Department of Internal Medicine, Krankenhaus der Barmherzigen Brüder, Graz, Austria
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Abstract |
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Methods. Forty-six subjects (41 females, 5 males) with osteopenia or osteoporosis were studied. In none of the subjects were overt metabolic acidosis, derangement of potassium homeostasis, or renal insufficiency present. Distal tubular acidification was studied by means of oral ammonium chloride loading test (0.1 g/kg body weight) and the oral frusemide test (40 mg). In addition the frusemide test was performed in 20 healthy age- and sex-matched controls (17 females, 3 males).
Results. In all control subjects a urinary pH <5.5 was observed following the ingestion of 40 mg frusemide. In contrast, in patients with reduced bone mineral density incomplete renal tubular acidosis type I (RTA I) was diagnosed in 10 of 46 subjects (22%) by oral ammonium chloride loading test. Disorders possibly related to RTA I were detected in eight of these 10 patients. Thirty-six patients had a normal urinary pH response following oral ammonium chloride loading. Oral frusemide, 40 mg, failed to lower urinary pH <5.5 in sixteen patients (35%), these included 10 subjects with incomplete RTA I, and six subjects with a normal oral ammonium chloride loading test. An abnormal frusemide test was found in 35% of patients with reduced bone mass and in none of the normal controls (2=7.39; P<0.01). With the ammonium chloride test as the gold standard for diagnosis of distal RTA, the frusemide test showed a sensitivity of 1.0 (95% CI, 0.691.0) and a specificity of 0.89 (95% CI, 0.780.96) for the diagnosis of distal RTA. Patients with incomplete RTA I were younger than those without incomplete RTA I (42±16 vs 54±14 years; P=0.025; mean±SD). Basal serum bicarbonate concentrations and capillary pH did not differ between the groups.
Conclusion. Incomplete RTA I may be prevalent in a significant proportion of patients suffering from osteopenia or osteoporosis. The outcome of the frusemide test suggests either a defect of the H+ATPase in the cortical collecting tubule (CCT) or a defective Na+ reabsorption in the CCT. Prospective studies are needed to further elucidate the impact of incomplete RTA I on the development of reduced bone mineral content.
Keywords: acidosis; metabolic acidosis; osteopenia; osteoporosis; renal tubular acidosis; RTA I
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Introduction |
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Subjects with a reduced renal acid excretory reserve, e.g. in the setting of incomplete distal renal tubular acidosis (renal tubular acidosis type I (RTA I)), may be at extra risk of bone mineral loss especially when ingesting the usual mixed Western diet. Recently we observed a high prevalence of incomplete distal tubular acidosis and primary osteoporosis [3]. The current study was undertaken to estimate the prevalence of incomplete RTA I in subjects with a reduced bone mineral content as compared to subjects with a normal bone density and to further define the mechanism of RTA I in this group of patients. A secondary goal was to study the test characteristics of the frusemide test.
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Subjects and methods |
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In all subjects (patients and controls) bone mineral density was assessed at the lumbar site (L2L5) using dual energy X-ray absorptiometry on a Sophos XLA machine. According to the criteria proposed by the World Health Organization (WHO), osteopenia and osteoporosis were diagnosed by a reduced bone mineral density (t-score -1.0 to -2.5, or t-score <-2.5 respectively) measured by DXA [4]. Any radiological evidence of vertebral fractures was also taken as a diagnostic criterion of osteoporosis. Applying these diagnostic criteria, 20 patients (43%) had osteopenia and 26 patients (57%) had osteoporosis. The baseline characteristics of the study population are shown in Table 1.
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The classical causes of secondary osteoporosis (glucocorticoid excess, hyperthyroidism, primary hyperparathyroidism) were ruled out by measurement of thyroid hormone (free T3, free T4, basal TSH), serum calcium and iPTH, and on the basis of clinical examination and patient history.
In none of the patients were renal insufficiency or overt metabolic acidosis present. The presence of RTA type IV (due to hyporeninaemic hypoaldosteronism) was considered unlikely because of normal serum potassium concentrations. Urinary pH was measured with a KCl electrode (pH-meter E 512, Metrohm, Herisau, Switzerland). Urinary tract infection was ruled out by urinalysis.
In all 46 patients both an oral ammonium chloride (NH4Cl) loading test and an oral frusemide test was performed; in 20 controls the frusemide test was done. In addition, three patients with a positive frusemide test and a negative NH4Cl loading test consented to a fludrocortisone-modified frusemide test [5].
Prior to the frusemide loading test patients were off diuretics and non-steroidal anti-inflammatory drugs (NSAID) for at least 2 days. The patients were given 40 mg of frusemide orally and urinary pH was measured 0, 2, 4, and 6 h after the frusemide dose [6]. In case of the fludrocortisone-modified frusemide test, oral frusemide was preceded on the previous evening by 0.5 mg of fludrocortisone. At least 2 days after the frusemide test the standardized short course oral NH4Cl test was performed [7]. Briefly, patients ingested 0.1 g/kg body weight of NH4Cl in gelatin capsules. Blood gas analysis was performed from capillary blood with an AVL 995 Hb automatic blood gas system (AVL, Graz, Austria) on an hourly basis. The metabolic acidosis induced by the NH4Cl load was documented by a fall of serum concentrations >3 mmol/1 and a pH <7.35. Urinary pH was measured at baseline and 2, 4, and 6 h after the completion of NH4Cl intake. Failure to lower urinary pH to less than 5.5 is consistent with some form of distal RTA I [4]. Each subject drank at least 500 ml of water during the test.
Statistical analysis
The t-test of untransformed data was used for group comparison of patients with and without a normal response in the NH4Cl test. A P value <0.05 was considered as significant. Data are shown as mean and ±SD. The 95% confidence interval (CI) of relative frequencies was derived from the binomial distribution. Absolute frequencies were compared by the 2 test.
With the NH4Cl test as the gold standard for the diagnosis of distal RTA, the diagnostic performance of the frusemide test was evaluated in terms of sensitivity and specificity. The failure to lower urinary pH <5.5 both in the NH4Cl and the frusemide test was considered as a true positive (TP) result, whereas an appropriate urinary acidification in both tests was scored as a true negative (TN) outcome. False positive (FP) and false negative (FN) frusemide tests were defined accordingly. Sensitivity was defined as TP/(TP+FN), specificity was defined as TN/(TN+FP) [8].
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Results |
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Serum bicarbonate, capillary pH, pCO2, serum creatinine, and potassium were within the normal range and did not differ between the two groups (Table 1).
In the group of patients with normal NH4CI testing but an abnormal frusemide test (n=6) serum bicarbonate (23.5±1.2 mmol/l), capillary pH (7.4±0.02), and capillary pCO2 (38.3 mmHg), serum creatinine (0.9±0.15 mg/dl), and serum potassium (4.2± 0.39 mmol/l) were also not different from those in subjects (n=30) with normal responses in either diagnostic procedure.
Patients with incomplete RTA I presented on average 12 years younger as compared to patients without RTA I (95% CI, 1.622.4 years; P=0.025; Table 1). Four of 26 (15%) patients with osteoporosis and six of 20 patients with osteopenia (30%) had incomplete RTA I.
In eight of the 10 subjects with incomplete RTA I, the following disorders possibly related to incomplete RTA I were present: nephrolithiasis and hypercalciuria (n=2), autoimmune thyroid disease (n=2), long-term habitual analgesic abuse (n=2), nephrocalcinosis due to medullary sponge kidney disease (n=1), and a familial history of RTA I in one patient. In two patients with incomplete RTA I, no associated disorders were revealed. In those six subjects with a normal NH4Cl test but an abnormal urinary pH response to oral frusemide, a past history of nephrolithiasis without current hypercalciuria (n=1), and autoimmune thyroid disease (n=1) were present. In the 30 patients with both a normal frusemide and NH4Cl test, hypercalciuria (n=2), habitual analgesic (n=2), and a past history of nephrolithiasis without current hypercalciuria (n=2) were recognized.
With the NH4Cl test as the gold standard for diagnosis of distal RTA the frusemide test showed a sensitivity of 1.0 (95% CI, 0.691.0) and a specificity of 0.89 (95% CI, 0.780.96).
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Discussion |
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The RTA syndromes encompass a disparate group of disorders that have in common an inability to excrete acid that is out of proportion to any reduction in glomerular filtration rate. RTA type I involves defects of acid excretion confined to the distal tubule. The hallmark of overt RTA type I is a hyperchloraemic metabolic acidosis accompanied by a reduced net acid excretion and the inability to lower urinary pH below 5.5 in the face of spontaneous acidaemia or after acid loading. In the complete form of RTA I plasma concentration is typically reduced. Incomplete RTA I may be suspected if in random urine spot samples urinary pH is
5.5 [4]. The definite diagnosis of incomplete RTA I requires the induction of a systemic metabolic acidosis by means of acid loading. Among the various acid-loading protocols the NH4Cl loading test introduced by Wrong and Davies [13] has recognized wide-spread clinical application. Since dissolved NH4Cl may cause abdominal discomfort and even vomiting we preferred to administer NH4Cl in gelatin capsules. In this gelatin form the test was better tolerated and no vomiting was observed. To give reliable results systemic acidosis has to be induced by the NH4Cl load. A fall of capillary pH below 7.35 in conjunction with a fall of serum
concentration >3 mmol/l is considered to reflect a sufficient degree of acidaemia [5], which was observed in all test subjects. The NH4Cl loading test was performed in all 46 subjects, resulting in an inadequate urinary acidification in 10 patients, who therefore were diagnosed having incomplete RTA I. Overt metabolic acidosis was not observed in these patients which is compatible with the incomplete type of RTA I.
Unfortunately, the NH4Cl test is frequently accompanied by abdominal discomfort, even when encapsulated NH4Cl is used. None of the patients studied by us agreed to a prolonged NH4Cl loading test over 3 days.
RTA I resembles a diagnosis with a variety of underlying aetiologies. Despite a recognized association of RTA I with disorders such as medullary sponge kidney, hypercalciuria, analgesic nephropathy, and immuno-mediated diseases such as lupus nephritis, Sjögren syndrome, and Graves disease [14], the cause of RTA I in some patients remains obscure. Recently, in some of these idiopathic forms of RTA I the absence of H+ATPase in the intercalated cells has been shown [15]. In all but two patients of the RTA I group a thorough work-up revealed disorders with a recognized association with RTA I. In addition, in two of the six patients with an abnormal frusemide test and a normal NH4Cl test disorders possibly related to distal tubular acidification disturbances were present. One may speculate that in some of these patients these disorders may have contributed to the blunted urinary pH response following oral frusemide.
Acidification in the collecting tubules (CT) is primarily achieved via H+ secretion by a luminal H+ATPase [16]. This pump is located in the intercalated cells of the cortex and in the medulla. The H+ secretion by intercalated cells of the cortical collecting tubule (CCT) is indirectly influenced by the Na+ reabsorption of the adjacent principal cells, since the removal of Na+ from the tubular fluid generates a lumen-negative potential which facilitates net H+ secretion by minimizing the degree of passive proton back-diffusion. Any reduction of Na+ reabsorption in the CCT diminishes the degree of lumen negativity (a condition called voltage-dependent defect) and results in a reduced H+ net secretion and an inability to lower the urinary pH. Application of frusemide provides a means of increasing the delivery of sodium to the sites of distal Na+ reabsorption. Following a rise in intraluminal sodium the Na+ reabsorption in the CCT increases [6] followed by a decrease of tubular fluid pH. In RTA I a common problem is thought to be a defect in the H+ATPase pump that may be present in the cortex and/or the medulla. Patients with this type of RTA I may or may not respond normally to the administration of frusemide. In situations where the H+ATPase defects are limited to the medullary collecting duct, an acidification of the urine may be expected, since the medullary H+ secretion is essentially Na+ dependent [17]. In contrast, a defective H+ secretory pathway in the CCT is expected to cause an inability to lower the urinary pH following frusemide application. The response of urinary pH to frusemide may be blunted by the presence of amiloride-type diuretics [18], NSAIDs, and volume contraction. Therefore we took care to perform the tests in clinically euvolaemic patients being off diuretics and NSAIDs for at least 2 days. The outcome of the frusemide test in the 10 patients with incomplete RTA I studied by us suggests either a defect of the H+ATPase in the CCT or a defective Na+ reabsorption in the CCT, whereas a defective H+ secretion in the medullary collecting tubules seem to be unlikely.
A dose of 40 mg frusemide given orally was chosen since none of the patients studied had renal insufficiency (the maximum serum creatinine concentration in the study population was 1.1 mg/dl) and since we wanted to avoid significant volume depletion. In patients with renal insufficiency a dose of 80 mg frusemide has been advocated in order to overcome the accompanying resistance to frusemide [19]. Circumstantial evidence from a non-osteoporotic female with a body weight of 111.5 kg and normal renal function showed that the oral dose of 40 mg may be too low in obese subjects; in this subject, 80 mg of frusemide were necessary to produce a normal urinary acidification. None of the patients studied was overweight. It has been suggested recently that the administration of a mineralocorticoid such as fludrocortisone on the evening preceding the frusemide test may reduce the frequency of false positive results of the frusemide test [5]. In our hands, a fall of urinary pH <5.5 was not observed in the three frusemide-positive and NH4Cl-negative subjects who agreed to a fludrocortisone-modified frusemide test, supporting the view that some form of tubular dysfunction is present. In future studies, the additional measurement of urinary citrate and excretion may provide additional insights into the renal acid handling.
A distal acidification defect was found in 10 of 46 patients (22%; CI, 1136%) with reduced bone mineral content patients when tested by the NH4Cl test and in as many as 16 of 46 (35%; CI, 2150%) by the frusemide test. When interpreting these frequencies one has to appreciate that the primary aim of the study was not to estimate the prevalence rates of RTA I in patients with osteoporosis or osteopenia. However, it is noteworthy that renal acidification was normal in all 20 subjects with normal bone density. Since the patients studied were referred to the hospital because of suspected osteoporosis, data are not controlled for referral bias. Studies in a randomly selected group of patients with osteopenia or osteoporosis as compared to matched controls with normal bone densities are needed to obtain an unbiased estimation of the prevalence of renal acidification defects.
It is interesting to note that subjects with incomplete RTA I presented at an earlier age (Table 1). Admittedly, this observation may arise from patient selection due to referral bias, but it is attractive to speculate that subjects with incomplete RTA I are prone to a more rapid loss of bone mineral and therefore present at a younger age. Clearly, an additional prospective study in an age- and sex-matched group of patients with and without incomplete RTA I is needed to define the rate of bone loss in patients with incomplete RTA I.
In conclusion, incomplete RTA I, both primary and secondary, is prevalent in patients suffering from reduced bone mineral content. Because of a reduced renal acid excretory reserve in these subjects the ingestion of nutrients stimulating the endogenous acid production (e.g. a diet rich in proteins) may induce a positive acid balance which eventually promotes the release of alkali and calcium from the bone.
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Acknowledgments |
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Notes |
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References |
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