ABSTRACT
BACKGROUND AND AIM: Magnetic resonance urography (MRU) is considered to be the next step in uroradiology. This technique combines superb anatomical images and functional information in a single test. In this article, we aim to present the topic of MRU in children and how it has been implemented in Northern Greece so far. The purpose of this study is to demonstrate the potential of MRU in clinical practice. We focus both on the anatomical and the quantitative information this technique can offer. MATERIALS AND METHODS: MRU was applied in 25 children (ages from 3 to 11 years) diagnosed with different types of congenital malformations. T1 and T2 images were obtained for all patients. Dynamic, contrast-enhanced data were processed and signal intensity versus time curves were created for all patients from regions of interest (ROIs) selected around the kidneys in order to yield quantitative information regarding the kidneys function. RESULTS: From the slopes of these curves we were able to evaluate which kidneys were functional and from the corticomedullary cross-over point to determine whether the renal system was obstructed or not. CONCLUSION: In all 25 cases MRU was sufficient, if not superior to other imaging modalities, to establish a complete diagnosis.
ABSTRACT
Urinary tract infection is a common bacterial disease that presents during childhood and may lead to renal scarring. Several studies have shown a strong association between the angiotensin converting enzyme (ACE) deletion polymorphism and renal scarring in children with vesicoureteric reflux (VUR). The purpose of this study was to investigate the possible correlation between the ACE deletion polymorphism and renal scarring in 186 children with urinary tract infection (UTI), of whom 90 were renal scar positive and 96 were renal scar negative. The control group consisted of 129 children with no UTI. Renal scars were diagnosed by means of (99m)Tc-dimercapto-succinic acid scans, and ACE genotypes were determined as II, ID, and DD by PCR analyses. The ACE genotype distribution was 10% II, 67% ID, and 23% DD in the renal scar-positive group, 18% IotaIota, 42% ID, and 40% DD in the renal scar-negative group, and 22% II, 47% ID, and 31% DD in the control group. No correlation was found between the DD genotype and renal scar formation in children with UTI. The same results were obtained following strafication of the patients by VUR and age of the first urinary tract infection. In conclusion, the results of this study suggest that the DD genotype is not an independent risk factor for renal scarring in children with UTI.