Pharmacological modulation of ureteral peristalsis in a chronically instrumented conscious pig model. I: Effect of cholinergic stimulation and inhibition.

PURPOSE: We evaluated in vivo the role of muscarinic receptors on ureteral peristaltic frequency and contraction force in a large animal model using pharmacological manipulation. MATERIALS AND METHODS: A total of 12 female pigs weighing a mean +/- SEM of 72 +/- 4 kg were chronically instrumented using an electronic pressure monitoring catheter in the right ureter. Furthermore, nephrostomy, arterial, venous and cystostomy catheters were placed. Ureteral peristalsis was repeatedly recorded before and after the administration of atropine and carbachol. RESULTS: Systemic and local effects of the 2 agents were observed. Compared with controls we recorded an increase in mean ureteral peristaltic frequency (2.0 +/- 0.3 versus 1.6 +/- 0.6 minutes-1, p <0.05) and mean contraction force (50.1 +/- 1.4 versus 45.3 +/- 1.7 cm H(2)O, p <0.05) during renal pelvis perfusion with 0.25 ml per minute saline. Administration of atropine or carbachol modulated neither the force of contraction nor the frequency of ureteral peristalsis in vivo (p >0.05). CONCLUSIONS: Smooth muscle motor activity at the mid and distal ureter is not modulated by muscarinic receptors. Peristaltic frequency is directly related to the pyelocaliceal load during a rate of diuresis not exceeding animal normal diuresis plus 0.25 ml per minute. Ureteral contraction force increases only in the mid ureter with increased diuresis.

Intraluminal pressure changes in vivo in the middle and distal pig ureter during propagation of a peristaltic wave.

OBJECTIVES: To establish the characteristics of mechanical activity during ureteral peristalsis and unidirectional bolus transport, pressure changes in the middle and distal (juxtavesical and ureterovesical junction) porcine ureter were quantified in vivo. METHODS: Five female New Yorkshire pigs (50 to 60 kg) were studied under halothane anesthesia. The endoscopic approach was used to position an 8-channel 6 F perfusion catheter under direct vision into the distal ureter by way of the orifice. Ureteral activity was studied in two separate sessions at 1-week intervals. The pressure, propagation velocity, and length of the peristaltic waves were analyzed. RESULTS: The average maximal pressure in a not previously instrumented ureter amounted to 35.7 +/- 1.2 cm H(2)O in the mid-ureter, and decreased to 19.4 +/- 1.3 cm H(2)O in the juxtavesical ureter (P < 0.001) and further to 7.2 +/- 1.0 cm H(2)O (P < 0.001) in the submucosal segment. The propagation velocity of the peristaltic wave through the ureter was 2.1 +/- 1.3 cm/s. The length of the pressure peak was 5.9 +/- 1.6 cm. CONCLUSIONS: A ureteral peristaltic contraction wave travels at approximately 2 cm/s and is approximately 6 cm long. It is responsible for the unidirectional transport of a urinary bolus and itself acts as an "active" antireflux mechanism. The maximal pressure in the lumen of the ureter decreased from proximally to distally, but remains sufficiently high at the ureterovesical junction to prevent retrograde urine leakage when the ureter empties its urinary bolus into the bladder and the orifice is open.

An in vivo endoluminal ultrasonographic study of peristaltic activity in the distal porcine ureter.

PURPOSE: Experiments were performed to quantify the duration and frequency of ureteric peristaltic activity in the laparotomized and non-laparotomized pig in its virgin and postinstrumented states. MATERIALS AND METHODS: Pigs (n = 10) in a steady state of hydration were studied under halothane anesthesia in two groups. The study was undertaken in two separate sessions at a week's interval. In group I laparotomy and vesicotomy were undertaken to obtain ELUS images. In group II, peristalsis was studied using an ELUS probe introduced through the working channel of a 22F rigid cystoscope. Peristalsis was visualized as a periodic diameter-change of ureter and recorded (for approx. 30 minutes) on videotape after an initial period of adaptation of approx. 30 minutes. RESULTS: The ureter acts like a pump discharging urine into the bladder through peristaltic activity. ELUS imaging of ureteric peristalsis correlated well with "eyeballing" of the passage of peristalsis through a ureter (group I). The shortest peristaltic activity in group I was 6.0+/-2.0 seconds in the non-instrumented- and 5.1+/-1.4 seconds in the instrumented ureter. In group II it was 6.8+/-1.5 seconds in the non-instrumented- and 6.4+/-1.5 seconds in the instrumented ureter. Chronic dilatation of ureter led to decrease in peristalsis frequency. Interestingly, acute dilatation caused an increase in ureteric peristalsis frequency. CONCLUSIONS: Ureteric peristalsis acts as a pump discharging urinary boluses (intraluminal fluid load) unidirectionally into the bladder. ELUS provides us an opportunity to quantify and study ureteric peristalsis.

An electro-myographic study of the distal porcine ureter.

PURPOSE: The accumulation of urine in the renal pelvis causes depolarisation of non-specific muscular pace-maker cells. The wave of depolarisation spreads distally in the ureteric smooth muscle cells via gap junctions. This wave of excitation causes a coordinated peristaltic contraction which transports the urine bolus distally to the bladder. The EMG activity in the distal porcine ureter was studied and analyzed to establish the characteristics of ureteric excitation. MATERIALS AND METHODS: Ten female New Yorkshire pigs (50 to 60 kg.) were studied in two groups under light halothane anesthesia (5% at induction and 1% for maintenance anesthesia). In both groups each pig was studied in two separate sessions at a week's interval. In group I (n = 5), bipolar needle electrodes (o: 0. 09 mm.) were implanted through a lower mid-line abdominal incision in the posterior bladder wall, the trigone and the pelvic ureter at intervals of 3 and 8 cm., respectively, from the ureteric orifice. In group II (n = 5), EMG spike burst activity was studied using a twin bipolar ring-electrode attached to an endoluminal ureteric catheter. EMG complexes were recorded using 0 to 30 Hz filters. The duration of spike burst complexes and their intervals were analyzed using a Nicollet, Pathfinder II(R) machine and a Poly(R) 4.9 digital signal processing program. RESULTS: Two types of spike burst activity could be distinguished between the electrodes: A, the migrating type and B, the non-migrating type. Frequency distribution analysis of spike burst duration revealed two main classes in experimental group II, a short spike burst (96%) which lasted 4.5 +/- 1.8 seconds and a longer one lasting 13.4 +/- 1.5 seconds. The conduction velocity of the migrating spike bursts (n = 177, 42% of total) between the proximal and the distal electrode had an average of 2.3 +/- 1.3 cm./sec. No relationship was found between the duration of the proximal spike burst and the conduction velocity. Data from experimental group I correlated well with data from group II. CONCLUSIONS: The results of our EMG study in the distal ureter reveal an approximately 9 cm. long electrically active zone in >/= 90% of EMG activity recordings. The duration of activity was approximately 5 seconds. Such an excited segment of ureter led to a contraction which occluded the ureter and could prevent retrograde leakage of intraluminal contents.

A study of ureteric peristalsis using a single catheter to record EMG, impedance, and pressure changes.

Ureteric peristalsis transports a urinary bolus from the renal pelvis to the bladder. We developed an intraluminal catheter with a pressure transducer on it to study intraluminal pressure changes and a twin bipolar electrode to record the ureteric EMG and impedance (Z) changes during a peristaltic wave. Five female New Yorkshire pigs (50-60 kg) were studied under light halothane anesthesia (5% at induction/1% for maintenance). A steady state of hydration was maintained using intravenous saline infusion. EMG spike burst activity was studied at a 10-cm interval using low (0-30) Hz filters. Impedance between the same electrodes is measured simultaneously in higher frequencies (1-5 KHz) as a function of ureteric motor activity. Pressure generation in the ureteric lumen was also measured simultaneously by a transducer on the same catheter. A digital signal processing program (Poly 4.9) was used for analysis. Parenteral furosemide was used to induce diuresis. Resting ureteric impedance (Z(R)) decreases to Z(B) (Z bolus) during the passage of the urinary bolus. Passage of a contractile zone during a peristaltic wave increases impedance from Z(B) to its Z(R) level and initiates a pressure rise. Bolus length (the length Z(B)) is not constant and decreases distally. EMG corresponds well in time to impedance. Z(R) disappears after infusion of furosemide because of increased urine load and changes of intraluminal ionic environment. The contractile segment of a ureteric peristaltic wave appears to be represented by an elevated Z segment (Z(C)). Pressure rise is recorded only at the beginning of a contractile zone. A specially adapted intraluminal catheter can be used to study peristalsis in the upper urinary tract. One can study all the three components of ureteric peristalsis (excitation, contraction, and intraluminal pressure rise) using such a catheter.

Three-dimensional pressure profilometry of the anal sphincter.

Single channel manometry is of limited value in determining the cause of sphincter dysfunction. This is due mainly to the recording variability caused by radial pressure asymmetry. Multi-channel manometry does not have this disadvantage, but is complicated and difficult to interpret. We report on computerized eight-channel manometry which permits three-dimensional reconstruction of the sphincter. Fifteen subjects were measured. At rest, lower pressures were recorded in the left, left-dorsal, and dorsal directions. Sphincter length was shortest in the right direction and ventral directions. The graphic reconstruction showed marked indentations in the right- and right anterior direction, and one indentation on the opposite side. At maximal squeeze the graphic reconstruction showed the same indentations, but they were more pronounced. In conclusion, computerized eight-channel manometry proved to be an efficient technique which could be routinely applicable. The graphic reconstruction provides insight into radial and axial pressure asymmetry.

The lower esophageal sphincter shown by a computerized representation.

The clinical application of manometry of the lower esophageal sphincter (LES) remains controversial. This is because of the large variability in recorded lower esophageal sphincter pressure (LESP). In this paper a computerized method providing a three-dimensional image of the LES is described. In 12 healthy subjects end-expiratory rapid pull-through LESP recordings were performed for 1 h, using a perfused 8-channel probe. A cylindric model of the sphincter was calculated by means of a graphics program. The graphic representation of the LES demonstrated a circular pressure zone that was affected by the gastric migrating motility complex. This pressure zone was located proximal to a persistent indentation in the posterior and right posterolateral direction. Three-dimensional visualization of the LES provides additional information that cannot be obtained by the usually used techniques of analysis of sphincter manometry.