Potential for recovery in bladder function after removing a urethral obstruction.

AIMS: We examined the relation between the loss of bladder function during obstruction and the potential for recovery of function after de-obstruction. METHODS: Guinea pigs received a partial urethral obstruction. Bladder pressure, urine flow rate, detrusor overactivity (DO), compliance and contractility were examined weekly for 2-4 weeks (short), 6-8 weeks (medium), or 9-12 weeks (long). Then the obstruction was removed and bladder function followed up to 7 weeks. The groups were compared to animals receiving only obstruction or a sham operation. RESULTS: During obstruction the three de-obstruction groups and the obstruction group progressively lost bladder function. Flow rate remained stable, compliance decreased, pressure, contractility and DO increased. After de-obstruction the response in the three de-obstruction groups varied. In S, bladder pressure and compliance normalized, contractility initially increased then decreased towards high normal values, DO remained high normal and flow rate increased. In M, bladder pressure and DO decreased to above average normal levels. Compliance improved but did not normalize. Contractility initially stabilized, then decreased to just above the normal range. Flow-rate increased. In L, bladder pressure and DO decreased to high normal. Compliance did not improve. Contractility decreased directly after de-obstruction, stabilizing at an above normal level, flow-rate increased. CONCLUSIONS: The potential for functional recovery decreases with increasing loss of bladder function. At all stages of bladder dysfunction, voiding pressure appears to normalize after de-obstruction. However, contractility remains high and compliance low. Such a bladder may be more vulnerable to new events of outflow obstruction than a low contractile, normal compliant bladder.

Abnormal urine flow in boys with distal hypospadias before and after correction.

PURPOSE: We established the urine flow rate and the effect of surgical correction on that rate in patients with hypospadias. MATERIALS AND METHODS: The urine flow rate, voided volume and residual urine were measured using an ultrasound flow probe and bladder scan in boys with distal hypospadias before operative correction in 42 with a mean age of 16 months, 3 and 9 months after operative correction in 28 and 11, respectively, and in a control group of 51 boys 0 to 3 years old (mean age 11 months). Long-term flow data were obtained retrospectively from the records of 63 patients with hypospadias 1 to 10 years after operation. RESULTS: Of the controls 37% had mainly intermittent and sometimes fractionated flows, 4% had a plateau phase flow and 59% had mainly bell-shaped flow curves. The average maximum flow rate +/- SD was 6.8 +/- 4.1 ml per second and maximum flow rate/voided volume was 0.26 +/- 0.11 l per second. Of the boys with distal hypospadias 76% produced intermittent flows (fractionated in the majority) before correction. After correction this percent decreased to 50%. The average maximum flow rate was 7.5 +/- 2.5 ml per second before correction, and 6.6 +/- 2.8 and 7.2 +/- 1.8 ml per second 3 and 9 months after operation, respectively. Average maximum flow rate/voided volume was 0.22 +/- 0.12 l per second before, and 0.16 +/- 0.09 and 0.16 +/- 0.09 l per second 3 and 9 months after operation, respectively. In the long-term group maximum flow rate/voided volume was 0.13 +/- 0.11 l per second. The number of patients voiding with a plateau phase increased from 6% before to 13% and 17% after correction, respectively. An obstructive pattern was also observed in 41% of the long-term followup group. CONCLUSIONS: An intermittent flow pattern is common in 0 to 3-year-old boys. It appears to be more common and more pronounced or fractionated in boys with distal hypospadias at the same ages. In relation to voided volume patients with hypospadias already produce an abnormally low urine flow rate before correction and even more so thereafter in the short and intermediate term. The corrective procedure increases the occurrence of flows with an obstructive pattern.

Raman spectroscopic analysis identifies testicular microlithiasis as intratubular hydroxyapatite.

PURPOSE: As diagnosed by ultrasonography, testicular microlithiasis is associated with various benign and malignant conditions. The molecular constitution of these microliths is largely unknown. Raman spectroscopy provides detailed in situ information about the molecular composition of tissues and to our knowledge it has not been applied to gonadal microliths. We analyzed the molecular composition of gonadal microlithiasis and its surrounding region using Raman spectroscopy in malignant and benign conditions. MATERIALS AND METHODS: Multiple microliths from 6 independent samples diagnosed with gonadal microlithiasis by ultrasound and histologically confirmed were investigated by Raman spectroscopy. The samples included 4 testicular parenchyma samples adjacent to a germ cell tumor (4 seminomas), a gonadoblastoma of a dysgenetic gonad and testicular biopsy of a subfertile male without malignancy. RESULTS: Raman spectroscopic mapping demonstrated that testicular microliths were located within the seminiferous tubule. Glycogen surrounded all microliths in the samples associated with germ cell neoplasm but not in the benign case. The molecular composition of the 26 microliths in all 6 conditions was pure hydroxyapatite. CONCLUSIONS: Microliths in the testis are located in the seminiferous tubules and composed of hydroxyapatite. In cases of germ cell neoplasm they co-localize with glycogen deposits.

Identification of bladder wall layers by Raman spectroscopy.

PURPOSE: We explored the applicability of Raman spectroscopy to in situ investigation of bladder wall tissue. MATERIALS AND METHODS: Bladder wall tissue was obtained from a guinea pig model and frozen sections were used for Raman spectroscopic investigations. From each section 500 to 700 spectra were obtained in a 2-dimensional grid spanning the urothelium, lamina propria and muscle layer. The data set of spectra was subdivided into groups of similar spectra by a cluster analysis algorithm. With each group assigned a different color Raman maps of frozen sections were constructed based on group membership of measured spectra. These maps were then compared with histological and histochemical data obtained from hematoxylin and eosin and immunohistochemical staining for collagen I and III and for smooth muscle actin to correlate Raman spectral features with bladder wall structure and molecular composition. RESULTS: Urothelium, lamina propria and muscle layers could be clearly distinguished based on Raman spectra. Lamina propria spectra were dominated by signal contributions of collagen and the smooth muscle layer showed strong signal contributions of actin. The urothelium had a relatively strong lipid signal contribution. CONCLUSIONS: These results and the fact that Raman spectroscopy is rapidly evolving into a technology that can be applied in vivo by thin, flexible fiberoptic catheters indicate that prospects are good for in vivo analysis of the molecular composition of the normal and pathological bladder without biopsies.