Clinical and biochemical patterns of presentation in monolateral and bilateral calcium nephrolithiasis.

To investigate patterns of monolateral and bilateral nephrolithiasis, we enrolled 196 patients with idiopathic calcium stone disease (ICaSD) and 36 with proven primary hyperparathyroidism (PHP). Monolateral disease occurred in 45 subjects with ICaSD and 3 with PHP. All had had three or more stone events. They were studied for a number of clinical and biochemical parameters. The expected prevalence of monolateral stone disease was calculated according to the binomial distribution of random events. Whereas the observed and expected prevalence of monolateral nephrolithiasis did not differ in PHP, the distribution did not follow a chance pattern in ICaSD, since monolateral disease was still frequent among patient with more than 6 episodes. To find out whether monolateral and bilateral ICaSD had distinct pathogenic mechanisms the two groups were compared for clinical and biochemical patterns: no differences emerged concerning metabolic derangements, urine saturation and diet-related biochemistries. Bilateral stone-formers had a higher recurrence rate, but a similar number of stone-operations or ESWL. In 81 of 151 bilateral idiopathic stone-formers in which we were able to assess the exact number of stone events in left and right kidney, the distribution of stones between kidneys did not differ from the binomial distribution. In conclusion, while PHP-associated nephrolithiasis presents predictable patterns, ICaSD comprises a subset in which the disease occurs monolaterally. These forms cannot be distinguished from bilateral forms with common clinical features or routine biochemistries.

[Wegener's granulomatosis. Diagnosis and follow-up of 7 cases]. / Granulomatosi di Wegener. Diagnosi e follow-up di 7 casi.

Wegener's granulomatosis (WG) is a rare small vessels necrotizing and granulomatous systemic vasculitis which usually affects the respiratory-tract and the kidneys. Diagnosis is often difficult, but has become easier with antineutrophil cytoplasmic antibodies (ANCA) detection that may justify a more aggressive biopsy policy also in the elderly. Classic treatment with steroids and oral cyclophosphamide (CY) has proven to be of benefit, but side-effects are severe and frequent and the search for less toxic therapeutic schemes should be encouraged. We treated with intravenous pulses of CY (1 g/m2 monthly for 6 months, every two months for the following 6 and quarterly for another year) 5 of 7 patients with WG recently admitted to our institution. We obtained a quick, complete response in 4 of these patients, with no side effects, nor relapses, after a mean follow-up of 17 months. The only patient who did not respond was identified soon after the beginning of the treatment because of a poor reduction of ESR and could be shifted to oral administration of CY successfully. From our still limited experience CY intravenous pulses have proven to be safe and effective enough to advice its use as the first-choice treatment for WG.

Citrate in urine determined with a new citrate lyase method.

An enzyme-spectrophotometric method to determine citrate in biological fluids is proposed, based on citrate lyase-catalyzed and phenylhydrazine reactions. The enzyme converts citrate into oxaloacetate, which, in the presence of phenylhydrazine, is transformed into the corresponding phenylhydrazone. The ultraviolet-absorbing product is determined by absorbance measurement at 330 nm. The method is more precise and twice as sensitive as the traditional citrate lyase method and, because it does not require the use of additional enzymes and coenzymes, is cheaper and simpler. Mean analytical recovery of citrate averaged 100.7% +/- 2.2%, imprecision (CV) of the assay for citrate at 0.96 mmol/L (urine) was 2.0%, and the lower limit of quantification was 0.08 mmol/L. Results correlated well with those by both ion-chromatographic and traditional citrate lyase methods.

Bony content of oxalate in patients with primary hyperoxaluria or oxalosis-unrelated renal failure.

Oxalate retention occurs in end-stage renal failure. Regular dialysis treatment does not prevent progressive accumulation of oxalate in cases of ESRF due to primary hyperoxaluria (PH), whereas such accumulation seldom seems to occur in oxalosis-unrelated ESRF. To elucidate this issue we have measured the bony content of oxalate on biopsies of the iliac crest taken from 32 uremic patients, 7 of them with ESRF associated with PH1 (6 cases) or PH2 (1 case). Ten subjects with normal renal function and no evidence of metabolic bone disease were taken as controls. Only trace amounts levels of oxalate were detected in normal subjects and oxalate to phosphate ratio was below 3:10,000. Non-PH dialyzed patients exhibited fivefold increases in oxalate levels, which rose to 5.1 +/- 3.6 mumol/g bony tissue. Calcium oxalate was estimated to represent 0.18% of the hydroxyapatite content of bone. Oxalate amounts were neither related to pre-dialysis plasma levels of oxalate, nor with duration of dialysis treatment, suggesting that accumulation was not progressive disorder. Oxalate levels were slightly higher in patients with a low turnover osteodystrophy compared to those with a high turnover pattern. Dialyzed patients with PH had remarkable increases in oxalate levels, which ranged between 14.8 and 907 mumol/g bony tissue. Oxalate deposition appeared to be progressive in that oxalate levels were significantly related to time on dialysis. In three patients calcium oxalate was a significant fraction of the mineralized bone. The occurrence of calcium oxalate crystals affected the histomorphometric patterns, that were featured by an increase in resorptive areas and a decrease in bone formation rate.(ABSTRACT TRUNCATED AT 250 WORDS)

Detection of primary hyperoxaluria type 2 (L-glyceric aciduria) in patients with maintained renal function or end-stage renal failure.

Primary hyperoxaluria (PH) type 1 and type 2 are autosomal recessive defects of oxalate metabolism resulting from glyoxylate accumulation which occurs by two distinct pathways. PH1 is associated to glycolic aciduria; PH2 to L-glyceric aciduria. Because hyperoxaluria leads to nephrolithiasis or nephrocalcinosis in both, they can be differentiated only through detection of the associated acidurias. However, glycolate and L-glycerate assays are not widely available and, in the setting of ESRF, diagnosis is hampered by a number of misleading events. At any stage of the disease diagnosis is crucial because there are differences between the two forms in clinical behaviour, long-term prognosis, and treatment. In this paper we outline diagnostic criteria for identification of PH2 in two patients, one with maintained renal function and one with ESRF on CPD, based on the use of a novel HPLC assay of L-glycerate in different body fluids. With the routine application of this procedure PH2 has been identified in two of 23 patients fulfilling criteria for diagnosis of PH. This suggests that the type 2 variant of PH may occur more frequently than so far suspected, and should be tested for even in the setting of ESRF.

The clinical significance of assessment of serum calcium oxalate saturation in the hyperoxaluria syndromes.

Estimating calcium oxalate saturation (beta CaOx) in body fluids is proposed as a simple and reproducible procedure to assess the risk of systemic oxalosis in several clinical conditions associated with oxalate retention. beta CaOx was computerized from the measured concentrations of main serum ions. Accurate assay of serum oxalate was crucial for reliability of beta CaOx estimates. However, beta CaOx also depended upon changes of calcium and magnesium concentrations. Patients with end-stage renal failure (ESRF) due to primary or enteric hyperoxaluria had beta CaOx greater than saturation, whereas this happened in only 10 of 25 and two of 24 of those with oxalosis-unrelated ESRF. Bony content of oxalate measured in some of these patients was consistent with these results. In patients with maintained renal function beta CaOx was inversely related to glomerular filtration rate, but the slope was steeper in patients with than in those without hyperoxaluria and beta CaOx reached saturation at earlier stages of renal insufficiency.

[Bartter's syndrome in children and adults. Study of 6 cases]. / La sindrome di Bartter nel bambino e nell'adulto. Studio di 6 casi.

Six patients (3 children and 3 adults) with the clinical and biochemical features of Bartter's syndrome are presented. Pediatric cases included a more severe form, in one patient, with physical and mental retardation, hypercalciuria and nephrocalcinosis, and a less severe one, including two patients, with milder clinical features, low calcium and high magnesium excretion and hypomagnesiemia. Adult patients were affected by either the mild congenital form (case n. 4) or the acquired variety (cases n.5 and 6). Tubular function was investigated in the 3 adults by assessing clearance measurements during maximal diuresis. There was a defective fractional distal solute reabsorption (FDR) ranging between 0.52 and 0.60. This was well below the results obtained in one patient with psychogenous vomiting (FDR 0.94) and comparable to those in two patients with interstitial nephropathies caused by vesico-ureteral reflux (FDR 0.63 and 0.67 respectively). We concluded that: 1) the etiopathogenetic spectrum of Bartter's syndrome corresponds to different clinical presentation (mild, heavy, congenital or acquired varieties), and alterations in mineral and electrolyte renal handling; 2) reduction in FDR is a feature neither essential nor exclusive of this syndrome.

Assay of plasma oxalate with soluble oxalate oxidase.

We use oxalate oxidase from barley seedlings for the colorimetric determination of oxalate in plasma. The oxalate is converted to hydrogen peroxide, which, in the presence of peroxidase, is detected by a Trinder-like chromogenic system. Optimization of the assay, including deproteinization and elimination of interferences from reducing substrates, is described. Ascorbate additions (200 mumol/L) did not affect oxalate concentration in plasma, even after long frozen storage. Mean analytical recovery of oxalate averaged 102% +/- 6.9%, imprecision (CV) at 2.0 mumol/L was 7.2%, and the lower limit of quantification (CV = 20%) was 0.6 mumol/L. Results correlated well with those by chromatography (r = 0.999, Sy/x = 0.29 mumol/L, n = 32, range for x, y = 0-140 mumol/L). Plasma oxalate concentrations measured in 32 healthy subjects ranged from 0.6 to 2.9 mumol/L (mean 1.28, SD 0.71 mumol/L), which agrees with those measurable by using indirect radioisotopic dilution methods. Patients with primary hyperoxaluria and chronic renal failure exhibited markedly greater plasma concentrations of oxalate.

[Renal damage in rheumatoid arthritis]. / Il danno renale in corso di artrite reumatoide.

Renal damage is not uncommon in rheumatoid arthritis, but the causative role of the disease per se is not well defined yet. In this paper the updated literature data are reported and our own experience as well. In particular, we describe renal syndromes associated with non-steroidal antiinflammatory drugs, remission-inducing agents (gold and penicillamine) and cytotoxic drugs, secondary amyloidosis, systemic rheumatoid vasculitis, glomerular and tubulo-interstitial nephritis not related to drug therapy.

Effects of oral and intravenous calcitriol on serum calcium oxalate saturation in dialysis patients.

1. To determine whether the multiple changes in the blood chemistry profile induced by calcitriol may be conducive to secondary systemic oxalosis we have studied nine patients on regular dialysis treatment under three different regimens: (1) oral calcitriol, 0.25 microgram/daily for at least 6 months. (2) off calcitriol, a 1-month withdrawal of the drug, taken as the baseline study period; (3) intravenous calcitriol, 1 microgram three times weekly at the end of dialysis, with tests performed at 1 and 3 months from initiation. 2. Serum concentrations were measured pre- and post-dialysis at the end of each study period. The whole dialysate was used for the determination of the overall calcium and oxalate removal by dialysis. The degree of saturation with calcium oxalate monohydrate was estimated by a computer program. Serum calcitriol concentrations were also assessed. 3. Total and ionized serum calcium did not change on average, although mild hypercalcaemia developed in some patients on intravenous calcitriol. There was an increase in plasma level of oxalate during both oral and intravenous calcitriol treatment, but this was less pronounced during intravenous therapy. Removal of oxalate by dialysis was also greater in patients on oral calcitriol. 4. These increases were probably originated from intestinal absorption and secondary to hyperabsorption of dietary calcium. Consequently, the degree of saturation with calcium oxalate before dialysis rose during calcitriol treatment, irrespective of the route of administration. 5. These results emphasize that, in addition to soft tissue calcification due to calcium phosphates, ectopic calcium oxalate crystallization must also be viewed as a potential risk associated with long-term administration of calcitriol.

High-performance liquid chromatographic microassay for L-glutamate:glyoxylate aminotransferase activity in human liver. Application in primary hyperoxaluria type 1.

A rapid and sensitive liquid chromatographic technique to determine L-glutamate:glyoxylate and aminotransferase (EC 2.6.1.4) activity in human liver is described. Homogenised tissue was incubated for 60 min in the presence of substrates and the 2-oxoglutarate generated was converted into the corresponding phenylhydrazone which was determined using reversed-phase high-performance liquid chromatography. The procedure allowed the detection of the enzyme activity expressed by 7.5 micrograms of liver protein, it was more sensitive and less time-consuming than the spectrophotometric procedure previously used. No significant differences were found between normal controls and patients with primary hyperoxaluria. In an 8-month-infant with primary hyperoxaluria type 1, the enzyme activity was reduced to 16% of the average control values.

Determinants of oxalate balance in patients on chronic peritoneal dialysis.

We assessed plasma levels and removal rates of oxalate in 24 patients on chronic peritoneal dialysis (CPD) for oxalosis-unrelated renal failure. The ion-chromatographic (IC) measurements of oxalate in plasma, dialysate, and urine (in seven patients with residual renal function) were used to calculate peritoneal and renal clearances of oxalate. The serum state of saturation with calcium oxalate was calculated by means of a computer-based model system. Patient data were compared with those from 19 healthy individuals. Peritoneal clearance of oxalate was 6.3 +/- 4.7 mL/min, ie, 8% of the normal renal clearance. As a result, both plasma oxalate and calcium oxalate saturation were higher than in controls and did not overlap. Plasma was supersaturated with calcium oxalate in only two of 24 patients (8%). Removal of oxalate by dialysis was related to the amount of fluid infused. Overall removal of oxalate (dialysate plus urine) was similar to 24-hour excretion of normal subjects and was taken as a measure of its generation. Oxalate generation rate was dependent on protein (whole and animal) intake, but not on caloric intake or pyridoxine status. Pyridoxine supplementation, 75 and 300 mg daily for 1 months, was not effective in reducing plasma levels or generation rates of oxalate. Residual renal function had a minor influence on oxalate patterns. We conclude that current programs are adequate to maintain oxalate balance in patients on CPD under basic conditions.

Ion-chromatographic determination of plasma oxalate reexamined.

This new procedure for determining oxalic acid in plasma is based on sample deproteinization with hydrochloric acid and acetonitrile and subsequent ion-chromatographic assay of the neutralized supernate. Sample pretreatment produces very clean samples, which ensures long column life. Mean analytical recovery of oxalate (5.0-10.0 mumol/L) added to plasma samples averaged 98.6 +/- 6.2%; imprecision (CV) was 5.2% (at 2.2 mumol/L) and the detection limit was 0.5 mumol/L at a signal-to-noise ratio of 5:1. Ascorbate to oxalate conversion was < 0.2%, indicating that the procedure is free from ascorbate interference. Plasma oxalate concentrations, measured in samples from 31 healthy persons, ranged from 0.8 to 3.4 mumol/L (mean 1.89, SD 0.75 mumol/L), which agrees with results from indirect radioisotopic dilution methods.

Thresholds of serum calcium oxalate supersaturation in relation to renal function in patients with or without primary hyperoxaluria.

Systemic oxalosis is a constant feature in patients with primary hyperoxaluria type 1 (PH1) and chronic renal failure (CRF) and is not prevented by regular dialysis (RDT), because removal cannot keep up with retention and overproduction of oxalate. These patients are candidates to kidney and/or liver transplantation, which should be ideally planned prior to the development of oxalosis. However, methods to detect the presence and extent of oxalosis are invasive and poorly reproducible, and only indirect approaches are feasible. Because supersaturation of body fluids is an essential condition for oxalotic deposits to form, we have assessed serum calcium oxalate saturation (beta CaOx) in 12 patients with PH1 and 26 with PH1-unrelated renal diseases and varying degrees of CRF. Nineteen healthy individuals were taken as controls. beta CaOx was closely dependent on oxalate serum levels. Serum oxalate and beta CaOx were increased in patients with CRF as compared to controls, and were inversely related to GFR, assessed as creatinine clearance. However, at any level of GFR, both were always greater in PH1 patients. From the slopes of the regression of beta CaOx over ClCr, saturation was predicted to be obtained at ClCr ranging 24-34 and 8-11 ml/min/1.73 m2 in PH1 and non-PH1 patients respectively. Based on the dependence of beta CaOx on oxalate, saturation was associated with serum oxalate between 44 and 46 mumol/l, irrespective of either the prevailing GFR or the underlying disease. These simple procedures represent a valuable non-invasive tool to define the risk of systemic oxalosis and may assist in timing of transplantation.

High-performance liquid chromatographic assay for L-glyceric acid in body fluids. Application in primary hyperoxaluria type 2.

We describe a liquid chromatographic technique to determine L-glycerate in body fluids. The method is based on the derivatisation of the L-glycerate by incubation with lactate dehydrogenase and nicotinamide-adenine dinucleotide in the presence of phenylhydrazine. Oxidation of L-glycerate forms beta-hydroxypyruvate which is converted in turn into the related phenylhydrazone. The UV-absorbing derivative is determined using reversed-phase high performance liquid chromatography. The sensitivity was 5 mumol/l and 50 microliters of sample were required. The imprecision relative standard deviation was 4.5% and the recovery was 96.5 +/- 6.8% for L-glycerate in plasma. L-Glycerate concentrations in urine and plasma were less than 5 mumol/l in both normal individuals and patients with glycolic aciduria. In a patient with systemic oxalosis and normal plasma glycolate, plasma L-glyceric acid was 887 mumol/l.

Plasma and urine glycolate assays for differentiating the hyperoxaluria syndromes.

To differentiate hyperoxaluria syndromes we measured plasma and urine glycolate by a novel high performance liquid chromatographic procedure. Mean glycolate level was 7.9 +/- 2.4 mumol./l. in plasma and 422 +/- 137 mumol./24 hours in urine from 19 control subjects. Renal clearance was about 50% the glomerular filtration rate irrespective of the underlying disease. There was close correlation between glycolate and oxalate in plasma. Plasma glycolate was normal in all but 8 patients who had primary hyperoxaluria 1. Plasma assay detected the disease more efficiently than urine assay. Pyridoxine decreased oxalate biosynthesis in 2 of the 4 patients treated with it and glycolate assay confirmed this behavior. Glycolate excretion was significantly high in 3 of 8 patients of primary hyperoxaluria 1 patients. Idiopathic stone formers had mild increases in glycolate excretion but this was not related with oxalate excretion. Glycolate levels were normal in 5 patients with enteric hyperoxaluria. We conclude that glycolate assay is essential for identifying patients with primary hyperoxaluria 1 and may represent a valuable tool for differentiating hyperoxaluria.

High-performance liquid chromatographic microassay for L-alanine:glyoxylate aminotransferase activity in human liver.

We examine the suitability of a rapid and sensitive liquid chromatographic technique to determine L-alanine:glyoxylate aminotransferase (AGT) activity in human liver. Homogenised tissue was incubated for 30 min in the presence of substrates and the generated pyruvate was converted into the corresponding phenylhydrazone which was determined using reversed-phase high-performance liquid chromatography (HPLC). The procedure allowed the detection of the enzyme activity expressed by 10 micrograms of liver protein and was rapid enough resulting more sensitive and less time-consuming than the previous colorimetric one. We found that AGT activity in two hyperoxaluria type 1 patients was reduced as compared with controls. Also, cirrhotic patients had very low enzyme activities, even in the absence of detectable disorders of oxalate metabolism and this was ascribed to abnormal liver morphology. This may represent a misleading drawback if diagnosis of type 1 primary hyperoxaluria (PH1) uniquely relies on AGT assay.

Oxalate balance studies in patients on hemodialysis for type I primary hyperoxaluria.

Primary hyperoxaluria type I (PH1) always leads to end-stage renal failure (ESRF) due to deposition of calcium oxalate in the kidney. Regular dialysis therapy (RDT) can not overcome the excess production of oxalate, hence, systemic oxalate deposition occurs. The extent of tissue deposition and the rate at which oxalate accumulates influence the quality of life and survival of the patients. Therefore, an estimate of the oxalate balance needs to be made for patients on RDT. In this study, we suggest a simple model by which some of the main parameters of oxalate turnover can be assessed without using radioactive materials. Levels of oxalate, glycolate, and urea, and degrees of calcium oxalate saturation, were assessed on plasma ultrafiltrates from two patients with PH1, sampled before, at the end of a dialysis session, and over the entire interdialytic interval. In patients with PH1, oxalate increased linearly during the early phases and then the curve flattened at a concentration corresponding to approximately threefold saturation. The initial phase of the relationship was used to estimate generation rate of oxalate. The delayed phase was ascribed to the deposition of newly generated oxalate out of its miscible pool. Conversely, the relationship for glycolate and urea remained linear. This was also different from the values obtained in four patients with oxalosis-unrelated ESRF, whose oxalate levels increased linearly over the entire interdialytic interval. In the two patients with PH1, the overall oxalate generation was assessed at 4 to 7 mmol/d. The difference between generation and dialysis removal indicated that tissue deposition was greater than 50 mumol/kg body weight/d.(ABSTRACT TRUNCATED AT 250 WORDS)