Osteomalacia as a very late manifestation of primary hyperparathyroidism

An 86-year-old woman with a history of treated hyperthyroidism and a 20-year history of untreated primary hyperparathyroidism developed generalized bone pain and a pseudofracture of the midshaft of the left femur. Laboratory examinations revealed elevated serum calcium, alkaline phosphatase, and C-terminal parathyroid hormone levels. Serum inorganic phosphate was below normal and 25-hydroxyvitamin D levels were low-normal. An undecalcified transiliac bone biopsy specimen following tetracycline double labeling revealed osteomalacia and osteitis fibrosa. Following treatment with vitamin D and phosphate, the serum inorganic phosphate level rose to normal. There was a decrease in bone pain, and the pseudofracture healed. However, the serum calcium, alkaline phosphatase, and C-terminal parathyroid hormone levels remained elevated. Longstanding primary hyperparathyroidism causes chronic hypophosphatemia and may lead to osteomalacia. Osteomalacia and its consequences may be part of the spectrum of bone disease seen in patients with longstanding primary hyperparathyroidism.     

Ketodiet, physiological calcium intake and native vitamin D improve renal osteodystrophy.

The effects of a very low-protein diet (VLPD) supplemented with amino acids and ketoanalogues (KA) and with 1 g of calcium carbonate and 1000 IU of vitamin D2, were studied in 17 patients with advanced renal failure (GFR < or = 20 ml/min) over a period of one year. The protein intake was 0.3 g protein/kg body wt/day. Daily phosphorus and calcium intake were respectively 1,500 mg and 300 mg. Sequential bone densitometry was performed and bone histomorphometry after double tetracycline labeling was evaluated, before and after one year of diet. Calcium and phosphate metabolism parameters were monitored every two months. In spite of a significant decrease of GFR, phosphorus, parathyroid hormone (1-84) and osteocalcin plasma levels decreased significantly, while low plasma bicarbonate normalized, and calcitriol and calcium levels remained respectively low and normal. Before the diet, histological study disclosed four cases of mixed osteopathy: osteomalacia associated with osteitis fibrosa (OM/OF), nine pure osteitis fibrosa (OF) and four with normal bone remodeling (NB). After one year of diet, the OM component of OM/OF disappeared, as evidenced by a normalization of the mineral apposition rate and osteoid thickness. In the patients presenting pure OF, a significant decrease in osteoblastic and osteoclastic surfaces, in the number of osteoclasts, and in the bone formation rate (BFR) were found. Vertebral mineral density measured by quantitative computerized tomodensitometry did not change significantly. In conclusion, this study not only confirms the beneficial effects of VLPD + KA + calcium on uremic hyperparathyroid bone disease in advanced renal failure assessed using static bone histomorphometry, but also shows a correction of histodynamic bone parameters.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hypercalcemic hyperparathyroidism and hypophosphatemic osteomalacia complicating neurofibromatosis

Summary Neurofibromatosis is sometimes complicated by impaired renal tubular reabsorption of phosphate, hypophosphatemia, and osteomalacia. Hyperparathyroidism has also been reported in patients with neurofibromatosis. When hypercalcemia and elevated levels of parathyroid hormone are found in osteomalacia, however, it may be difficult to determine if the hyperparathyroidism was primary or tertiary. We describe a patient with neurofibromatosis, hypercalcemic hyperparathyroidism, hypophosphatemic osteomalacia, vitamin D deficiency, and clear-cell hyperplasia of all four parathyroid glands. Serial biomechanical, bone biopsy, and densitometric studies confirmed that treatment with ergocalciferol, calcium, and phosphate supplements significantly improved the osteomalacia but caused increased parathyroid overactivity. After subtotal parathyroidectomy, the parathyroid hormone concentration became normal and the bone mineral content increased at the spine and hip, but inappropriate phosphaturia persisted. The findings indicate that hyperparathyroidism, osteomalacia, and vitamin D deficiency adversely affect each other.     

No Evidence of Osteopenia 5 to 8 Years After Ileal Orthotopic Bladder Substitution

Purpose

The use of bowel segments as bladder substitutes may result in chronic, impaired vitamin D and calcium metabolism, and ultimately in bone demineralization.

Materials and Methods

Bone metabolism was examined in 14 patients who lived for 5 to 8 years with an ileal low pressure bladder substitute after radical cystectomy for bladder cancer. Bone mineral density was measured using dual energy x-ray absorptiometry of the total skeleton, lumbar spine, femoral neck, and tibial epiphysis and diaphysis. Laboratory studies included serum levels of 1,25-dihydroxyvitamin D, 25-hydroxyvitamin D, intact parathyroid hormone, plasma alkaline phosphatase, electrolytes, creatinine and blood gas analysis.

Results

Bone mineral density was normal in all patients. There was no evidence of deficient vitamin D stores. There was a tendency toward slightly elevated serum creatinine values in patients with preexisting impaired renal function, including 1 who also had slight acidosis. No patient had hyperchloremia.

Conclusions

We found no evidence of osteomalacia, osteoporosis or significant metabolic acidosis in 14 patients with an ileal bladder substitute for 5 to 8 years. However, it is not known whether the absence of osteopenia would also apply to patients with poor renal function, to those not followed meticulously and, thus, at risk for major long-term functional or metabolic disturbances from the ileal bladder substitute or to patients with orthotopic bladder substitutes made from longer or other bowel segments than we used.     

Changes in bone mineral density following treatment of osteomalacia.

Osteomalacia is characterized by defective mineralization and low bone mineral density (BMD). Clinical and biochemical improvements typically occur within a few weeks of starting treatment, though the bone mineral deficits may take longer to correct. We report a case series of 26 patients with frank osteomalacia (pseudo fractures on X-rays, elevated serum total alkaline phosphatase and parathyroid hormone, normal/low serum calcium and phosphorus, and low serum 25-hydroxy vitamin D) who were followed-up for changes in BMD during treatment using dual- energy X-ray absorptiometry (DXA). There were 23 patients with nutritional vitamin D deficiency, 2 with malabsorption syndrome, and 1 with renal tubular acidosis. All patients were treated with vitamin D and calcium; the 3 patients with associated disorders were treated accordingly. At baseline, there was low BMD at all sites tested. The rate of increase in vertebral and hip BMD was rapid in the initial few months, which subsequently slowed down. In contrast to the large increases in BMD at the femoral neck and lumbar spine, the radial BMD did not recover. At the time when most patients had marked clinical and biochemical improvement (2.8+/-1.4 mo), the vertebral and hip BMD, although improved from baseline, had not completely recovered. Bone loss at the forearm (cortical site) appears to be largely irreversible. Although the clinical correlates of these changes are presently unclear, BMD measurements are useful in assessing the initial severity of bone loss as well as the response to therapy.     

甲状腺功能亢进症合并骨软化1例并文献复习

甲状腺功能亢进(简称甲亢)是导致碱性磷酸酶升高的原因之一,在甲亢的治疗过程中,如碱性磷酸酶进行性升高,伴骨痛,不能排除骨软化的可能性,值得引起注意。随着对代谢病骨病研究的深入,骨软化患者逐渐增多,病因包括维生素D摄入不足、维生素D吸收和代谢障碍、肾脏疾病(肾病综合征、慢性肾衰、肾小管酸中毒、范可尼综合征等),以及遗传性和肿瘤性低磷性骨软化,其他如重金属中毒、高氟摄入、某些药物等。然而,甲状腺功能亢进症患者出现骨质疏松多见,出现骨软化者较少见,罕有报道,容易漏诊和误诊。本文报道l例甲状腺功能亢进患者口服赛治(甲巯咪唑)后碱性磷酸酶进行性升高,伴全身骨痛,应用骨化三醇后碱性磷酸酶逐渐下降和骨痛消失。为此,甲亢治疗期间,结合国外文献报告,考虑骨软化可能性较大,密切观察患者碱性磷酸酶变化,给予积极对症治疗后,骨软化症状明显缓解。因此,应重视碱性磷酸酶的变化及临床特点,以明确是否合并骨软化并予尽早处理。     

Bone mineral density and histology in distal renal tubular acidosis

BACKGROUND: Chronic metabolic acidosis in distal renal tubular acidosis (RTA) has been implicated in the pathogenesis of enhanced bone resorption and osteopenia, resulting in a loss of bone mineral content. However, histomorphometric and bone densitometric studies of patients who suffered from long-standing distal RTA have rarely been done. METHODS: A cross-sectional study to determine the alterations of bone mineral density (BMD) and histology was done in 14 nonazotemic RTA patients (11 females and 3 males) who had never received alkaline therapy before enrolling into this study. The mean age was 32.7 +/- 11.9 years. BMD measurements and transiliac bone biopsy were done in all patients. Blood chemistries, intact parathyroid hormone level, and a 24-hour urine collection for the determination of urinary calcium, phosphate, sodium, and potassium were obtained from the RTA patients at the time of bone biopsy. Data from 28 age-, sex-, and body mass index-matched, normal controls who were residents in the same area were also obtained. RESULTS: Urinary excretion of calcium was 2.05 +/- 1.59 mmol/day. No patient had hypercalciuria. The serum intact parathyroid hormone level was 15.92 +/- 8.48 pg/mL. RTA patients had lower BMD in most areas when compared with normal controls. There were two patients who suffered from a pathologic fracture at the femur. Bone histomorphometry from RTA patients shows a significantly decreased bone formation rate (0.02 +/- 0.02 vs. 0.07 +/- 0.045 microm(3)/microm(2)/day, P < 0.05), not significantly decreased osteoblastic surface (0.78 +/- 1.03% vs. 2.6 +/- 1.1%) and osteoclastic surface (0.05 +/- 0.03 vs. 0.13 +/- 0.23%), but significantly increased osteoid surface (31.47 +/- 24.52 vs. 5.79 +/- 4.39%, P < 0.05) and osteoid volume (2.95 +/- 3.09 vs. 0.92 +/- 1.05%, P < 0.05) when compared with those of normal controls. There was no difference in osteoid thickness (10.65 +/- 6.10 vs. 8.69 +/- 2.14 microm). Only one distal RTA patient who had a marked increase in osteoid thickness justified the diagnosis of osteomalacia. CONCLUSIONS: This study demonstrates that low bone mass is common in distal RTA patients. Chronic metabolic acidosis results in suppression of bone formation and resorption, which in turn may contribute to the development of low bone mass in distal RTA patients. Although minor elevations in osteoid surface and osteoid volume are found among distal RTA patients, overt osteomalacia is not the predominant bone lesion.     

Osteomalacia mimicking spondyloarthropathy: a case report

Osteomalacia is a metabolic bone disorder characterized by impaired mineralization of bone matrix. Symptoms of osteomalacia can be confused with other conditions such as spondyloarthropathy, polymyalgia rheumatica, polymyositis, and fibromyalgia. In this case, we report a patient with axial osteomalacia who developed low back pain, morning stiffness, and “grade 3 sacroiliitis” in pelvis X-ray, leading to the misdiagnosis as seronegative spondyloarthropathy. Serum biochemical studies revealed low serum phosphorus, low 25-hydroxy vitamin D₃, normal calcium, elevated parathyroid hormone, and alkaline phosphatase levels. Her symptoms were relieved with vitamin D and calcium therapy. The diagnosis of osteomalacia should be considered in case of sacroiliitis and spondylitis.     

Alteration of noncollagenous bone matrix proteins in distal renal tubular acidosis

Our previous report on bone histomorphometry in patients with distal renal tubular acidosis (dRTA) revealed decreased bone formation rate (BFR) when compared to healthy subjects. The abnormality improved significantly after alkaline therapy. The modest increase in osteoblastic surface, after correction of metabolic acidosis, could not explain the striking improvement in bone formation, suggesting additional influence of metabolic acidosis on osteoblast function and/or bone matrix mineralization. Osteoblasts and, to a lesser extent, osteoclasts synthesize and secrete bone matrix including type I collagen and various noncollagenous proteins (NCPs). Substantial evidence suggested diverse functions of NCPs related to bone formation, resorption, and mineralization. Metabolic acidosis, through its effect on bone cells, may result in an alteration in the production of NCPs. Our study examined bone histomorphometry with detailed analysis on the mineralization parameters and NCPs expression within the bone matrix of patients with dRTA before and after treatment with alkaline. Seven dRTA patients underwent bone biopsy at their initial diagnosis and again 12 months after alkaline therapy. Bone mineral density (BMD) and bone histomorphometry were obtained at baseline and after the treatment. The expression of NCPs was examined by immunohistochemistry, quantitated by digital image analysis, and reported as a percentage of area of positive staining or mineralized trabecular bone area. Alkaline therapy normalized the low serum phosphate and PTH during acidosis. The reduction in BMD at baseline improved significantly by the treatment. Bone histomorphometry demonstrated the increase in osteoid surface and volume without significant alteration after acidosis correction. In comparison to the normal subjects, osteoid thickness was slightly but insignificantly elevated. Osteoblast and osteoclast populations and their activities were suppressed. The reduction in mineral apposition rate and adjusted apposition rate were observed in conjunction with the prolongation of mineralization lag time. Alkaline therapy improved the mineralization parameters considerably. In addition to the increase in BFR relative osteoblast number after acidosis correction, osteocalcin expression in the bone matrix increased significantly from 16.7% to 22.3%. Six of seven patients had decreased osteopontin expression. In conclusion, the abnormal bone remodeling in dRTA is characterized by low turnover bone disease with some degree of defective mineralization. Alteration of NCPs expression suggested the effect of metabolic acidosis on bone cells. Alkaline therapy increased bone mass through the restoration of bone mineral balance and, perhaps, improved osteoblast function.     

Inhibition of cortical and trabecular bone formation in the long bones of immobilized monkeys

The acute effects of immobilization on cortical and trabecular bone formation were studied in juvenile male rhesus monkeys (Macaca mulatta). Four animals were immobilized for two weeks by application of total body casts. Two control monkeys were housed in separate metabolic cages under similar environmental and dietary conditions. Tetracycline derivatives were administered on three separate occasions to label sites of bone formation. The tetracycline-labeling frequency and mineral apposition rate of osteons and trabecular bone surfaces in the humerus and femur were determined. The inhibition of bone formation induced by immobilization was more pronounced in trabecular bone. Immobilized monkeys exhibited a moderate, but statistically nonsignificant, reduction in the percentage of osteons forming bone. Conversely, the dramatic decline in the percentage of trabecular surfaces undergoing bone formation in immobilized monkeys was found to be highly significant. The diminished rate of mineral apposition in osteons suggested that osteoblastic activity was impaired in cortical bone during immobilization. The mineral apposition rate in trabecular bone could not be determined reliably due to minimal tetracycline deposition, which indicated that osteoblastic activity and/or recruitment almost ceased in the metaphyseal tissue of immobilized monkeys.     

Tetracycline fluorescence in uremic and primary hyperparathyroid bone

Twenty-five patients with end-stage renal disease, nine of whom were receiving pharmacologic doses of vitamin D, and seventeen patients with primary hyperparathyroidism underwent bone biopsy following a three-day course of tetracycline administration. The mean width of the fluorescent tetracycline bands were significantly greater in the bones of patients with uremia than in those with primary hyperparathyroidism. This difference was due to wide labels present in the patients with uremia who had not been treated with vitamin D, as no differences existed in mean label widths of patients with uremia who had received this compound and the patients with primary hyperparathyroidism. Comparison of the maximum label widths distinguished not only primary hyperparathyroid patients from those with uremia, but uremic patients who had recieved vitamin D from those who had not been so treated. Quantitative microscopy of standard, nonfluorescent histologic features failed to make this latter distinction. These data are consistent with the presence of a wide zone of instantaneously fluorescing material in uremic bone following tetracycline administration, which does not relate to bone apposition occurring during antibiotic administration. This phenomenon probably represents a delay in mineral maturation which is normalized by vitamin D. Furthermore, it is apparent that the use of a continuously administered (single) tetracycline label will result in an overestimation of bone formation rates, particularly in osteomalacic states.     

Inhibition of bone matrix apposition by (3-amino-1-hydroxypropylidene)-1,1-bisphosphonate (AHPrBP) in the mouse

To elucidate the mechanism of action of (3-amino-1-hydroxypropylidene)-1,1-bisphosphonate (AHPrBP, formerly APD) on bone metabolism, we have studied the influence of low doses of AHPrBP on bone resorption and formation in the mouse. Thirty-five-day-old mice were given daily injections of 0.16, 1.6, or 16 mumol/kg BW per day of AHPrBP for 10 days. At sacrifice biochemical parameters were measured in serum and bone ash, and histomorphometric parameters of bone formation and resorption were determined on undecalcified sections of caudal vertebrae after double 3H-proline and double tetracycline labelings. Serum calcium and 1,25-dihydroxyvitamin D levels remained normal at all dosage levels. Compared to controls, AHPrBP at doses of 1.6 and 16 mumol/kg per day increased the number of osteoclasts and the number of nuclei per osteoclast but markedly decreased the number of acid phosphatase-stained osteoclasts. Thus, AHPrBP appears to inhibit osteoclastic activity in vivo in part through reduction of acid phosphatase activity. At doses of 1.6 and 16 mumol/kg per day AHPrBP reduced serum alkaline phosphatase and the osteoblastic surface and decreased the endosteal osteoid surface and thickness. Both the matrix apposition rate and the mineral apposition rate were progressively reduced at the endosteal level, although they were not significantly changed at the periosteal level. Greater inhibition of bone resorption than bone formation resulted in increased endosteal bone density and bone mineral content. AHPrBP at a dose of 0.16 mumol/kg per day did not alter either the osteoclastic bone resorption or the mineral and matrix apposition rates.     

Osteomalacia in a patient with severe anorexia nervosa

A 27-year-old woman with anorexia nervosa since adolescence was referred to our unit for generalized bone pain most severe at the pelvis and an inability to stand. She reported a pelvic fracture diagnosed one year earlier, which had failed to heal. Laboratory tests showed low serum phosphate, normal total serum calcium corrected for serum albumin, and very low urinary calcium excretion. Serum bone alkaline phosphatase and parathyroid hormone levels were elevated, whereas 25-hydroxy-vitamin D was severely decreased. Multiple vertebral and rib fractures were seen on plain radiographs. Radiographic images consistent with osteomalacia were pseudofractures of the left inferior pubic ramus, a bilateral complete fracture of the superior pubic ramus, and a characteristic pseudofracture (Looser zone) in the lateral margin of the right scapula. Vitamin D-deficient osteomalacia with secondary hyperparathyroidism was strongly suspected at this point, but it was decided not to confirm this diagnosis by bone biopsy with histomorphometry and osteoid labeling because of the emotional instability of the patient. Dual-energy X-ray absorptiometry disclosed severe demineralization. After two months on calcium and vitamin D supplements, the bone pain had abated and the patient was able to stand. Serum calcium had increased; serum phosphate, 25-hydroxy-vitamin D, and parathyroid hormone had returned to normal, and the pseudofractures showed evidence of healing. Osteoporosis is a well-known complication of anorexia nervosa. This case shows that osteomalacia can also occur. Vitamin D status should be assessed in patients with long-standing severe anorexia nervosa.     

Renal bone disease: a new conceptual framework for the interpretation of bone histomorphometry

My purpose in this article is to restore the histologic appraisal of renal bone disease to the mainstream of bone and mineral metabolism from which it has been separated for many years. Historically, both the two major components were found in varying degrees in most patients, although one or other of them often predominated. For more than 15 years bone biopsy has been used almost exclusively to classify individual patients into hyperparathyroid, osteomalacic, mixed and adynamic categories according to rigid non-overlapping criteria, and remarkably few histologic data have been reported. All metabolic bone diseases result from disordered bone remodeling, the physiologic mechanism for replacing bone that has become too old to carry out its mechanical or metabolic functions. Bone remodeling is not directly concerned with the regulation of plasma calcium, which reflects the level of equilibration at quiescent bone surfaces between systemic and bone extracellular fluid set by parathyroid hormone. The separation of remodeling from homeostasis explains the concurrence of increased turnover and decreased plasma calcium in chronic renal failure; it is the homeostatic system, rather than the remodeling system, which is resistant to parathyroid hormone. The effect of mild hyperparathyroidism is a nonspecific increase in bone turnover, of which the best index is the bone formation rate measured by double tetracycline labeling expressed per unit of bone surface. Increased turnover is always accompanied by increased reversible mineral deficit. In prolonged hyperparathyroidism there is also accelerated irreversible bone loss manifested mainly as thinning of cortical bone, detectable in chronic renal failure before any symptoms, due to increased resorption depth on the endocortical surface. In severe hyperparathyroidism resorbed bone is replaced, not by a lesser quantity of normal bone, but by a mixture of vascular fibrous tissue and woven bone, referred to as osteitis fibrosa. In osteomalacia there is increased accumulation of osteoid, due not to increased turnover, but to prolongation of mineralization lag time, which in conjunction with increased thickness, surface and volume of osteoid is diagnostic. Converting histomorphometric data into category assignment discards most of the useful information, which can be retained by two-dimensional representation of severity. For the hyperparathyroid dimension, bone formation rate measured by double tetracycline labeling expressed per unit of bone surface is the most useful although not ideal. For the osteomalacic dimension a mineralization index was constructed that is unaffected by age or race. In patients with osteitis fibrosa, bone formation rate per unit of bone surface and mineralization index were inversely correlated. For the third dimension a structure/formation index was constructed which increases with age in healthy women and shows weak inverse correlation with bone formation rate. The structure/formation index is lower than normal in patients with osteitis fibrosa, and should be useful in the study of osteopenia in chronic renal failure. Bone formation rate is low in osteomalacia, but some patients have subnormal rates through quite a different mechanism. The frequency of this finding has been overestimated for several reasons: failure to exclude atypical osteomalacia (increased surface and volume but not thickness of osteoid), use of inappropriate reference values, and failure to measure the bone formation rate on endocortical and intracortical surfaces. In healthy women bone formation rate can be zero on the cancellous surface alone. Low bone formation rate is sometimes due to diabetes but most often is the expected response to subnormal parathyroid hormone secretion accompanying an excess of calcium, a situation recognized only recently because of improvement in parathyroid hormone assay methodology. Low cancellous bone formation rate should not increase fracture risk because turnover is much lower in the peripheral than in the central skeleton, and all reports of increased fracture risk are flawed or open to different interpretation. Low bone formation rate is associated with reduced skeletal buffering of calcium and increased soft tissue calcification. This is not a new disease needing its own treatment, however, but represents the final stage of skeletal adaptation to a surfeit of calcium. The concept of adynamic bone disease has been harmful by directing attention away from the most important consequence of over-treatment of hyperparathyroidism.     

Bone mineral content of transilial biopsies in patients with hip fracture

In a survey of 125 patients with hip fracture vitamin D deficiency was frequently observed, but overt osteomalacia was not found in the bone biopsies (Lips et al., 1982). In order to detect a possible hypomineralization in these vitamin D-deficient patients, we measured the bone mineral content in 64 transilial biopsies, embedded in methylmethacrylate for histomorphometric evaluation. The results were compared with those of 18 bone samples obtained at autopsy from subjects who did not suffer from metabolic bone disease. The calcium:hydroxyproline ratio, the phosphorus:hydroxyproline ratio, and the calcium:phosphorus ratio were similar in the two groups. The magnesium:hydroxyproline ratio was higher in the hip fracture group than in the controls. The ratios did not correlate with serum concentrations of the vitamin D metabolites. The results are not consistent with a decreased bone mineralization in patients with hip fracture.     

肿瘤相关性成人低血磷骨软化症1例报道

目的报道一例肿瘤相关性低磷骨软化症(tumor-induced hypophosphorus osteomalacia,TIO),提高临床医师对本病的认识。方法对该TIO患者的临床表现、实验室检查、影像学、病理检查和治疗随访结果进行分析和总结。结果该病例支持成人低血磷骨软化症诊断,手术切除右下腹包块,病理符合良性磷酸盐尿性间叶肿瘤(PMT),进一步行FGF-23组化染色,显示FGF-23(+)。术后患者血磷快速恢复正常,尿磷降低;给予适当钙剂和维生素D制剂治疗,随访12周,患者全身疼痛完全缓解,步态恢复正常;随访至24周,患者的骨转换指标、血钙磷基本维持正常;随访36周时骨密度恢复正常,获得临床治愈。结论对于无家族史成人发病的低血磷骨软化症应考虑肿瘤相关性骨软化症的可能,手术切除肿瘤是治疗的关键,FGF-23染色阳性证实了对TIO的诊断。     

Effects of Different Regimens of Sodium Fluoride Treatment for Osteoporosis on the Structure, Remodeling and Mineralization of Bone

We compared initial and final bone histomorphometric findings in 66 osteoporotic patients treated with sodium fluoride (NaF) according to three regimens, and in 7 osteoporotic patients who did not receive NaF. Fourteen patients received continuous NaF 75 mg/day (high-dose) with calcium 1500 mg/day for a mean of 41 months. Twenty-six patients received continuous NaF 50 mg/day (low-dose) with calcium 2000 mg/day for a mean of 15 months, either with (10 patients) or without (16 patients) vitamin D. Twenty-six patients received cyclical low-dose NaF, alternating with vitamin D, for a mean of 15 months and a total treatment duration of 28 months, of whom 14 were and 12 were not on NaF at the time of the second biopsy. Disregarding differences between regimens, there were significant increases in total and mineralized bone volume and trabecular thickness and nonsignificant decreases in these measurements in the control group. Fluoride-induced bone formation was exclusively appositional with no evidence for the creation of new trabeculae. The effect of low-dose NaF on bone structure was the same when the same total dose was given continuously or intermittently, and when the patient was or was not taking vitamin D. The increases in total and mineralized bone volume but not trabecular thickness were greater with high-dose than with low-dose NaF. Low-dose NaF caused modest but significant increases in all osteoid indices, and modest but significant declines in adjusted apposition rate and osteoid maturation rate and no change in bone formation rate. With high-dose NaF, the increase in BV/TV was greater but all indices of osteoid accumulation were much higher and all indices of impaired osteoblast function and mineralization were much lower, and 12 of 14 patients had some form of osteomalacia. This occurred also in 3 of 30 patients treated with low-dose NaF who were not taking vitamin D; the mean increase in osteoid thickness was significantly greater in these patients than in 22 low-dose patients who were taking vitamin D. We conclude: (1) The inconsistent effect of NaF in increasing bone strength is partly due to failure to restore connectivity in patients with severe bone loss and partly due to substantial osteoid accumulation. (2) Even low-dose NaF causes impaired osteoblast function, but this is much greater with high-dose prolonged therapy. (3) There is an unexplained discrepancy between the increase in bone formation implied by increases in spinal bone mineral and the lack of increase in bone formation measured histomorphometrically. (4) Defective mineralization is more closely related to the total cumulative dose of NaF than to the duration of treatment, and with low-dose treatment may be preventable by vitamin D. (5) Future clinical trials should be carried out with smaller doses of NaF and before there has been substantial loss of horizontal trabeculae in the spine. Received: 31 March 1997 / Accepted: 6 February 1998     

Effect of low-calcium hemodialysate on bone metabolism

In the present study, we investigated the kinetics of bone metabolism by determining serum bone metabolic markers and quantifying bone mineral density by dual-energy X-ray absorptiometry to clarify the effect of long-term use of low-calcium hemodialysate on bone metabolism. After changing the calcium concentration in the dialysate from 3.0 mEq/l to 2.5 mEq/l, serum intact parathyroid hormone level, serum highly sensitive parathyroid hormone level, and serum bone metabolic markers were determined in ten patients with chronic nondiabetic renal insufficiency during 1 year. The doses of an oral phosphate binder and activated vitamin D were carefully regulated to control serum ionized calcium levels and serum inorganic phosphorus levels. Bone mineral density was determined at the distal 1/3 and 1/6 of the radius on the nonshunt side. As a result, the required amount of oral phosphate binder was increased; however, there was no need to significantly increase the amount of activated vitamin D. Intact parathyroid hormone showed no significant variation, but the highly sensitive parathyroid hormone was significantly increased. There were no significant changes in any bone metabolic markers or in bone mineral density. From these study results, it was found that it was difficult to increase the dose of activated vitamin D even if low-calcium hemodialysate was used, and that during use of the low-calcium hemodialysate the serum level of parathyroid hormone tended to increase but led to neither acceleration of bone turnover nor a decrease in bone mineral density. Received: Feb. 22, 1999 / Accepted: July 6, 1999     

Osteoporosis and mild metabolic acidosis in the rat after orchiectomy and their prevention: should prophylactic therapy be administered to patients with androgen deprivation?

PURPOSE: To date there has been little research on the etiology and prophylaxis of osteopenia during androgen deprivation. This condition is gaining increasing attention, partially due to the considerable osteoporosis related side effects of hormone withdrawal symptoms in patients with prostate cancer. We characterized androgen deprivation and its prophylaxis. MATERIALS AND METHODS: A total of 36 male Sprague-Dawley rats underwent laparotomy, orchiectomy or orchiectomy with subsequently treatment with calcium acetate and sodium citrate via the water supply. Postoperative observation was 19 weeks. Test parameters were weight development, testosterone, parathyroid hormone, vitamin D, osteocalcin, cross links, hydroxyproline and cyclic adenosine monophosphate as well as bone density, tensile strength, mineral content and histomorphometry. RESULTS: Animals subjected to orchiectomy had a reduction in bone mineral content and fracture energy with mild metabolic acidosis. The markers of bone metabolism were statistically unchanged, while the ratio of trabeculae-to-tissue area decreased. Animals treated with orchiectomy, calcium acetate and sodium citrate had moderately compensated metabolic alkalosis and increased bone minerals. Fracture energy was likewise normal and there was a tendency toward higher bone metabolism. CONCLUSIONS: Castration led to a reduced increase in body mass, considerable standard deviation from biochemical and histological criteria for tubular bone and, thus, an increased fracture risk. A possible cause may be reduced formation and unchanged bone loss combined with mild metabolic acidosis. Calcium and alkalization seem to be effective prophylaxis for androgen deprivation. Considering the large number of osteoporotic complications after androgen deprivation, further clinical studies are justified to show the benefits of prophylactic therapy.     

Bone histology and bone mineral density after correction of acidosis in distal renal tubular acidosis

BACKGROUND: The association between chronic metabolic acidosis and alterations in bone cell functions has been demonstrated in vitro and in animal studies. However, the causal role of acidosis and the effects of alkaline therapy on bone histology and bone mineral density in chronic metabolic acidosis have never been systematically demonstrated in humans. This study was conducted to examine the alterations in bone mineral density and bone histology before and after correction of acidosis among patients with distal renal tubular acidosis (dRTA) METHODS: Correction of metabolic acidosis by potassium citrate was done in non-azotemic dRTA patients, 6 females and 4 males, who had never received long-term alkaline therapy before enrolling into this study. Blood chemistries, serum intact parathyroid hormone, and 24-hour urine collection for the determination of urinary calcium, phosphate, sodium, potassium, bone mineral density determination, and transiliac bone biopsy were done in all patients at baseline and after one year of potassium citrate therapy. RESULTS: Significant elevations in serum bicarbonate (16.5 +/- 3.0 vs. 24.6 +/- 2.8 mEq/L, P < 0.05) and urinary potassium excretion (35.2 +/- 7.9 vs. 55.4 +/-3.5 mEq/L, P < 0.05) were observed after potassium citrate therapy. No significant alterations in other serum and urine electrolytes were found after the therapy. Serum intact parathyroid hormone level was also significantly elevated after one year of treatment (12.8 +/- 7.3 vs. 26.2 +/- 8.7 pg/mL, P < 0.05). Bone formation rate was significantly suppressed at baseline and was normalized by the treatment (0.02 +/- 0.02 vs. 0.06 +/- 0.03 microm(3)/microm(2)/day, P < 0.05). There were non-significant elevations in trabecular bone volume, osteoblastic and osteoclastic numbers. Bone mineral densities in dRTA patients were also significantly decreased below normal values in most studied areas at baseline and were significantly elevated at the trochanter of femur (0.677 +/- 0.136 vs. 0.748 +/- 0.144 g/c m(2), P < 0.05) and total femur (0.898 +/- 0.166 vs. 0.976 +/- 0.154 g/c m(2), P < 0.05) after the treatment. CONCLUSIONS: This study demonstrates that alkaline therapy corrects abnormal bone cell function and elevates bone mineral density in dRTA patients, indicating the causal role of acidosis in the alterations of bone cell functions and reduction in bone mineral density. Parathyroid gland activity also may be involved in the adaptation of the body to chronic metabolic acidosis.