whewellite and Urolithiasis

This study describes the primary characteristics of the selected kidney stones surgically removed from the patients at the Mersin University Hospital in the southern Turkey and interprets their formation via petrographic, geochemical, XRD, SEM-EDX, and ICP-MS/OES analyses. The analytical results revealed that the kidney stones are composed of the minerals whewellite, struvite, hydroxyapatite, and uric acid alone or in different combinations. The samples occur in staghorn, bean-shaped composite, and individual rounded particle shapes, which are controlled by the shape of the nucleus and the site of stone formation. The cross-section of the samples shows concentric growth layers due to variations in saturation, characterizing the metastable phase. Kidney stone formation includes two main stages: (i) nucleation and (ii) aggregation and/or growth. Nucleation was either Randall plaque of hydroxyapatite in tissue on the surface of the papilla or a coating of whewellite on the plaque, or crystallization as free particles in the urine. Subsequently, aggregation or growth occurs by precipitation of stone-forming materials around the plaque or coating carried into the urine, or around the nucleus formed in situ in the urine. Urinary supersaturation is the main driving force of crystallization processes; and is controlled by many factors including bacterially induced supersaturation.

Topics: Humans; Hydroxyapatites; Kidney Calculi; Turkey; Urolithiasis

Incidence of pediatric urolithiasis is decreasing in most developing countries where endemic bladder stones are less prevalent than in the past years. In parallel, stone composition has changed. Only few data are available in North Africa, except for Tunisia. We report stone composition in the Moroccan pediatric population.. Composition of 432 stones from children (302 boys, 130 girls) was determined by infrared spectroscopy. The samples were collected during the period 1999-2016. Stone morphology, which is an important aspect for etiology was determined by examination of each stone under a stereomicroscope. Stone composition was compared to patients' age and gender.. The global male-to-female ratio was 2.32. Regarding stone composition, calcium oxalate was the main component in 51.6% of the stones, followed by struvite (18.1%), ammonium urate (9.5%) and carbapatite (9%). Significant differences were found between males and females: calcium oxalate accounted for 72.3% of stones in girls and 42.7% in boys (P<10. This is the largest series of pediatric stones in Morocco studied by infrared analysis and morphological examination.. 3.

Topics: Adolescent; Age Factors; Apatites; Calcium Oxalate; Child; Child, Preschool; Female; Humans; Incidence; Infant; Male; Morocco; Sex Factors; Spectrophotometry, Infrared; Struvite; Urinary Calculi; Urolithiasis

The outpatient forensic aftercare department of the Charité Berlin treated 32 paraphilic sex offenders with GnRH analogues within the past 5 years. Out of those patients, three men suffered from urolithiasis and were in need of treatment. All 3 patients had previously developed osteopenia/osteoporosis while on antiandrogen treatment.This article describes these 3 cases and suggests an intense consideration of the possible occurrence of urolithiasis in sex offenders on antiandrogen treatment.

Topics: Adult; Calcium Oxalate; Cyproterone Acetate; Delayed-Action Preparations; Follow-Up Studies; Gonadotropin-Releasing Hormone; Humans; Kidney Calculi; Leuprolide; Long-Term Care; Male; Middle Aged; Paraphilic Disorders; Recurrence; Triptorelin Pamoate; Ureteral Calculi; Urolithiasis

Stone analysis is incompletely done in many clinical centers. Identification of the stone component is essential for deciding future prophylaxis. X-ray diffraction, Fourier transform infrared spectroscopy, and scanning electron microscopy (SEM) still remains a distant dream for routine hospital work. It is in this context that optical microscopy is suggested as an alternate procedure. The objective of this article was to assess the utility of an optical microscope which gives magnification of up to 40x and gives clear picture of the surface of the stones. In order to authenticate the morphological analysis of urinary stones, SEM and elemental distribution analysis were performed. A total of 250 urinary stones of different compositions were collected from stone clinic, photographed, observed under an optical microscope, and optical photographs were taken at different angles. Twenty-five representative samples among these were gold sputtered to make them conductive and were fed into the SEM machine. Photographs of the samples were taken at different angles at magnifications up to 4,000. Elemental distribution analysis (EDAX) was done to confirm the composition. The observations of the two studies were compared. The different appearances of the stones under optical illuminated microscopy were mostly standardized appearances, namely bosselations of pure whewellite, spiculations of weddellite, bright yellow colored appearance of uric acid, and dirty white amorphous appearance of phosphates. SEM and EDAX gave clearer pictures and gave added confirmation of the stone composition. From the references thus obtained, it was possible to confirm the composition by studying the optical microscopic pictures. Higher magnification capacity of the SEM and the EDAX patterns are useful to give reference support for performing optical microscopy work. After standardization, routine analysis can be performed with optical microscopy. The advantage of the optical microscope is that, it is easy to use and samples can be analyzed in natural color.

Topics: Calcium Oxalate; Calcium Phosphates; Chemistry Techniques, Analytical; Humans; Microscopy; Microscopy, Electron, Scanning; Uric Acid; Urinary Calculi; Urolithiasis