Bone biopsy to diagnose hyperoxaluria in patients with renal failure

Oxalate Bone Disease - an Emerging Form of Renal Osteodystrophy

Rosette-like arrays of highly birefringent calcium oxalate crystals are commonly seen in the marrow space of bone biopsy specimens taken from patients with primary hyperoxaluria, particularly if complicated by renal failure. Similar deposits have been described in chronic hemodialysis patients with secondary forms of oxalosis. Large multinucleated histiocytes may be seen surrounding these crystal deposits. Many of these cells are histologically indistinguishable from osteoclasts. We present a patient in whom this histiocytic reaction appeared to be of sufficient magnitude to stimulate bone resorption and to cause severe osteodystrophy. This observation, and those of other investigators reviewed in the discussion, suggest that oxalate deposition within bone may contribute to the pathogenesis of uremic osteodystrophy in chronic renal failure patients with primary or secondary types of oxalosis.

Bone metabolism in oxalosis: a single-center study using new imaging techniques and biomarkers

The deposition of calcium oxalate crystals in the kidney and bone is a hallmark of primary hyperoxaluria type 1 (PH1). We report here an evaluation of the bone status of 12 PH1 children based on bone biomarkers [parathyroid hormone, vitamin D, fibroblast growth factor 23 (FGF23)] and radiological assessments (skeletal age, three-dimensional high-resolution peripheral quantitative computed tomography, HR-pQCT) carried out within the framework of a cross-sectional single-center study. The controls consisted of healthy and children with chronic kidney disease already enrolled in local bone and mineral metabolism studies. The mean age (+ or - standard deviation) age of the patients was 99 (+ or - 63) months. Six children suffered from fracture. Bone maturation was accelerated in five patients, four of whom were <5 years. The combination of new imaging techniques and biomarkers highlighted new and unexplained features of PH1: advanced skeletal age in young PH1 patients, increased FGF23 levels and decreased total volumetric bone mineral density with bone microarchitecture alteration.

Primary hyperoxaluria type 1 in Japan

BACKGROUND/AIMS

Current status of primary hyperoxaluria (PH) has not been surveyed in Japan.

METHODS

Japanese patients with PH were reviewed in the published literature.

RESULTS

Fifty-nine patients were diagnosed as PH from 1962 to 2003. The median ages both at diagnosis and at the onset of initial symptoms were 17 (range: 0.02-63) and 13 (range: 0-58) years, respectively. Twenty-nine (49%) patients were older than 20 years at diagnosis, among whom 26 (90%) already presented end-stage renal failure (ESRF) or soon evolved into ESRF. Among 30 (51%) diagnosed as PH under 20 years old, only 13 (43%) were already in a terminal stage of renal insufficiency. Ten patients were diagnosed as PH1 by liver biopsy. We identified two types of enzymatic phenotypes in 3 of those patients examined. In 1 case, immunoreactive SPT/AGT protein level was very low due to accelerated proteolysis, while in other 2 cases, the immunoreactivity was detected on mitochondria due to mistargeting. Of 9 cases having been subjected to kidney transplantation at a median age of 20 years (range 7.3-40.0), it was only 2 cases that were reported to be successful, while the median survival time of the kidney grafts being 1.4 years (range 0-7). Of 4 patients having undergone combined liver/kidney transplantations (at the ages of 1.3, 1.4, 9 and 41 years, respectively), the surgery was successful in 3 cases; in the remaining one case, however, rejection required removal of the transplanted kidney was observed. The overall survival ratio of all the 59 PH cases accounted for 77, 71 and 55% at 5, 10 and 20 years, respectively.

CONCLUSION

Assuming that the majority of the 59 patients with PH reported was classified as PH1, it is postulated that morbidity of violent infantile PH1 in Japan might be less than those in the USA and Europe, and symptoms of elderly Japanese PH1 patients seem to be milder than those of Western patients. Establishment of an early detection system of PH1 and more popular application of combined liver/kidney transplantation deserve further study.

Multiple periarticular osteosclerosis accompanied by joint destruction treated with bilateral total knee arthroplasty

This report documents the case of a 53-year-old man with multiple periarticular osteosclerosis in the bilateral wrists, elbows, knees, and ankles. He underwent bilateral total knee arthroplasty to relieve difficult walking as a result of osteosclerosis accompanied by joint destruction in both knees. Because the bones were abnormally hard and brittle, the start of the surgery caused fracture, so that considerable caution was necessary during the subsequent procedures. The patient's symptoms were thought to be associated with hemodialysis because he had been suffering from renal failure since 1989. Involvement of other associated diseases was also suspected because of the unusually formation, brittleness and crystallinity of the patient's bones. However, no definite diagnosis could be made for this patient.

Bone mineral density in children with primary hyperoxaluria type I

BACKGROUND

In primary hyperoxaluria type I (PH 1), hepatic overproduction of oxalate leads to its deposition in various organ systems including bone (oxalosis). To evaluate skeletal status non-invasively in PH 1 we measured bone mineral density (BMD).

METHODS

Peripheral quantitative computed tomography of the distal radius was performed in 10 children with PH 1 (mean chronological age 9+/-3.1, mean skeletal age 8.3+/-3.0 years): seven were on conservative treatment (CT) including one patient after pre-emptive liver transplantation (PH1-CT) and three were studied with end-stage renal disease on peritoneal dialysis (PH1-ESRD).

RESULTS

Mean trabecular bone density (TBD) was significantly increased in PH1-ESRD compared with both age-matched healthy and uraemic controls (65227 vs. 168+/-63 and 256+/-80 mg/cm(3); P<0.002 and P<0.007, respectively), while cortical bone density (CBD) was elevated to a lesser degree (517+/-23 vs. 348+/-81 vs. 385+/-113 mg/cm(3); P<0.02 and P<0.04, respectively). In PH 1, CBD and, even more so, TBD were significantly correlated with serum creatinine (r=0.91 and r=0.96, P<0.0001, respectively) and plasma oxalate levels (r=0.86 and r=0.94, P<0.001 and P<0.0001, respectively). In children with PH 1 and normal glomerular function, both CBD and TBD were comparable with healthy controls.

CONCLUSION

These preliminary data suggest that in PH 1 BMD is significantly increased in ESRD, probably due to oxalate disposal. Measurement of BMD may be a valuable and non-invasive tool in determining and monitoring oxalate burden in this disorder.

Primary hyperoxaluria type 1: An underestimated cause of nephrocalcinosis and chronic renal failure in Saudi Arabian children

BACKGROUND

Primary hyperoxaluria type I (PHI) is a rare metabolic disease caused by deficiency or abnormalities of the peroxisomal enzyme alanine-glyoxylate aminotransferase. In the majority of patients, the clinical expression of PHI is characterized by recurrent calcium oxalate urolithiasis, nephrocalcinosis and renal failure.

PATIENTS AND METHODS

Sixteen children aged 5 months to 14 years were diagnosed as PHI over a 10-year period ending in June 1997. The diagnosis was established by quantitative urinary oxalate excretion, or by a high urine oxalate/creatinine ratio on spot urines.

RESULTS

The majority of patients had nephrolithiasis (13/16) and/or nephrocalcinosis (12/16). Four patients already had advanced chronic renal failure at the time of diagnosis. Altogether, PHI accounted for 20% of nephrocalcinosis and 6% of end-stage renal disease. Two patients had a complete response to pyridoxine therapy, while four patients had a partial response. Eight patients underwent organ transplantation, three underwent kidney transplantation, three received combined liver/kidney transplantation for end-stage renal disease, and two received isolated preemptive liver transplantation.

CONCLUSION

Combined organ transplantation provided the best long-term results.

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 μg/mg creatinine) and glycerate (0–5 years, 12–177 μg/mg creatinine and &gt;5 years, 19–115 μg/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.

[Value of extracorporeal shockwave lithotripsy in primary hyperoxaluria type I]

BACKGROUND

Application of extracoporal shock wave lithotripsy (ESWL) has revolutionized the management of many types of urolithiasis, including that observed in primary hyperoxaluria where surgical attempts to remove calculi sometimes result in worsening of renal function.

CASE REPORTS

Three unrelated patients aged 8, 10 and 11 years, respectively, with type I primary hyperoxaluria, suffered from recurrent bouts of abdominal pain (two patients) or anemia (one patient). Two patients had chronic renal failure. Plain abdominal films and ultrasonography showed several large bilateral stones. ESWL was applied to the three patients permitting complete removal of stones following three sessions in one patient and partial removal following four sessions in the second patient who developed infection after the first session with transitory increase in creatinemia. Several sessions of ESWL failed to fragment stones in the third patient.

CONCLUSION

ESWL may represent a safe procedure for attempting stone removal in patients with primary hyperoxaluria.

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)

Cutaneous oxalate granulomas in a haemodialysed patient: report of a case with unique clinical features

We report a patient undergoing haemodialysis, who developed multiple subcutaneous nodules. Histology showed that the nodules were composed of deposits of crystals in the dermis, with an associated foreign-body reaction. The crystalline deposits were identified as calcium oxalate by histochemical staining, polarizing microscopy, and analytical electron microscopy.

Skeletal manifestations of primary oxalosis

We describe the clinical, radiographic and histological features of skeletal involvement in four patients with end-stage renal failure due to primary oxalosis. The clinical features were unrelenting bone pain, and in two patients multiple fractures. Radiographic features were, in chronological order: (1) radiodense metaphyses and other red marrow bone; (2) cortical defects in metaphyses; (3) spontaneous fracture-separations of epiphyses of long limb bones which healed poorly. The fractures occurred through crystal deposits, and fracture displacement was associated with extrusion of crystalline material from bone. On histological examination crystals were found to replace metaphyseal bone. Pericrystalline giant cell granulomata replaced bone marrow. Erosion surfaces near granulomas were increased. Subperiosteal and intra-osseous tophi of calcium oxalate were seen. Calcium oxalate appears to precipitate with greater facility than does physiological mineral. Bone showed the features of mixed uraemic osteodystrophy in all four patients. We conclude that: (1) the fractures occurred through heavy crystal deposits; (2) ununited fractures and intra-osseous and subperiosteal tophi contributed to the pain; (3) spontaneous fractures are of poor prognostic significance. We recommend that unstable fractures be internally fixed.

[Type I oxalosis in childhood--studies within the scope of terminal renal failure in the child]

The difficulties of biochemical diagnosis in children and in chronic renal failure are discussed in detail, as well as the development of diagnostic and therapeutic possibilities in recent years, exemplified by 4 cases. Excretion of oxalate (and glycolate) may be incorrectly assumed to be normal with: a) uncritical application of the method of measurement, b) disregard of the clearly lower oxalate excretion in children (values should be referred to m2 of body surface), c) disregard of a decreased glomerular filtration rate (values should be referred to the creatinine clearance). With compromised renal function the excretion of oxalate and glycolate in primary oxalosis drops to "normal" whereas plasma values increase considerably. In this case the biochemical diagnosis is possible only by measurement of plasma values of glycolate and oxalate. Consequently, extensive extrarenal deposition of calcium oxalate crystals will, as a rule, become clinically manifest only after chronic renal failure has turned irreversible. In recent years, several therapeutic procedures, have been developed. They are of therapeutic significance for the early stages of the disease as well. Observing especially conditions renal transplantation or combined hepatorenal transplantation can be managed with a successful outcome. As the perioxisomal enzyme is activated only in the liver cells, an early liver transplantation as a definitive treatment by enzyme replacement may be the successful therapy in the future.

Calcium oxalate and other crystals associated with kidney diseases and arthritis

The recognition of tissue deposits of crystalline material in a variety of organs, including the kidney, predated the association of crystals and arthritic disease. Because of this, the pathophysiology of crystal formation and its resultant inflammation is based in part on studies of renal stones. A number of disease states involving renal and articular crystallization exist. The most common of these, uric acid precipitation, or gout, and calcium phosphate precipitation were not reviewed in this discussion. This review described a variety of less common disease states involving articular and renal crystal deposition. The renal diseases discussed included both parenchymal or ectopic crystal deposition, as seen in nephrocalcinosis or cystinosis, and ductal crystallization as seen in renal calculus disease. The crystals involved included not only calcium oxalate, but also aluminum, amino acids and proteins (cystine, hemoglobin, cryoglobulins, and immunoglobulins), purine metabolites (xanthine, hypoxanthine), and even lipids and their degradative enzymes (cholesterol, phospholipids, phospholipase, and fatty acids). The simultaneous occurrence of crystals in both kidneys and joints was found in some cases to result from the systemic deposition of an excess of a particular biological compound. However, of more interest, some renal deposits were shown to more selectively reflect the normal or abnormal function of the kidney in its secretory and excretory roles. This is particularly evident in the variety of arthritic states described in end-stage renal disease.

Bone disease of primary hyperoxaluria in infancy

A patient with primary hyperoxaluria type I in infancy is reported. He had renal insufficiency, but urolithiasis was absent. Demonstration of diffuse nephrocalcinosis by renal ultrasound contributed to early diagnosis. Prolonged survival leads to extensive extrarenal oxalate deposition. Repeated skeletal surveys showed the development and the progression of severe hyperoxaluria-related bone disease. Translucent metaphyseal bands with sclerotic margins, wide areas of rarefaction at the ends of the long bones, and translucent rims around the epiphyses and the tarsal bones were signs of disordered bone growth. Bone density generally increased with time indicating progressive sclerosis due to oxalate deposition in the previously normal bone structure.

Oxalosis in bone causing a radiographical mimicry of renal osteodystrophy

We report a patient on maintenance dialysis with oxalosis and radiographical signs typical of hyperparathyroid bone disease in patients with end-stage renal insufficiency. The patient underwent a subtotal parathyroidectomy. Because his bone pain worsened during long-term dialytic therapy, a bone biopsy was performed and revealed crystalline deposits in trabecules and the bone marrow characteristic of oxalate. Trabecular destruction and signs of defective mineralization of bone were also found. When the diagnosis was made, the patient had become addicted to narcotic analgesics; he died from an overdose. The case underscores the limits of skeletal radiographs for the diagnosis of oxalosis in bone. Furthermore, the radiographic findings may lead to erroneous conclusions in patients with renal osteodystrophy because the radiographic signs of oxalosis can mimic those of hyperparathyroid bone disease.

Primary bone oxalosis: the roles of oxalate deposits and renal osteodystrophy

Primary oxalosis is a rare congenital disorder. The excessive oxalate biosynthesis induces deposits in many organs, particularly in kidney and bone. The late onset of primary oxalosis is reported in a 50-year-old man. His chronic renal failure was treated by maintenance hemodialysis for 3 years. He then developed a diffuse bone disease with osteosclerosis and roentgenographic features of hyperparathyroidism. A parathyroidectomy was performed, with debatable improvement of bone lesions. Laboratory results and histologic and histomorphometric studies before and after parathyroidectomy suggest a double histopathogenetic mechanism for this bone disease: renal osteodystrophy and massive bone oxalate deposits. Such deposits may induce both a heterogeneous osteosclerosis with dense metaphyseal bands and histologic bone lesions similar to those of hyperparathyroidism. The crystalline deposits induce in the bone tissue a granulomatous macrophagic reaction. These macrophages are unable to phagocytize the crystals and may be involved in active bone resorption. Bone lesions of oxalosis occur in patients with chronic renal failure, and hyperparathyroidism has a worsening role.

Bone oxalate in a long-term hemodialysis patient who ingested high doses of vitamin C

We performed a bone biopsy on a patient who had been receiving hemodialysis for 23 years. The bone had oxalate deposition. Previous bone biopsies had shown osteitis fibrosis without oxalate deposition. The osteoid area was increased (11% of bone area), as was the fibrosis (6.1% of tissue area) and aluminum deposition (38% of surface). Bone formation rate was normal (259 mu 2/mm2/d). We examined bone biopsies of 22 patients who had been receiving hemodialysis for over 10 years, and none had oxalate deposits. We discovered that our patient had been ingesting 2.6 g/d of vitamin C. The bone oxalate deposition may have been caused by the ingestion of high doses of vitamin C.

Arthropathy and cutaneous calcinosis in hemodialysis oxalosis

Recently, calcium oxalate crystals have been identified in the synovial fluid of patients with arthritis and end-stage renal failure. We describe 4 patients who, during the course of long-term hemodialysis, developed calcium oxalate crystal deposits in the synovium and skin. Clinical manifestations included podagra, tenosynovitis, olecranon bursitis, and acute and chronic synovitis of the large joints that were associated with chondrocalcinosis or subchondral bone erosions. Diffuse involvement of the hand, with chondrocalcinosis of the finger joints, miliary calcified deposits in the skin, and artery calcifications, was observed in 3 patients. The fourth patient had erosive arthropathy. Oxalosis secondary to end-stage renal failure in patients treated with long-term hemodialysis can present with articular manifestations that resemble those of gout, pseudogout, and apatite deposition disease. Other characteristic features of the synovitis associated with oxalosis secondary to end-stage renal disease were: predominant involvement of the hand, mild inflammatory changes in the synovial fluid and synovium, and poor response to administration of nonsteroidal antiinflammatory agents.

Calcium-oxalate-crystal-induced bone disease

A 13-year-old boy with primary hyperoxaluria and a successful renal allograft developed symptomatic bone disease, hypercalcemia, and hypercalciuria. Transiliac bone biopsy revealed calcium oxalate crystals in the marrow within mononuclear phagocytes and multinucleated giant cells. Deep resorption bays were seen adjacent to these crystal-cell aggregates. Serum 1,25-(OH)2-vitamin D (calcitriol) and iPTH concentrations were low or normal. We suggest that hypercalcemia results from macrophage-mediated bone resorption initiated by Ca oxalate crystal deposition.

Calcium oxalate deposition in growing bone: anatomical and radiological study in a case of primary oxalosis

A combined radiological, histological, and crystallographical study of bone, primarily the inferior femur, taken at autopsy from a 9 year old female with primary oxalosis, is reported. The essential feature is the deposition of calcium oxalate monohydrate (whewellite) crystals, inducing a foreign body reaction and bone remodelling. Synovial and cartilage surfaces are not involved. The changes occur primarily at sites of previous or present growth and seem to be related to the reaction of tissue to the deposition of blood-borne crystals. The radiological changes may be explained in part by the deposition of crystals at Harris' lines of growth arrest. Cancellous bone also shows changes similar to those observed in renal osteodystrophy.