic Fibers, Preganglionic ; physiology ; Cholinergic Fibers ; metabolism ; Immunohistochemistry ; Motor Neurons ; cytology ; metabolism ; Nerve Regeneration ; physiology ; Neural Pathways ; cytology ; metabolism ; Rats ; Rats, Sprague-Dawley ; Reflex ; physiology ; Spinal Cord Injuries ; physiopathology ; Spinal Nerve Roots ; surgery ; Urinary Bladder ; innervation ; physiology ; surgery ; Urinary Bladder, Neurogenic ; surgery