Modulation of the rat micturition reflex with transcutaneous ultrasound

INTRODUCTION Low intensity focused ultrasound has recently been identified as a novel method of stimulating targeted neurons. We hypothesized that ultrasound stimulation of the posterior tibial nerve would inhibit bladder contractions in an established rat model of rhythmic bladder contractions. MET...

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Bibliographic Details
Published in:Neurourology and urodynamics 2017-11, Vol.36 (8), p.1996-2002
Main Authors: Casella, Daniel P., Dudley, Anne G., Clayton, Douglass B., Pope, John C., Tanaka, Stacy T., Thomas, John, Adams, Mark C., Brock, John W., Caskey, Charles F.
Format: Article
Language:English
Subjects:
Animals
Bladder
Female
focused ultrasound
Latency
Muscle Contraction - physiology
Muscle, Smooth - physiology
neuromodulation
posterior tibial nerve stimulation
Rats
Rats, Sprague-Dawley
Reflex - physiology
Reflexes
Rhythms
Rodents
Tibial nerve
Tibial Nerve - physiology
Ultrasonic imaging
Ultrasonography
Ultrasound
Urinary bladder
Urination
Urination - physiology
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Summary:INTRODUCTION Low intensity focused ultrasound has recently been identified as a novel method of stimulating targeted neurons. We hypothesized that ultrasound stimulation of the posterior tibial nerve would inhibit bladder contractions in an established rat model of rhythmic bladder contractions. METHODS Cyclical detrusor contractions were initiated by placing a transurethral catheter in female rats and infusing saline into the bladder. Transcutaneous ultrasound pulses were then delivered to the lower extremity of a rat (overlying the posterior tibial nerve) using a single element spherically focused 250 kHz transducer. Sixty‐three cycles were repeated at 2 kHz for 300 ms at peak negative pressure of 900 kPa pulsed at 0.5 Hz. RESULTS We report successful suppression of bladder contractions using ultrasound stimulation in 10 animals. The average latency between the initiation of ultrasound and suppression of bladder contractions was 3 min 23 s (±51 s), the average time of contraction suppression was 13 min and 50 s (±2 min 25 s) and the average time from the end of ultrasound to return of contractions was 9 min 37 s (±2 min and 30 s). CONCLUSION In this work, we demonstrate the ability of targeted transcutaneous ultrasound to inhibit rhythmic bladder contractions in anesthetized rats. Due to its non‐invasive nature and ease of application, we believe ultrasound mediated suppression of the micturition reflex is potentially an ideal outpatient treatment of overactive bladder and dysfunctional elimination.
ISSN:0733-2467
1520-6777
DOI:10.1002/nau.23241