High deposition rate of aluminum in tissues in diabetic hemodialysis patients

Aluminum (Al) accumulation in bone is a serious problem in patients on hemodialysis. We studied deferoxamine infusion test (DFO test) in 14 diabetic patients on hemodialysis (HDDM) and 23 hemodialysis patients originated from glomerulo nephritis (HDCGN) to determine whether Al accumulation is different between the two groups or not. There was no difference in hemodialysis duration and total oral intake of Al containing drugs between two groups. Serum C-terminal parathyroid hormone (C-PTH) in HDDM was lower than that in HDCGN group (1.82 +/- 1.30 vs. 3.80 +/- 1.82 ng/ml; P less than 0.01). However serum Al (s-Al) levels were comparable (61.9 +/- 53.0 vs, 45.0 +/- 32.3 micrograms/l). A significant correlation was observed between duration of dialysis period and s-Al in HDDM (r = 0.806, p less than 0.01), but in HDCGN, the relation was not significant. The patients in HDDM whose cumulative aluminum intake was less than 2.0 kg showed the higher serum A1 concentrations before DFO and greater increases in s-Al after DFO test, as compared with those in HDCGN with matched aluminum intake (93.8 +/- 67.6 vs. 35.9 +/- 23.6 micrograms/l; p less than 0.001 and 141.2 +/- 81.8 vs. 70.3 +/- 41.1 micrograms/l; p = 0.035). These results indicate that in uremic diabetic patients with lower intake of Al containing drugs, an early accumulation of Al in the whole body occurs possibly because of the enhanced absorption rate of Al at an intestine and/or the low PTH level.     

Non-invasive prediction of aluminum bone disease in hemo- and peritoneal dialysis patients.

Between October 1987 and October of 1989, we conducted a prospective study to evaluate non-invasive test strategies for predicting aluminum bone disease (ABD) in a group of largely unselected dialysis patients based on their deferoxamine (DFO) test alone, or the combined results of their DFO test and intact 1-84 parathyroid hormone (PTH) levels. These test parameters were evaluated against the pathological diagnosis of ABD based on bone biopsy ("gold standard"). A total of 445 patients in three dialysis centers in Toronto were serially followed for their clinical, laboratory and risk parameters for renal osteodystrophy during the study, and 259 (142 PD and 117 HD) patients underwent a series of investigations which included the DFO test, measurement of intact 1-84 PTH levels, and an iliac crest bone biopsy. Serum aluminum ([Al]) level greater than or equal to 3700 nM (or 100 micrograms/liter) had a positive predictive value (PPV) of 75% for ABD in our PD and 88% in our HD patients, but its sensitivity was low (10 and 37%). Delta [Al] (that is, incremental rise of serum [Al] from baseline post-DFO) was useful in predicting ABD in our PD but not HD patients. Test combination based on delta [Al] greater than or equal to 5550 nM (or 150 microgram/liter) and PTH levels less than 20 pM (or 200 pg/ml) yielded the best PPV greater than or equal to 95% for ABD in both PD and HD patients. This test cut-off would remain highly predictive of ABD even if the prevalence of ABD decreases to as low as 5% for the PD patients and 10% for the HD patients.(ABSTRACT TRUNCATED AT 250 WORDS)     

Leptin and biochemical markers of bone turnover in dialysis patients

BACKGROUND AND OBJECTIVE: The adipose tissue cytokine leptin is suggested to interfere with bone turnover mechanisms because, in rats with leptin deficiency, intra-cerebroventricular administration of this cytokine causes a reduction in bone mass. We studied the relationship between plasma leptin and biochemical bone turnover indicators in 161 hemodialysis (HD) patients. RESULTS: Plasma leptin was sex-dependent, being significantly higher (p<0.001 ) in female dialysis patients than in male dialysis patients, and it related directly to body mass index (BMI). In males, plasma leptin related inversely to serum intact parathyroid (PTH) (partial r= -0.34), serum PTH(1-84) (r= -0.36), carboxyterminal PTH (C-PTH) fragment (r= -0.31) and serum PTH(1-84)/C-PTH fragment ratio (r= -0.22), while no such relationships were found in females. Of 93 male dialysis patients, 44 had a serum intact PTH <100 pg/mL and 14 had a serum PTH(1-84)/C-PTH fragment ratio <1. In a multiple logistic regression analysis in males, for each 1 ng/mL increase in plasma leptin there was an 11% excess risk of serum intact PTH <100 pg/mL (odds ratio (OR) 1.11, 95% confidence interval (95% CI): 1.02-1.20, p=0.01) and a similar OR was found when low bone turnover was defined based on a serum PTH(1-84)/C-PTH fragment ratio <1 (p=0.01). In addition, plasma leptin related inversely to skeletal alkaline phosphatase and again this relationship was found in male but not in female dialysis patients. CONCLUSIONS: Our data support the theory that leptin reduces bone turnover in male dialysis patients. Whether this link underlies a noxious or a protective mechanism, i.e. if it can serve to limit high bone turnover due to hyperparathyroidism, remains to be established in prospective studies based on solid outcome measures like the risk of fractures.     

Effect of body iron stores on serum aluminum level in hemodialysis patients.

To evaluate the influence of body iron stores on the serum aluminum (Al) level, we studied the correlation between iron status (the serum ferritin, serum iron and transferrin saturation) and serum Al levels in 68 severely anemic hemodialysis patients. Among them, 36 underwent the desferrioxamine (DFO) mobilization test. These 68 patients were divided into three groups according to their serum ferritin level. The basal Al level in the patient group was 41.4 +/- 37.4 micrograms/l (control, 4.1 +/- 2.4 micrograms/l). The serum Al level after DFO infusion of the patient group was 111.1 +/- 86.8 micrograms/l. A significantly higher basal Al and peak Al level after DFO infusion were found in group 1 patients (serum ferritin less than 300 micrograms/l) when compared to group 2 (serum ferritin 300-1,000 micrograms/l) and group 3 (serum ferritin greater than 1,000 micrograms/l) patients. A significant negative correlation between serum ferritin and basal serum Al (r = -0.544, p = 0.0001), as well as peak serum Al after DFO infusion (r = -0.556, p = 0.0001), was noted. Similarly, a negative relationship between serum Al (both basal and peak) and either serum iron or transferrin saturation was noted. However, there was no correlation between the serum Al level and the dosage of aluminum hydroxide. In conclusion, serum ferritin, serum iron and transferrin saturation were inversely correlated with serum Al in our hemodialysis patients. Iron deficiency may probably increase Al accumulation in these patients.     

Diagnostic evaluation of plasma free gamma-carboxyglutamic acid in maintenance hemodialytic patients with renal osteodystrophy

The levels of serum Bone Gla Protein (BGP) and plasma free gamma-carboxyglutamic acid (free gamma-Gla) were measured in 36 patients on maintenance hemodialysis and compared with conventional parameters of renal osteodystrophy (ROD), such as C-PTH, intact PTH, Al-PIII and hydroxyproline levels in serum, and sigma GS/D. Even though the values of BGP were significantly elevated in patients group, 64.5 +/- 1.74 ng/ml, but the low values within normal range could be found in 3 of 36 patients, also. On the other hand, plasma levels of free gamma-Gla were markedly elevated in all cases as high as 10.40 +/- 3.10 nmol/ml in average compared to 1.29 +/- 0.37 nmol/ml (n = 15) in healthy controls. Comparative analysis of BGP with other parameters showed exclusively significant correlation as follows, C-PTH: r = 0.833 (p less than 0.01), intact PTH: r = 0.702 (p less than 0.01), Al-PIII: r = 0.771 (p less than 0.01), hydroxyproline: r = 0.462 (p less than 0.01), sigma GS/D: r = -0.407 (p less than 0.05). Respective for its higher levels, comparative analysis of plasma levels of free gamma-Gla with other parameters failed to show a significant correlation except for correlation with C-PTH (r = 0.459, p less than 0.01). Based upon these results, we could confirm a marked elevation in plasma levels of free gamma-Gla in all patients, but couldn't point out its clinical value in ROD in this study.     

Kinetics of aluminoxamine and feroxamine chelates in dialysis patients.

To achieve a rational basis for the use of deferoxamine (DFO) in aluminum (AL) -and iron (Fe)-overloaded uremic patients, important insights may be provided by the recently available micromethods to determine DFO and its metallochelates aluminoxamine (AlA) and feroxamine (FeA). With this procedure, AlA and FeA plasma kinetics were evaluated in a pilot study in 10 uremic patients during a whole week after a single DFO infusion performed during the first hour of the first standard bicarbonate hemodialysis (HD) of the week. Patients were divided into normal (n = 6) and high (n = 4) ferritin groups (1 and 2 respectively). Baseline Al concentrations were greater than 2 less than 6 in group 1 and less than 1.5 mumol/l in group 2. DFO was given at doses of 40, 20 and 10 mg/kg. AlA and FeA showed substantially different kinetics. AlA kinetics were similar in group 1 and 2: they reached their peak at the beginning of the 2nd HD, decreased during the 2nd and 3rd HD, and with the highest DFO dose still increased between the 2nd and 3rd HD. At similar pre-DFO Al values (greater than 2 less than 3.3 mumol/l), increased DFO doses produced increased AlA concentrations ranging from 95 to 40% of total plasma Al for all the week. At higher pre-DFO Al values (greater than 3.5 less than 6 mumol/l), even a DFO dose as low as 10 mg/kg was sufficient to form consistent AlA amounts (from 80 to 15% of total Al).(ABSTRACT TRUNCATED AT 250 WORDS)     

Parathyroid hormone and growth in children with chronic renal failure

BACKGROUND: In pediatric chronic renal failure (CRF) optimal parathyroid hormone (PTH) concentrations that minimize renal osteodystrophy and maximize growth are unknown. The search for optimum concentrations has been complicated as currently used "intact" PTH (iPTH) assays cross-react with long carboxyl-terminal PTH fragments (C-PTH), which antagonize the biologic actions of 1-84 PTH. The purpose of this study was to investigate the relationship between PTH, the 1-84 PTH:C-PTH ratio and growth rate in children with CRF. METHODS: A total of 162 patients, median (range) age 9.9 years (0.3 to 17.1 years), were recruited: 136 with a glomerular filtration rate (GFR) <60 mL/min/1.73 m(2)[96 managed conservatively (CRF group) and 40 transplanted patients], and 26 dialysis patients. Over a median (range) period of 1.1 years (0.5 to 1.7 years), children attended five (three to 15) clinics at which iPTH, cyclase-activating PTH (CAP-PTH), and height were measured. RESULTS: Mean PTH concentrations were within the normal range for both assays for the CRF group and up to twice the upper limit of normal for the dialysis group; CAP-PTH 24.8 pg/mL and 59.9 pg/mL (normal range 5 to 39 pg/mL), iPTH 37.1 pg/mL, and 102.6 pg/mL, respectively (normal range 14 to 66 pg/mL). The patients grew normally (change in height standard deviation score per year (DeltaHtSDS) =-0.01). There was no relationship between PTH concentrations and DeltaHtSDS in any patient group. The 1-84 PTH:C-PTH ratio was lower in dialyzed patients (P= 0.003), with worsening renal function (P= 0.047) and with PTH concentrations outside the normal range (P= 0.01). There was a weak correlation between the 1-84 PTH:C-PTH ratio and the DeltaHtSDS (r= 0.2, P= 0.01). CONCLUSION: Normal range PTH concentrations are appropriate, allowing normal growth in children with CRF managed conservatively. C-PTH may be of clinical significance.     

Carboxyl-terminal parathyroid hormone fragments: role in parathyroid hormone physiopathology

PURPOSE OF REVIEW: Carboxyl-terminal parathyroid hormone (C-PTH) fragments constitute 80% of circulating PTH. Since the first 34 amino acids of the PTH structure are sufficient to explain PTH classical biological effects on the type I PTH/PTHrP receptor and since C-PTH fragments do not bind to this receptor, they have long been considered inactive. Recent data suggest the existence of a C-PTH receptor through which C-PTH fragments exert biological effects opposite to those of human PTH(1-84) on the type I PTH/PTHrP receptor. This is why a lot of attention has been paid to these fragments recently. RECENT FINDINGS: In vivo, synthetic C-PTH fragments are able to decrease calcium concentration, to antagonize the calcemic response to human PTH(1-34) and human PTH(1-84) and to decrease the high bone turnover rate induced by human PTH(1-84). In vitro, they inhibit bone resorption, promote osteocyte apoptosis and exert a variety of effects on bone and cartilaginous cells. These effects are opposite to those of human PTH(1-84) on the PTH/PTHrP type I receptor. This suggests that the molecular forms of circulating PTH may control bone participation in calcium homeostasis via two different receptors. Clinically, the accumulation of C-PTH fragments in renal failure patients may cause PTH resistance and may be associated with adynamic bone disease. Rare parathyroid tumors, without a set point error, overproduce C-PTH fragments. The implication of C-PTH fragments in osteoporosis is still to be explored. SUMMARY: C-PTH fragments represent a new field of investigation in PTH biology. More studies are necessary to disclose their real importance in calcium and bone homeostasis in health and disease.     

Circulating PTH molecular forms: what we know and what we don't

Circulating parathyroid hormone (PTH) molecular forms have been identified by three generations of PTH assays after gel chromatography or high-performance liquid chromatography fractionation of serum. Carboxyl-terminal (C) fragments missing the amino-terminal (N) structure of PTH(1-84) were identified first. They represent 80% of circulating PTH in normal individuals and up to 95% in renal failure patients. They are regulated by calcium (Ca) slightly differently than PTH(1-84), occurring in a relatively smaller proportion relative to the latter in hypocalcemia but in a much larger proportion in hypercalcemia. Synthetic C-PTH fragments do not bind to the PTH/PTHrP type I receptor and are not implicated in the classical biological effect of PTH(1-84). They bind to a different C-PTH receptor and exert biological actions on bone that are opposite to those of PTH(1-84). The integrity of the distal C-structure appears to be important for these biological effects, and it is uncertain if all C-PTH fragments are intact up to position 84. A second category of C-PTH fragment has a partially preserved N-structure. They are called non-(1-84) PTH or N-truncated fragments. They react in Intact (I)-PTH assays but not in PTH assays with a 1-4 epitope. They are acutely regulated by Ca(2+) concentration. They also exert similar hypocalcemic and antiresorptive effects but have 10-fold greater affinity for the C-PTH receptor compared to other C-PTH fragments. Even if they represent only 10% of all C-PTH fragments, they could be as relevant biologically. An N form of PTH other than PTH(1-84) has been identified in the circulation. It reacts very well in PTH assays with a 1-4 epitope but poorly in I-PTH assay with a 12-18 epitope. It is oversecreted in severe primary and secondary hyperparathyroidism and in parathyroid cancers. Its biological activity is still unknown. Overall, these studies suggest that PTH(1-84) and C-PTH fragments are regulated differently to exert opposite biological effects on bone via two different receptors. This may serve to control bone turnover and Ca concentration more efficiently.     

Improved assessment of bone turnover by the PTH-(1-84)/large C-PTH fragments ratio in ESRD patients

BACKGROUND: The "intact" parathyroid hormone (PTH) assay recognizes PTH-(1-84) as well as amino terminally truncated PTH fragments, that is, large carboxyterminal PTH fragments (C-PTH fragments). The present study investigated whether the use of the plasma PTH-(1-84)/C-PTH fragment ratio enhances the noninvasive assessment of bone turnover in patients on dialysis. METHODS: Bone biopsies and blood samples for determinations of routine indices of bone turnover and PTH peptides were obtained in 51 adult patients on dialysis not treated with drugs affecting bone such as vitamin D or corticosteroids. Blood levels of large C-PTH fragments were calculated by subtracting PTH-(1-84) from "intact" PTH. Patients were classified according to their levels of bone turnover based on histomorphometrically obtained results of activation frequency. Prediction of bone turnover by the various blood indices was done by using proper statistical methods. In addition, hypercalcemia was induced by calcium gluconate infusion in a subset of patients, and levels of PTH-(1-84), "intact" PTH, and PTH-(1-84)/C-PTH fragment ratio were determined. RESULTS: The PTH-(1-84)/C-PTH fragment ratio was the best predictor of bone turnover. A ratio> 1 predicted high or normal bone turnover (sensitivity 100%), whereas a ratio <1 indicated a high probability (sensitivity 87.5%) of low bone turnover. Calcium infusion resulted in decrease in PTH-(1-84)/C-PTH fragment ratio. CONCLUSIONS: The PTH-(1-84)/C-PTH fragment ratio predicts bone turnover with acceptable precision for biological measurements. Moreover, a change in serum calcium levels is one of the regulators of the relative amount of circulating PTH-(1-84) and its large C-PTH fragments.     

Variable parathyroid hormone(1-84)/carboxylterminal PTH ratios detected by 4 novel parathyroid hormone assays

AIM: Parathyroidhormone (PTH) measurement is important in the evaluation of bone disease in patients with chronic renal failure. Large carboxyl-terminal PTH fragments (C-PTH) cross-react with second-generation PTH assays, lead to an overestimation of biologically active PTH, and are evaluated by a combination of second- and third-generation PTH assays. The aim of our study was to examine whether the use of 4 different PTH assays of putatively same specificity leads to comparable results detecting C-PTH fragments. SUBJECTS AND METHODS: In 70 chronic dialysis patients, total PTH and PTH(1-84) were measured in parallel by 4 novel PTH assays (Nichols Advantage Intact PTH and Bio-Intact PTH Chemiluminescence Assay, Nichols Institute Diagnostics, USA, DUO Total and CAP PTH IRMA, Scantibodies Laboratory, USA). The C-PTH concentration was quantitated by subtracting PTH(1-84) from total PTH. Consecutively, the PTH(1-84)/C-PTH ratio was calculated. RESULTS: Nichols Intact PTH and DUO Total PTH assays were highly correlated (r = 0.985), as well as Nichols Bio-Intact and DUO CAP assays (r = 0.984). However, total PTH values measured by the Nichols assay were 30% higher (median (range): 185 (9.9 - 2,332) versus 130 (2.3 - 1,271.1) pg/ml, p < 0.01). PTH(1-84) values, measured by the Nichols Bio-Intact PTH assay were 8% higher compared to the Scantibodies CAP assay (median (range): 79.6 (7.5 - 1,060.9) versus 73.7 (4.4 - 918.9) pg/ml, p = NS). Thirty-six patients had a ratio < 1 measured by the Nichols assays, whereas only 8 patients showed the same ratio when measured by the Scantibodies assays. In 28 patients (40%), contradictory PTH(1-84)/C-PTH ratios were found, showing a ratio < 1 when measured by the Nichols assays, but > 1 when the Scantibodies assays were used. CONCLUSION: In conclusion, our results suggest that the PTH(1-84)/C-PTH ratio cannot be equally used as a predictor of bone turnover when different PTH assays are used. Depending on those assays, differences in total PTH values mathematically lead to varying amounts of C-PTH fragments resulting in variable, even contradictory PTH(1-84)/C-PTH ratios.     

The effect of an iron supplement on serum aluminum level and desferrioxamine mobilization test in hemodialysis patients.

BACKGROUND: The serum aluminum (Al) measurement with desferrioxamine (DFO) mobilization is a screening test for uremic patients with an Al overload. In these patients, body iron status is one of the factors affecting the serum Al level. This study is designed to elucidate the effects of iron supplements on the serum Al and the DFO mobilization test. METHODS: Our study featured ten hemodialysis patients with iron deficiency anemia. The iron supplement was given intravenously with saccharated ferric oxide, 40 mg three times weekly, at the end of each hemodialysis. The total amount of iron supplement was 1,000 mg. All the patients underwent a DFO test at a dose of 5 mg/kg. The same test was repeated two weeks after completion of the iron supplement. RESULTS: After the iron supplement, patients' iron deficiency anemia improved with a serum ferritin elevation from 312.4 +/- 589.5 to 748.2 +/- 566.2 microg/L (p < 0.01), and iron saturation from 21.6 +/- 20.3 to 41.1 +/- 21.7% (p = 0.06). The basal serum Al level decreased from 34.3 +/- 13.8 to 21.8 +/- 8.5 microg/L (p = 0.01). In the DFO mobilization test, the peak serum Al level decreased from 63.4 +/- 19.3 to 50.7 +/- 20.5 microg/L (p < 0.01). The amount of Al increment (deltaAl) in DFO test was not changed (29.1 +/- 12.0 vs. 28.9 +/- 15.9 microg/L, p = 0.86). The change in basal Al level tended to negatively correlate with the percentage of increment in iron saturation (r = -0.628, p = 0.05). CONCLUSION: Results in this study suggest that iron supplements may significantly reduce the basal serum Al and peak Al in DFO mobilization test, without significant change of the mean deltaAl. The data presented indicate that in the interpretation of serum aluminum levels the iron status should be taken into account.     

The diagnostic critical value in DFO low dose loading test on patient with aluminum accumulation compared to each parameter of ROD

One hundred two hemodialyzed patients were examined to determine the standard level of delta Al value which is the difference of serum Al concentrations between pre and post DFO loading test. We applied low dose of DFO 15 mg/kg in this loading test. Some significant negative correlations were found between delta Al and MCI, sigma GS/D, osteocalcin, free-Hydroxyproline (dialysate) and free-gamma-Carboxyglutamic acid (dialysate). Each correlation rate was -0.58, -0.44, -0.76, -0.57 and -0.51 respectively. In addition tendencies of correlation were found between delta Al and ALP and between delta Al and %QCT (QCT/mean QCT in patient's age x 100). And statistical significant differences were found between (0 less than delta Al less than or equal to 150 micrograms/l) group and (150 micrograms/l less than delta Al) group in each osteobiochemical parameter. These results indicate that 150 micrograms/l is the lower diagnostic standard level of delta Al in 15 mg/kg DFO loading test.     

Low-dose desferrioxamine test for the diagnosis of aluminium-related bone disease in patients on regular haemodialysis

Bone biopsy in an invasive method of diagnosing aluminium related bone disease (ABD). Toxic side-effects have been reported with the currently used 'high-dose Desferrioxamine (DFO) tests.' A low-dose DFO test was evaluated for the diagnosis of ABD in 28 symptomatic patients (13 male) on regular haemodialysis treatment. DFO 0.5 g diluted in 100 ml of 0.9% sodium chloride was given intravenously during the first 2 h of dialysis. Aluminium estimation before (t1) and 48 h after DFO challenge (t2) were made by DC plasma emission spectrometry. Following the DFO test bone biopsy was performed and the specimen stained for aluminium using soluchrome zurine. The DFO test was considered positive if the t2 concentration was 150 micrograms/l or treble the amount of t1. Nineteen patients (8 male) fell into this group and all except two had ABD. Of the nine remaining patients (5 male) who had a negative DFO test none had ABD. We conclude that ABD can be diagnosed safely in the majority of patients using a low-dose DFO test, thereby avoiding toxic side-effects.     

Deferoxamine test and bone disease in dialysis patients with mild aluminum accumulation

Aluminum bone disease is a frequent complication of dialysis patients. The deferoxamine (DFO) test has been advocated as a noninvasive procedure for the diagnosis of AI bone lesion. However most of these studies have been performed in symptomatic patients with significant AI bone disease. Whether this test may provide similar data at an earlier stage of AI toxicity is not known. The present study evaluates prospectively 28 patients with mild AI load. Patients studied ranged in age from 21 to 65 years; duration of dialysis was 5.6 +/- 3.2 years; deferoxamine, 40 mg/kg body weight, was infused at the end of dialysis. Serum AI was measured before DFO administration and before the next dialysis treatment. Bone biopsies were performed in all patients. Cortical bone AI was determined biochemically; trabecular and cortical bone AI were also determined histochemically. Mean basal serum AI (43.2 +/- 30.8 micrograms/L) and cortical bone AI (25.7 +/- 35.2 micrograms/g) were moderately increased. Basal serum AI correlated (r = 0.77) with the increment in serum AI after DFO infusion. After DFO, stainable trabecular and cortical bone AI correlated in a similar manner with both basal serum AI and increment in serum AI. Only biochemically determined cortical bone AI was not significantly related to basal serum AI. Nineteen of the 28 patients had evidence of osteitis fibrosa on bone biopsy. Stained AI surfaces but not trabecular AI were different in patients with low and patients with high bone formation rates. The bone findings, assessed as bone formation rates and resorption surfaces, did not correlate with biochemically or histochemically determined bone AI.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of a low calcium dialysate on parathyroid hormone secretion in diabetic patients on maintenance hemodialysis.

Diabetic patients on maintenance dialysis often are characterized by a relative parathyroid hormone (PTH) deficiency and a form of renal osteodystrophy with low bone turnover known as adynamic bone. The goal of the present study was to determine whether a reduction in the dialysate calcium concentration would increase the predialysis (basal) PTH and maximal PTH level. Thirty-three diabetic maintenance hemodialysis patients with basal PTH values less than 300 pg/ml were randomized to be dialyzed with either a regular (3.0 mEq/liter or 3.5 mEq/liter, group I) or low (2.25 mEq/liter or 2.5 mEq/liter, group II) calcium dialysate for 1 year. At baseline and after 6 months and 12 months of study, low (1 mEq/liter) and high (4 mEq/liter) calcium dialysis studies were performed to determine parathyroid function. At baseline, basal (I, 126+/-20 vs. II, 108+/-19 pg/ml) and maximal (I, 269 pg/ml+/-40 pg/ml vs. II, 342 pg/ml+/-65 pg/ml) PTH levels were not different. By 6 months, basal (I, 98+/-18 vs. II, 200+/-34 pg/ml, p = 0.02) and maximal (I, 276 pg/ml+/-37 pg/ml vs. II, 529 pg/ml+/-115 pg/ml; p = 0.05) PTH levels were greater in group II. Repeated measures analysis of variance (ANOVA) of the 20 patients who completed the entire 12-month study showed that only in group II patients were basal PTH (p = 0.01), maximal PTH (p = 0.01), and the basal/maximal PTH ratio (p = 0.03) different; by post hoc test, each was greater (p < 0.05) at 6 months and 12 months than at baseline. When study values at 0, 6, and 12 months in all patients were combined, an inverse correlation was present between basal calcium and both the basal/maximal PTH ratio (r = -0.59; p < 0.001) and the basal PTH (r = -0.60; p < 0.001). In conclusion, in diabetic hemodialysis patients with a relative PTH deficiency (1) the use of a low calcium dialysate increases basal and maximal PTH levels, (2) the increased secretory capacity (maximal PTH) during treatment with a low calcium dialysate suggests the possibility of enhanced parathyroid gland growth, and (3) the inverse correlation between basal calcium and both the basal/maximal PTH ratio and the basal PTH suggests that the steady-state PTH level is largely determined by the prevailing serum calcium concentration.     

Accelerated removal of deferoxamine mesylate-chelated aluminum by charcoal hemoperfusion in hemodialysis patients

Although deferoxamine mesylate (DFO) is effective in removing aluminum (Al) in hemodialysis patients, treatment with this drug is associated with a number of adverse effects. In order to limit the exposure of patients to DFO-Al complexes, the efficacy of colloidin-coated microencapsulated charcoal cartridges added in series to conventional dialyzers was investigated. The clearances of Al by the sorbent system were initially 116 +/- 4.7 mL/min, but decreased to 42.5 +/- 6.6 mL/min after 120 minutes of treatment. Thereafter, the Al clearances remained constant. In contrast, the Al clearances of the dialyzer were 29.5 +/- 1.8 mL/min initially and did not change during the treatment period. Both the percent and absolute decrease in Al levels after four hours of dialysis were greater with the dialyzers plus carbon cartridges than with the dialyzers alone. This resulted in an increase in the minimum net Al removal from 1,862 +/- 174 micrograms/treatment to 3,007 +/- 43 micrograms/treatment (P less than 0.05). Treatment with sorbent hemoperfusion should be considered in selected hemodialysis patients being treated with DFO for Al overload.     

Thyroparathyroidectomy modifies the skeletal response to aluminum loading in the rat

Diminished parathyroid hormone (PTH) secretion may contribute to the accumulation of aluminum (Al) in bone and to impaired bone formation in Al-related bone disease. Therefore, intact (AL, N = 9) and thyroparathyroidectomized (TPTX-AL, N = 9) rats were given intraperitoneal injections of Al, 2 mg/day, for 42 days; intact control (C, N = 11) and TPTX control (TPTX-C, N = 9) animals received i.p. injections of vehicle only. Quantitative bone histology and measurements of mineralized bone formation (Rbf) using double tetracycline labeling were done for cortical and for trabecular bone; trabecular bone aluminum content (BA) was determined by histochemical methods. BA did not differ between AL and TPTX-AL, 33 +/- 13% versus 39 +/- 14%, and Rbf decreased similarly from control values in both Al-treated groups. In contrast, osteoid production was impaired to a greater extent in TPTX-AL than in AL. Thus, osteoid area and osteoid seam width were each lower in TPTX-AL than in TPTX-C; these values did not differ between AL and C. TPTX can aggravate Al induced reductions in osteoid synthesis, and low serum PTH levels may contribute to the pathogenesis of aplastic bone. However, reductions in Rbf during Al loading are not mediated by PTH.     

The effects of discontinuation of aluminum exposure on aluminum-induced osteomalacia

Studies in patients on dialysis have shown that aluminum (Al) accumulation in bone plays a major role in the pathogenesis of osteomalacia. It has been suggested that deferoxamine (DFO) may be beneficial in the treatment of aluminum-induced osteomalacia. The present studies were performed in four groups of uremic rats to determine if DFO and/or discontinuation of Al administration have an effect on bone histomorphometry and blood chemistries. The groups were: 1) uremic control 2) aluminum (0.75 to 1.0 mg/rat i.p., five times a week for twelve weeks): 3) aluminum + DFO, after twelve weeks Al was discontinued and the rats received DFO (75 mg/rat two times a week for nine weeks); 4) aluminum + time, after twelve weeks Al was discontinued and the rats were sacrificed after nine weeks. High levels of Al in serum and bone and low levels of PTH were seen in rats receiving Al. Bone histology revealed Al at the mineralization front, abnormal tetracycline uptake, and an increase in osteoid. DFO treatment did not significantly change the level of Al in bone, however both DFO treatment and discontinuation of Al reversed towards normal the above described lesions. In conclusion, these studies suggest that DFO and/or discontinuation of Al administration to rats with approximately 30% of renal function greatly improve aluminum-induced osteomalacia.     

Deferoxamine and coated charcoal hemoperfusion to remove aluminum in dialysis patients

We studied the in vitro and in vivo characteristics of aluminum (Al) removal by coated charcoal hemoperfusion (HP) in combination with intravenous deferoxamine (DFO). DFO enhanced the clearance of Al by HP in vitro after 180 minutes of perfusion with a solution containing 403.3 +/- 14.0 ng/ml of Al at 150 ml/min. The Al clearance was 139 +/- 1.0 ml/min with DFO and 49 +/- 10.0 ml/min (P less than 0.001) without DFO. Addition of DFO enhanced in vitro Al removal from 5.5 +/- 0.9 mg to 10.0 +/- 1.2 mg (P less than 0.05). During our in vivo studies, an HP device was in series in the dialysis circuit after a Cuprophan hemodialyzer. Eight patients with Al toxicity were studied on twelve occasions. Patients received DFO (40 mg/kg) 40 hours before the study. The total Al clearance with the combined hemodialysis (HD) and HP devices was higher than that obtained by the dialyzer alone at 30 minutes (62 +/- 4.9 ml/min vs. 25 +/- 2.5 ml/min, P less than 0.02) and after 180 to 210 minutes (32 +/- 3.0 ml/min vs. 19 +/- 2.9 ml/min, P less than 0.02). After 120 minutes the Al clearance by the HP device alone was significantly lower than the initial Al clearance by HP. Combined HD plus HP removed 2.9 +/- 0.4 mg of Al, whereas the total removal of Al by HD alone was 1.5 +/- 0.3 mg (P less than 0.01).