Acute urinary retention is one of the most common complications after surgery and anesthesia. Micturition depends on coordinated actions between the detrusor muscle and the external urethral sphincter. Under the influence of epidural analgesia, patients may not feel the sensation of bladder filling, which can result in urinary retention and bladder overdistension. Overfilling of the bladder can stretch and in some cases permanently damage the detrusor muscle. Because epidural anesthesia can be performed at various levels of the spinal cord, it is possible to block only a portion of the spinal cord (segmental blockade). Thoracic epidural analgesia with bupivacaine significantly inhibits the detrusor muscle during voiding, resulting in clinically relevant post void residuals which required monitoring or transurethral catheterisation. This bladder muscle inhibition is comparable to a motor blockade. The epidural administration of ropivacaine during labour results in a clinically relevant reduction of motor blocks. The hypothesis is that thoracic epidural analgesia with the local anesthetics ropivacaine leads to less significant changes in bladder function than bupivacaine as a control group, in patients undergoing lumbotomy incision for renal surgery.
Background Acute urinary retention is one of the most common complications after surgery and anesthesia. It can occur in patients of both sexes and all age groups and after all types of surgical procedures. It is linked to several factors including increased intravenous fluids, postoperative pain and type of anaesthesia. Micturition depends on coordinated actions between the detrusor muscle and the external urethral sphincter. Motorneurons of both muscles are located in the sacral spinal cord and coordination between them occurs in the pontine tegmentum of the caudal brain stem. Motorneurons innervating the external urethral sphincter are located in the nucleus of Onuf, extending from segment S1 to S3. The detrusor smooth muscle is innervated by parasympathetic fibers, which reside in the sacral intermediolateral cell group and are located in S2-4. Sympathetic fibers innervating the bladder and urethra play an important role in promoting continence and are located in the intermediolateral cell group of the lumbar cord (L1-L4). Most afferent fibers from the bladder enter the sacral cord through the pelvic nerve at segments L4-S2 and the majority are thin myelinated or unmyelinated. There are few studies on the urodynamic effects of various anaesthetic agents, which mainly focused on lumbar epidural anaesthesia. Under the influence of epidural analgesia, patients may not feel the sensation of bladder filling, which can result in urinary retention and bladder overdistension. Overfilling of the bladder can stretch and in some cases permanently damage the detrusor muscle. Because epidural anesthesia can be performed at various levels of the spinal cord, it is possible to block only a portion of the spinal cord (segmental blockade). Based on knowledge of the bladder innervations, it can be assumed that epidural analgesia within segments T4-6 to T10-12 has no or minimal influences on lower urinary tract function. In a previous study, the investigators found, against their expectations, that thoracic epidural analgesia (TEA) with bupivacaine significantly inhibits the detrusor muscle during voiding, resulting in clinically relevant post void residuals which required monitoring or transurethral catheterisation 11. This detrusor inhibition is comparable to a motor blockade. In addition, it is known that the epidural administration of ropivacaine during labour results in a clinically relevant reduction of motor blocks. However, the analgesic potency of ropivacaine is approximately 60% that of bupivacaine. Objective The main objectives of this investigator initiated trial are: * To analyse if a TEA with the local anesthetics ropivacaine leads to less detrusor atony and thus resulting to lower incidence of postvoid residual urine volume resulting in postoperative urinary retention. * To compare urodynamic parameters (storage and voiding phases) during TEA with ropivacaine versus bupivacaine. Methods Assessments of bladder function: International Prostate Symptom Score (IPSS) will be used for assessment of lower urinary tract symptoms preoperatively. Urodynamic investigations will be performed: The first investigation will be done as baseline data before attempted surgery. Urodynamic investigations will be performed according to good urodynamic practice. After placement of a 6 French transurethral dual channel catheter and a 14 French rectal balloon catheter (Gaeltec, Dunvegan, Scotland), the bladder will be filled at a rate of 25 to 50 ml/min with Ringer's lactate solution at room temperature. Parameters of both the storage phase (maximum cystometric capacity, bladder compliance) and voiding phase (detrusor pressure at maximum flow rate (PdetQmax), maximum flow rate (Qmax) and PVR will be recorded. All methods, definitions and units will be in accordance with the standards recommended by the International Continence Society.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
TRIPLE
Enrollment
42
local anesthetics, which will epidurally administered
local anesthetics, which will epidurally administered
Patrick Wuethrich, Department of Anaesthesiology and Pain Therapy, University Hospital Bern Inselspital Bern
Bern, Canton of Bern, Switzerland
Post void residual urine volume: Change between postvoid residual urine volume before surgery versus during thoracic epidural analgesia for postoperative analgesia
Time frame: before surgery/TEA (baseline), during TEA (expected to be on average ca. 5 days)
Bladder volume at first desire to void (mL)
Change of the parameters of the storage and voiding phases from baseline (preoperative) to postoperative day 2 or 3, depending on patient's mobility.
Time frame: before surgery/TEA (baseline), during TEA (expected to be on average ca. 5 days)
Maximum cystometric capacity (mL)
Change of the parameters of the storage and voiding phases from baseline (preoperative) to postoperative day 2 or 3, depending on patient's mobility.
Time frame: before surgery/TEA (baseline), during TEA (expected to be on average ca. 5 days)
Bladder compliance (mL/cmH2O)
Change of the parameters of the storage and voiding phases from baseline (preoperative) to postoperative day 2 or 3, depending on patient's mobility.
Time frame: before surgery/TEA (baseline), during TEA (expected to be on average ca. 5 days)
Urethral pressure profile (cmH2O)
Change of the parameters of the storage and voiding phases from baseline (preoperative) to postoperative day 2 or 3, depending on patient's mobility.
Time frame: before surgery/TEA (baseline), during TEA (expected to be on average ca. 5 days)
Maximum detrusor pressure (cmH2O)
Change of the parameters of the storage and voiding phases from baseline (preoperative) to postoperative day 2 or 3, depending on patient's mobility.
Time frame: before surgery/TEA (baseline), during TEA (expected to be on average ca. 5 days)
Detrusor pressure at maximum flow rate(cmH2O)
Change of the parameters of the storage and voiding phases from baseline (preoperative) to postoperative day 2 or 3, depending on patient's mobility.
Time frame: before surgery/TEA (baseline), during TEA (expected to be on average ca. 5 days)
Maximum flow rate (mL/sec)
Change of the parameters of the storage and voiding phases from baseline (preoperative) to postoperative day 2 or 3, depending on patient's mobility.
Time frame: before surgery/TEA (baseline), during TEA (expected to be on average ca. 5 days)
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