Combined Liver-Kidney Transplantation for Primary Hyperoxaluria Type 2: A Case Report.

Combined liver/kidney transplant is the preferred transplant option for most patients with primary hyperoxaluria type 1 (PH1) since orthotopic liver transplantation replaces the deficient liver-specific AGT enzyme, thus restoring normal metabolic oxalate production. However, primary hyperoxaluria type 2 (PH2) is caused by deficient glyoxylate reductase/hydroxypyruvate reductase (GRHPR), and this enzyme is widely distributed throughout the body. Though the relative abundance and activity of GRHPR in various tissues is not clear, some evidence suggests that the majority of enzyme activity may indeed reside within the liver. Thus the effectiveness of liver transplantation in correcting this metabolic disorder has not been demonstrated. Here we report a case of 44-year-old man with PH2, frequent stone events, and end-stage renal disease; he received a combined liver/kidney transplant. Although requiring confirmation in additional cases, the normalization of plasma oxalate, urine oxalate, and urine glycerate levels observed in this patient within a month of the transplant that remain reduced at the most recent follow-up at 13 months suggests that correction of the GRHPR deficiency in PH2 can be achieved by liver transplantation.

Sustained pyridoxine response in primary hyperoxaluria type 1 recipients of kidney alone transplant.

Combined liver kidney transplant is the preferred transplant option for most patients with primary hyperoxaluria type 1 (PH1) given that it removes the hepatic source of oxalate production and improves renal allograft survival. However, PH1 patients homozygous for the G170R mutation can develop normal urine oxalate levels with pyridoxine therapy and may be candidates for kidney alone transplant (KTx). We examined the efficacy of pyridoxine therapy following KTx in five patients homozygous for G170R transplanted between September 1999 and July 2013. All patients were maintained on pyridoxine posttransplant. Median age at transplant was 39 years (range 33-67 years). Median follow-up posttransplant was 8.5 years (range 0.2-13.9 years). At the end of follow-up, four grafts were functioning. One graft failed 13.9 years posttransplant due to recurrent oxalate nephropathy following an acute medical illness. After tissue oxalate stores had cleared, posttransplant urine oxalate levels were <0.5 mmol/24 h the majority of times checked. Calcium oxalate crystals were noted in only 3/13 allograft biopsies. This series suggests that a subgroup of PH1 patients demonstrate sustained response to pyridoxine therapy following KTx. Therefore, pyridoxine combined with KTx should be considered for PH1 patients with a homozygous G170R mutation.

Transplantation outcomes in primary hyperoxaluria.

Optimal transplantation strategies are uncertain in primary hyperoxaluria (PH) due to potential for recurrent oxalosis. Outcomes of different transplantation approaches were compared using life-table methods to determine kidney graft survival among 203 patients in the International Primary Hyperoxaluria Registry. From 1976-2009, 84 kidney alone (K) and combined kidney and liver (K + L) transplants were performed in 58 patients. Among 58 first kidney transplants (32 K, 26 K + L), 1-, 3- and 5-year kidney graft survival was 82%, 68% and 49%. Renal graft loss occurred in 26 first transplants due to oxalosis in ten, chronic allograft nephropathy in six, rejection in five and other causes in five. Delay in PH diagnosis until after transplant favored early graft loss (p = 0.07). K + L had better kidney graft outcomes than K with death-censored graft survival 95% versus 56% at 3 years (p = 0.011). Among 29 year 2000-09 first transplants (24 K + L), 84% were functioning at 3 years compared to 55% of earlier transplants (p = 0.05). At 6.8 years after transplantation, 46 of 58 patients are living (43 with functioning grafts). Outcomes of transplantation in PH have improved over time, with recent K + L transplantation highly successful. Recurrent oxalosis accounted for a minority of kidney graft losses.

Hyperoxaluric nephrolithiasis is a complication of Roux-en-Y gastric bypass surgery.

Roux-en-Y bypass surgery is the most common bariatric procedure currently performed in the United States for medically complicated obesity. Although this leads to a marked and sustained weight loss, we have identified an increasing number of patients with episodes of nephrolithiasis afterwards. We describe a case series of 60 patients seen at Mayo Clinic-Rochester that developed nephrolithiasis after Roux-en-Y gastric bypass (RYGB), including a subset of 31 patients who had undergone metabolic evaluation in the Mayo Stone Clinic. The mean body mass index of the patients before procedure was 57 kg/m(2) with a mean decrease of 20 kg/m(2) at the time of the stone event, which averaged 2.2 years post-procedure. When analyzed, calcium oxalate stones were found in 19 and mixed calcium oxalate/uric acid stones in two patients. Hyperoxaluria was a prevalent factor even in patients without a prior history of nephrolithiasis, and usually presented more than 6 months after the procedure. Calcium oxalate supersaturation, however, was equally high in patients less than 6 months post-procedure due to lower urine volumes. In a small random sampling of patients undergoing this bypass procedure, hyperoxaluria was rare preoperatively but common 12 months after surgery. We conclude that hyperoxaluria is a potential complicating factor of RYGB surgery manifested as a risk for calcium oxalate stones.

Treatment of the primary hyperoxalurias: a new chapter.

Despite advances in the enzymology, molecular genetics, and clinical knowledge of the primary hyperoxalurias, few treatments are available. Oxalobacter formigenes is a promising new therapy with potential to induce secretion of oxalate into the intestinal lumen, where it can be degraded by the bacteria.

Combined liver-kidney and kidney-alone transplantation in primary hyperoxaluria.

Combined liver-kidney and kidney-only transplantation outcomes in primary hyperoxaluria (PH) are described. Strategies for the selection of type and timing of transplantation and pretransplantation and posttransplantation management are reviewed. Records were reviewed for 16 patients with PH who received 9 liver-kidney and 10 kidney-only transplants. Plasma oxalate values declined from 61 +/- 42 micromol/L pretransplantation to 9 +/- 6 micromol/L 1 month after transplantation in liver-kidney transplant recipients and 92 +/- 19 to 9 +/- 5 micromol/L in kidney-only transplant recipients. In most liver-kidney transplant recipients, hyperoxaluria persisted for 6 to 18 months after transplantation. Follow-up was 3.5 +/- 4.1 years in liver-kidney and 4.5 +/- 6.3 years in kidney-alone transplant recipients. Patient survival rates were 78% for liver-kidney and 89% for kidney-only transplant recipients. No hepatic allografts were lost. Three of 9 liver-kidney and 6 of 10 kidney-alone transplants lost renal allograft function. In those with functioning kidneys, renal clearance was 45.1 +/- 19.5 mL/min/1.73 m(2) in liver-kidney transplant recipients and 49.5 +/- 26.1 mL/min/1.73 m(2) in kidney-only transplant recipients at last follow-up. Kaplan-Meier 1-, 2-, 3-, and 5-year renal allograft survival rates for patients undergoing transplantation after 1984 were 78%, 78%, 52%, and 52% in liver-kidney transplant recipients and 86%, 71%, 54%, and 36% in kidney-only transplant recipients. Simultaneous grafting of liver and kidney after the development of renal insufficiency is recommended for the majority of patients with PH type I (PH-I). Kidney-alone transplantation is recommended for those with pyridoxine-responsive type I disease because pharmacological therapy allows favorable management of oxalate production in this situation. Kidney-alone transplantation also is recommended for PH type II (PH-II). This disease is less severe than PH-I, and it is currently unknown whether liver transplantation will correct the metabolic defect responsible for PH-II.

Two cases of non-O157:H7 Escherichia coli hemolytic uremic syndrome caused by urinary tract infection.

Escherichia coli serotype O157:H7 is a leading cause of diarrhea and hemolytic uremic syndrome (HUS). Because of the limitations of current diagnostic techniques, the prevalence of non-O157:H7 Shiga toxin-producing E coli strains is not known. We describe two patients with HUS in whom no E coli O157:H7 was demonstrable in stool cultures. On culture of the urine, the first patient was found to have E coli O113:H21 strain, and the second patient had E coli O6:H1 serotype. Shiga toxin production (stx2) by the O113:H21 isolate was confirmed. The first patient required 15 days of peritoneal dialysis and subsequently recovered renal function. At last follow-up, serum creatinine was 0.9 mg/dL. The second patient had preservation of renal function throughout the acute illness with serum creatinine of 0.5 mg/dL. The clinical presentation, bacteriology, course, and outcome as well as epidemiologic implications of the increasing number of patients with E coli urinary tract infections associated with HUS are discussed. These cases illustrate the need to investigate patients with nondiarrheal HUS for infection with Shiga toxin-producing E coli of the non-O157 strain variety.

Chronic renal failure secondary to oxalate nephropathy: a preventable complication after jejunoileal bypass.

Enteric hyperoxaluria is a commonly seen adverse event after the jejunoileal bypass procedure. The increased concentration of urinary oxalate predisposes bypass patients to various renal complications such as nephrolithiasis and oxalate nephropathy. If not diagnosed and appropriately treated, these complications can lead to irreversible renal damage. We describe 3 patients in whom severe renal complications developed with irreversible compromise of renal function after a jejunoileal bypass. Patients who undergo a jejunoileal bypass require lifelong follow-up with close monitoring of their renal function. Marked decline in renal function mandates prompt investigation and aggressive intervention, including reversal of the jejunoileal bypass if necessary. Chronic renal failure secondary to oxalate nephropathy is preventable and treatable but may require conversion of a jejunoileal bypass to a more current form of bypass.

Phenotypic expression of primary hyperoxaluria: comparative features of types I and II.

BACKGROUND: The primary hyperoxalurias are autosomal recessive disorders resulting from deficiency of hepatic alanine:glyoxylate aminotransferase (PHI) or D-glycerate dehydrogenase/glyoxylate reductase (PHII). Marked hyperoxaluria results in urolithiasis, renal failure, and systemic oxalosis. A direct comparison of PHI and PHII has not previously been available. METHODS: Twelve patients with PHI and eight patients with PHII with an initial creatinine clearance of greater than or equal to 50 mL/min/1.73 m2 underwent similar laboratory evaluation, clinical management, and follow-up. Diagnosis of PHI and PHII was made by hepatic enzyme analysis (N = 11), increased urinary excretion of glycolate or glycerate (N = 7), or complete pyridoxine responsiveness (N = 2). Six PHI and five PHII patients had measurements of calcium oxalate crystalluria, urine supersaturation, and urine inhibition of calcium oxalate crystal formation. RESULTS: PHI and PHII did not differ in age at the onset of symptoms, initial serum creatinine, or plasma oxalate concentration. Urine oxalate excretion rates were higher in PHI (2.19 +/- 0.61 mmol/1.73 m2/24 hours) than PHII (1.61 +/- 0.43, P = 0.04). Urine osmolality, calcium, citrate, and magnesium concentrations were lower in PHI than PHII (P = 0.001, P = 0.019, P = 0.0002, P = 0.03, respectively). Crystalluria scores and calcium oxalate inhibitory activity of the urine did not differ between PHI and PHII. Calcium oxalate supersaturation in the urine was less in PHI (7.3 +/- 1.9) compared with PHII (14.0 +/- 3.3, P = 0.002). During follow-up of 10.3 +/- 9. 6 years in PHI and 18.1 +/- 5.6 years in PHII, stone-forming activity and stone procedures were more frequent in PHI than PHII (P < 0.01 and P = 0.01, respectively). Four of 12 PHI compared with 0 of 8 PHII patients progressed to end-stage renal disease (P = 0.03). CONCLUSION: The severity of disease expression is greater in type I primary hyperoxaluria than in type II. The difference may be due to greater oxalate excretion and lower concentrations of urine citrate and magnesium in patients with PHI compared with PHII.

(L)-2-oxothiazolidine-4-carboxylate in the treatment of primary hyperoxaluria type 1.

OBJECTIVE: To evaluate the short-term efficacy of (l)-2-oxothiaolidine-4-carboxylate (OTZ, which reduces urinary oxalate excretion in normal subjects) in the treatment of primary hyperoxaluria type 1 (PH1) in a phase II study. PATIENTS AND METHODS: Two patients with PH1 received intravenous infusions of OTZ (100 mg/kg body weight for 2 h) given every 8 h for four doses. One patient also received a placebo treatment. Urine samples (24-h collections) were obtained before and during OTZ treatment and assayed for oxalate, citrate, creatinine, sulphate and pH. Daily blood samples were assayed for plasma oxalate and serum creatinine. RESULTS: Urinary oxalate excretion was unaffected by OTZ treatment. Plasma oxalate declined in both individuals with OTZ treatment, but the effect was small. Plasma cysteine was normal in one patient, rising from a mean (sd) of 36 (3.7) micromol/L before treatment to a peak of 141 micromol/L after OTZ, but was not detected in samples from the other patient. The ratio of oxalate to creatinine clearances was high in both patients, with mean values of 3.1 and 3.8. CONCLUSIONS: Treatment with OTZ did not lead to clinically significant changes in urinary oxalate excretion. The high clearance of oxalate in these patients suggests a substantial renal secretion of oxalate.

Evaluation and management of proteinuria and nephrotic syndrome in children: recommendations from a pediatric nephrology panel established at the National Kidney Foundation conference on proteinuria, albuminuria, risk, assessment, detection, and elimination (PARADE).

OBJECTIVE: The development of this review article evolved from a National Kidney Foundation consensus conference on recent advances in the importance of evaluating and treating proteinuria. From this conference, a series of recommendations for the evaluation of adults with proteinuria was published. Because specific pediatric aspects of the problem were outside the scope of the original National Kidney Foundation publication, an ad hoc committee of 6 pediatric nephrologists who were active participants in the National Kidney Foundation conference was established to provide primary care physicians with a concise, up-to-date reference on this subject. METHODS: The recommendations that are given represent the consensus opinions of the authors. These are based on data from controlled studies in children when available, but many of the opinions are, by necessity, based on uncontrolled series in children or controlled trials performed in adults, because controlled trials in children have not been performed to evaluate many of the treatments described. RESULTS AND CONCLUSIONS: These recommendations are intended to provide primary care physicians with a useful reference when they are faced with a young child or teenager who presents with proteinuria, whether this is mild and asymptomatic or more severe, leading to nephrotic syndrome.

Hyperoxaluria and urolithiasis in young children: an atypical presentation.

Urolithiasis is uncommon in adolescence and rare in early childhood. In pediatric populations, congenital urinary tract anomalies associated with stasis and infection, idiopathic urolithiasis (adolescents), and nephrocalcinosis (premature infants) account for the majority of urolithiasis patients. Inborn errors of metabolism, such as the primary hyperoxalurias, are rare causes of urolithiasis in childhood. We report six children (mean age at symptom onset 1.3 years; range 0.32-4.1 years) with moderate hyperoxaluria (mean 1.10 +/- 0.58 mmoL/1.73m2 per day; range 0.69-2.19 mmoL/1.73m2 per day). Urolithiasis was present in four. Stones from two children were comprised of calcium oxalate dihydrate. Calcium oxalate crystalluria was seen in two of the patients. Findings included a mean urine calcium concentration of 6.61 +/- 2.28 mg/kg per day, urine citrate of 925.5 +/- 291.29 mg/g of creatinine per day, and mean renal clearance of 99.83 +/- 23.27 mL/min. All children were born full term, none was receiving diuretics, and none had recurrent urinary tract infections. Secondary causes of hyperoxaluria, including dietary oxalate excess, pyridoxine deficiency, and malabsorption, were excluded. Urine glycolate and glycerate were normal in all patients. In one hyperoxaluric member of each sibship, hepatic alanine-glyoxylate aminotransferase and D-glycerate dehydrogenase/glyoxylate reductase activity were normal. The clinical and biochemical features of these children are unlike those in previously recognized hyperoxaluric states. Thus, our description of a separate hyperoxaluric entity, referred to as unclassified hyperoxaluria.

The gene encoding hydroxypyruvate reductase (GRHPR) is mutated in patients with primary hyperoxaluria type II.

Primary hyperoxaluria type II (PH2) is a rare monogenic disorder that is characterized by a lack of the enzyme that catalyzes the reduction of hydroxypyruvate to D-glycerate, the reduction of glyoxylate to glycolate and the oxidation of D-glycerate to hydroxypyruvate. The disease is characterized by an elevated urinary excretion of oxalate and L-glycerate. The increased oxalate excretion can cause nephrolithiasis and nephrocalci-nosis and can, in some cases, result in renal failure and systemic oxalate deposition. We identified a glyoxylate reductase/hydroxypyruvate reductase (GRHPR) cDNA clone from a human liver expressed sequence tag (EST) library. Nucleotide sequence analysis identified a 1198 nucleotide clone that encoded a 984 nucleotide open reading frame. The open reading frame encodes a predicted 328 amino acid protein with a mass of 35 563 Da. Transient transfection of the cDNA clone into COS cells verified that it encoded an enzyme with hydroxy-pyruvate reductase, glyoxylate reductase and D-glycerate dehydrogenase enzymatic activities. Database analysis of human ESTs reveals widespread tissue expression, indicating that the enzyme may have a previously unrecognized role in metabolism. The genomic structure of the human GRHPR gene was determined and contains nine exons and eight introns and spans approximately 9 kb pericentromeric on chromosome 9. Four PH2 patients representing two pairs of siblings from two unrelated families were analyzed for mutations in GRHPR by single strand conformation polymorphism analysis. All four patients were homozygous for a single nucleotide deletion at codon 35 in exon 2, resulting in a premature stop codon at codon 45. The cDNA that we have identified represents the first characterization of an animal GRHPR sequence. The data we present will facilitate future genetic testing to confirm the clinical diagnosis of PH2. These data will also facilitate heterozygote testing and prenatal testing in families affected with PH2 to aid in genetic counseling.

Disseminated varicella infection in pediatric renal transplant recipients treated with mycophenolate mofetil.

BACKGROUND: Mycophenolate mofetil (MMF) is a new immune suppressive agent, effective in the prevention of acute rejection after renal transplantation. METHODS: The study was a retrospective review of records of pediatric renal transplant recipients from 1985 to the present. RESULTS: Since October 1995, the immune suppression protocol for pediatric renal transplant recipients at Mayo Eugenio Litta Children's Hospital has included MMF, prednisone, and cyclosporine A. During that time, 19 children and adolescents have received renal allografts, 17 of whom were seropositive for varicella antibody before transplantation, while 2 were seronegative. Varicella infection occurred in 3 of 19 patients (15.8%), all 3 of whom had serologically documented immunity to varicella virus before transplantation. All episodes occurred within 12 months of transplantation. All had generalized vesicular lesions without dermatomal distribution. None of the patients developed fever, respiratory, mucocutaneous, or central nervous system manifestations. All were managed with oral acyclovir, and had an uncomplicated recovery without neuralgia. By contrast, of 74 consecutive patients transplanted before use of MMF, only 1 patient (1.4%) had varicella infection after transplantation (P=0.026). CONCLUSION: The enhanced immunosuppression achieved with MMF appears to be associated with increased susceptibility to varicella infection.

Clinical expression and long-term outcomes of primary hyperoxaluria types 1 and 2.

Primary hyperoxaluria, types 1 and 2, are rare disorders. Much of the information in the literature has been derived from case reports and data registries limited to patients requiring dialysis and/or transplantation. We present a single-center experience of 42 patients and 437 patient years of clinical experience with primary hyperoxaluria. Median age at onset of symptoms for patients with type 1 PH was 9 years, type 2 15.7 years. Sixty-four percent of the patients were less than 15 years of age at onset of symptoms. There was no correlation between urine oxalate excretion rates and age at onset of symptoms. Stone forming activity was greater in patients with type 1 PH than type 2. Ten patients presented initially with ESRD, and an additional seven developed ESRD during the course of follow-up. ESRD occurred in 54 percent of the patients with type 1 and 12 percent of patients with type 2 PH. Eight patients received nine renal allografts, five patients received combined kidney/liver transplants, and one patient received a hepatic allograft only. Ten of the transplanted patients were surviving at the time of the most recent follow up. Eight of them have functioning renal grafts and four have functioning hepatic grafts. There have been no deaths since 1988 among the 32 patients followed since that time. These data may suggest a broad range of clinical expression of primary hyperoxaluria. With current management strategies, outcomes are more favorable than has been reflected in previous literature.

Neonatal presentation of autosomal dominant polycystic kidney disease with a maternal history of tuberous sclerosis.

BACKGROUND: Childhood presentation of polycystic kidney disease has been reported with tuberous sclerosis complex (TSC). Recently some such cases have been shown to be due to combined deletion of the PKD1 and TSC2 genes, which lie close together on chromosome 16. The phenomenon of anticipation, whereby disease presentation occurs at a progressively earlier age in each generation, has been suggested to occur in autosomal dominant polycystic kidney disease (ADPKD). We have carried out a genetic study of a family in which these issues became clinically relevant. Neonatal presentation of polycystic kidneys occurred in an individual with a maternal family history of epilepsy and features of TSC without renal cystic disease. METHODS: Detailed historical and clinical profiles were gathered for three generations of the maternal and paternal families. Both parents underwent renal ultrasound scanning. Genomic DNA was obtained from affected and unaffected individuals from the maternal family and used for linkage analysis to gene loci for TSC. RESULTS: Renal cysts were not present in the mother by ultrasound. Linkage to TSC2 was found for members of the maternal family with clinical features of TSC. While a diagnosis of TSC was confirmed in her mother the child was found not to have inherited the disease-related allele. The father was found to have asymptomatic bilateral polycystic kidneys consistent with ADPKD. The presence of ADPKD in other paternal relatives could not be confirmed. CONCLUSIONS: The index case was found to have paternally inherited ADPKD with unusually early presentation. While at risk for concomitant maternal inheritance of TSC this diagnosis was ruled out by linkage analysis studies. The ability to clarify the true nature of a complex inherited condition greatly facilitates future management and counselling. The mechanisms underlying phenotypic heterogeneity in ADPKD remain to be clearly defined and are the subject of ongoing investigation.

Extraction of glyceric and glycolic acids from urine with tetrahydrofuran: utility in detection of primary hyperoxaluria.

Primary hyperoxaluria (PH) is an autosomal recessive metabolic abnormality characterized by excessive oxalate excretion leading to nephrocalcinosis and progressive renal dysfunction. Type I primary hyperoxaluria (PH I) results from a deficiency of alanine:glyoxylate aminotransferase, whereas type II disease has been traced to a deficiency of D-glycerate dehydrogenase. The two syndromes are often distinguished on the basis of organic acids that are coexcreted with oxalate: glycolate and L-glycerate in type I and type II disease, respectively. Routine organic acid analysis with diethyl ether extraction followed by gas chromatographic analysis failed to detect normal and increased concentrations of these diagnostic metabolites. Subsequent extraction of urine with tetrahydrofuran (THF), however, extracted 75% of added glycerate, 42% of added glycolate, and 75% of added ethylphosphonic acid (internal calibrator). THF extraction was analytically sensitive enough to allow determination of normal excretion of glycolate (14-72 micrograms/mg creatinine) and glycerate (0-5 years, 12-177 micrograms/mg creatinine and > 5 years, 19-115 micrograms/mg creatinine). Four of five patients with PH I and both patients with type II disease were correctly identified. Thus, THF extraction is a convenient adjunct to routine organic acid analysis and facilitates the detection of PH.