Molecular genetic diagnosis of de novo and recurrent bladder cancer.

Abstract

Bladder cancer, the second most common urological tumor, is usually diagnosed by endoscopy and biopsy of the lower urinary tract. However, this procedure is expensive, can cause discomfort to the patient and is a source of infection. Commercially available diagnostic systems measure protein byproducts of bladder carcinoma in voided urine; their sensitivity is only between 60-80%. Polymerase chain reaction (PCR)-based microsatellite analysis of the urine sediment (MAUS) is a noninvasive, inexpensive and easily performed analytical method which was introduced in the de novo diagnosis and follow-up of bladder cancer. By utilizing the PCR with 20 polymorphic microsatellite markers on different chromosomes and separating PCR products by electrophoresis on 7% denaturing polyacrylamide-formamide-urea slab gels, a 91% diagnostic sensitivity could be achieved. In order to minimize costs and analysis time, the separation and detection of PCR products was carried out by capillary array electrophoresis and two-color fluorescent primer labeling/laser beam detection in another study. The accuracy of both methods was the same. In either detection system, MAUS is an accurate and promising tool in the noninvasive diagnosis of bladder cancer.