The use of the urinary anion gap in the diagnosis of hyperchloremic metabolic acidosis

We evaluated the use of the urinary anion gap (sodium plus potassium minus chloride) in assessing hyperchloremic metabolic acidosis in 38 patients with altered distal urinary acidification and in 8 patients with diarrhea. In seven normal subjects given ammonium chloride for three days, the anion gap was negative (-27 +/- 9.8 mmol per liter) and the urinary pH under 5.3 (4.9 +/- 0.03). In the eight patients with diarrhea the anion gap was also negative (-20 +/- 5.7 mmol per liter), even though the urinary pH was above 5.3 (5.64 +/- 0.14). In contrast, the anion gap was positive in all patients with altered urinary acidification, who were classified as having classic renal tubular acidosis (23 +/- 4.1 mmol per liter, 11 patients), hyperkalemic distal renal tubular acidosis (30 +/- 4.2, 12 patients), or selective aldosterone deficiency (39 +/- 4.2, 15 patients). When the data on all subjects studied were pooled, a negative correlation was found between the urinary ammonium level and the urinary anion gap. We conclude that the use of the urinary anion gap, as a rough index of urinary ammonium, may be helpful in the initial evaluation of hyperchloremic metabolic acidosis. A negative anion gap suggests gastrointestinal loss of bicarbonate, whereas a positive anion gap suggests the presence of altered distal urinary acidification.     

The acidosis of cholera. Contributions of hyperproteinemia, lactic acidemia, and hyperphosphatemia to an increased serum anion gap

To study the metabolic acidosis that occurs during the diarrhea of cholera, we examined the serum anion gap in 21 patients with hypovolemic shock due to Vibrio cholerae infection. Measurements of serum electrolytes, as well as divalent cations and the anionic contributions of serum proteins, lactate, phosphate, and serum creatinine, were made at the time of admission, after rehydration, and during convalescence. At the time of admission, the mean serum concentration of sodium was 134.8 mmol (meq) per liter, that of chloride was 103.2 mmol per liter, and that of bicarbonate was 11.4 mmol per liter; the mean anion gap was 20.2 mmol per liter. The mean serum creatinine concentration was 2.48 mg per deciliter. The low serum bicarbonate level and the high serum anion gap were corrected by rehydration. The increased serum anion gap was caused by hyperproteinemia, lactic acidemia, and hyperphosphatemia, with anionic contributions to the rise in anion gap estimated as protein, 5.5 meq per liter; lactate, 2.5 meq per liter; and phosphate, 2.5 meq per liter. The hyperproteinemia was attributed to dehydration, the lactic acidemia to shock, and the hyperphosphatemia to acidosis and transient renal failure. The mean concentrations of serum calcium and magnesium were slightly elevated but did not affect the increased anion gap. These results indicate that severe cholera causes acidosis with relatively little change in serum chloride but an increased serum anion gap. The acidosis is more profound than would be expected on the basis of stool losses of bicarbonate, because of superimposed lactic acidemia and renal failure.     

Metabolic acidosis

Acute metabolic acidosis is frequently encountered in critically ill patients. Metabolic acidosis can occur as a result of either the accumulation of endogenous acids that consumes bicarbonate (high anion gap metabolic acidosis) or loss of bicarbonate from the gastrointestinal tract or the kidney (hyperchloremic or normal anion gap metabolic acidosis). The cause of high anion gap metabolic acidosis includes lactic acidosis, ketoacidosis, renal failure and intoxication with ethylene glycol, methanol, salicylate and less commonly with pyroglutamic acid (5-oxoproline), propylene glycole or djenkol bean (gjenkolism). The most common causes of hyperchloremic metabolic acidosis are gastrointestinal bicarbonate loss, renal tubular acidosis, drugs-induced hyperkalemia, early renal failure and administration of acids. The appropriate treatment of acute metabolic acidosis, in particular organic form of acidosis such as lactic acidosis, has been very controversial. The only effective treatment for organic acidosis is cessation of acid production via improvement of tissue oxygenation. Treatment of acute organic acidosis with sodium bicarbonate failed to reduce the morbidity and mortality despite improvement in acid-base parameters. Further studies are required to determine the optimal treatment strategies for acute metabolic acidosis.     

Hypokalaemic paralysis revealing Sjögren syndrome in an elderly man.

A 73 year old white man presented with life threatening hypokalaemic paralysis requiring admission to an intensive care unit. Biochemical investigations showed severe hypokalaemia with hyperchloraemic metabolic acidosis, a spot urine pH of 6.5, and a positive urinary anion gap, establishing the diagnosis of distal renal tubular acidosis. Autoimmune tests revealed Sjögren syndrome as the underlying cause of the distal renal tubular acidosis. Full recovery followed potassium and alkali replacement. This dramatic presentation of Sjögren syndrome has not previously been reported in an elderly man.     

Primary distal renal tubular acidosis: a case report

The primary distal renal tubular acidosis is characterized biochemically by the inability of the kidney to produce appropriately acid urine in the presence of systemic metabolic acidosis or after acid loading (e.g. ammonium chloride). It is secondary to defective excretion of H(+) by the cells of the collecting duct. We report the observation of the child MC, 4-year-old, for whom the association of polyuria-polydipsia syndrome, a failure to thrive, nephrolithiasis, hypercalciuria, and especially a high urine pH in the presence of metabolic acidosis did evoke diagnosis of distal renal tubular acidosis. An urine acidification test with ammonium chloride was performed, the urinary pH was always higher than 5.5, thus confirming the diagnosis.     

Diffuse lymphomatous infiltration of kidney presenting as renal tubular acidosis and hypokalemic paralysis: case report

We report the case of a 22-year-old woman who presented with acute onset flaccid quadriparesis. Physical examination showed mild pallor with cervical and axillary lymphadenopathy, hepatomegaly, and bilateral smooth enlarged kidneys. Neurological examination revealed lower motor neuron muscle weakness in all the four limbs with hyporeflexia and normal sensory examination. Laboratory investigations showed anemia, severe hypokalemia, and metabolic acidosis. Urinalysis showed a specific gravity of 1.010, pH of 7.0, with a positive urine anion gap. Ultrasound revealed hepatosplenomegaly with bilateral enlarged smooth kidneys. Renal biopsy was consistent with the diagnosis of non-Hodgkin lymphoma (B cell type). Metabolic acidosis, alkaline urine, and severe hypokalemia due to excessive urinary loss in our patient were suggestive of distal renal tubular acidosis. Renal involvement in lymphoma is usually subclinical and clinically overt renal disease is rare. Diffuse lymphomatous infiltration of the kidneys may cause tubular dysfunction and present with hypokalemic paralysis.     

Proximal renal tubular acidosis in methylmalonic acidemia

A patient with methylmalonic acidemia was found to have a persistent hyperchloremic acidosis. Investigation documented the presence of a proximal renal tubular acidosis. Between 14 and 18 months of age the urinary pH was as high as 8.0 when the serum bicarbonate was 17 mEq/liter and the threshold for bicarbonate was at 16-17 mEq/liter. When restudied at 33 months of age, the threshold had risen to 20 mEq/liter, but this was still abnormal and supplemental treatment was required to keep the serum concentration of bicarbonate above 20 mEq/liter. It is postulated that organic acid metabolites which accumulate in this and related disorders may interfere with renal tubular function as has been shown for maleic acid in experimental animals.     

Proximal Renal Tubular Acidosis in Methylmalonic Acidemia

A patient with methylmalonic acidemia was found to have a persistent hyperchloremic acidosis. Investigation documented the presence of a proximal renal tubular acidosis. Between 14 and 18 months of age the urinary pH was as high as 8.0 when the serum bicarbonate was 17 mEq/liter and the threshold for bicarbonate was at 16-17 mEq/liter. When restudied at 33 months of age, the threshold had risen to 20 mEq/liter, but this was still abnormal and supplemental treatment was required to keep the serum concentration of bicarbonate above 20 mEq/liter. It is postulated that organic acid metabolites which accumulate in this and related disorders may interfere with renal tubular function as has been shown for maleic acid in experimental animals.     

Kinetics of luminal acidification in cortical tubules of the rat kidney.

1. Some kinetic aspects of renal tubular acidification were studied in proximal and distal tubules of the rat kidney by combining stationary microperfusion methods and continuous measurements of luminal pH changes of phosphate or bicarbonate buffers by means of antimony electrodes. The analysis included the measurement of steady-state pH, steady-state buffer concentrations and acidification half-times. From these data, net rates of tubular bicarbonate reabsorption and of H ion secretion were obtained since it was shown that the rate of phosphate acidification provides a realistic estimate of H ion secretion. 2. Experiments were performed in control rats, in animals undergoing metabolic acidosis or alkalosis and in control and acidotic rats receiving the carbonic anydrase inhibitor Diamox. 3. In all experiments, the rates of tubular bicarbonate reabsorption and of phosphate acidification (H ion secretion) were proportional to luminal buffer levels. The changes of luminal acid concentrations followed first-order kinetics. 4. Steady-state transepithelial pH differences were reduced in metabolic alkalosis and after diamox but augmented during metabolic acidosis. 5. Acidification half-times were prolonged in metabolic acidosis and after Diamox but remained similar to control levels in metabolic alkalosis. 6. From the observation that both bicarbonate reabsorption and phosphate acidification are similarly affected by these experimental manoeuvres, it is concluded that H ion secretion plays a key role in both transport processes.     

Studies of the urinary acidification defect induced by lithium

Experiments were carried out in rats and isolated turtle bladders to study the defect in H+ transport induced by LiCl. After 3-4 days of intraperitoneal LiCl, rats developed urinary findings of "distal" renal tubular acidosis. Proximal tubular fluid pH measured in situ by glass microelectrodes was higher in lithium-treated rats than in acidotic controls. Proximal fluid total CO2 [tCO2] was also higher, and the fraction of tCO2 leaving the proximal tubule was 14 vs. 7% (P less than 0.001). Impaired acidification was also apparent beyond distal convoluted tubules, as judged by normal distal tCO2 reabsorption but increased HCO3(-) in the urine. During NaHCO3 loading, the proximal defect was ameliorated but not the distal. Turtle bladder studies showed that mucosal lithium inhibits H+ secretion secondary to reducing transepithelial electrical potential, presumably by hyperpolarization of the luminal membrane. A similar mechanism may be responsible for lithium's effect on the distal nephron. Inhibition of proximal tubular HCO3(-) reabsorption is probably not attributable to electrical potential changes but might be due to interference of luminal membrane Na+ entry by Li+ and reduced (Na+ + Li+)-H+ exchange.     

Roles of organic anion transporters (OATs) in renal proximal tubules and their localization

Organic anions (OAs) are secreted in renal proximal tubules in two steps. In the first step, OAs are transported from the blood through basolateral membranes into proximal tubular cells. The prototypical substrate for renal organic anion transport systems, para-aminohippurate (PAH), is transported across basolateral membranes of proximal tubular cells via OAT1 (SLC22A6) and OAT3 (SLC22A8) against an electrochemical gradient in exchange for intracellular dicarboxylates. In the second step, OAs exit into urine through apical membranes of proximal tubules. This step is thought to be performed by multidrug efflux transporters and a voltage-driven organic anion transporter. However, the molecular nature and precise functional properties of these efflux systems are largely unknown. Recently, we characterized an orphan transporter known as human type I sodium-phosphate transporter 4, hNPT4 (SLC17A3), using the Xenopus oocyte expression system. hNPT4 acts as a voltage-driven efflux transporter (“human OATv1”) for several OAs such as PAH, estrone sulfate, diuretic drugs, and urate. Here, we describe a model for an OA secretory pathway in renal tubular cells in which OAs exit cells and enter the tubular lumen via hOATv1 (hNPT4). Additionally, hOATv1 functions as a common renal secretory pathway for both urate and drugs, indicating that hOATv1 may be a leak pathway for excess urate that is reabsorbed via apical URAT1 to control the intracellular urate levels. Therefore, we propose a molecular mechanism for the induction of hyperuricemia by diuretics: the diuretics enter proximal tubular cells via basolateral OAT1 and/or OAT3 and may then interfere with the NPT4-mediated apical urate efflux in the renal proximal tubule.     

Renal tubular acidosis: an immunopathological study on four patients

Renal biopsies and sera of four patients with distal renal tubular acidosis were examined. The findings consisted of immunoglobulin containing mononuclear cellular infiltrates around the distal tubules, bound immunoglobulin and complement in tubules. The sera of the patients contained antibodies reacting with various tissue antigens, among them renal tubular antigens.

The results suggest that autoimmunity was involved in the pathogenesis of the renal tubular acidosis in these patients.

     

Regulated acid–base transport in the collecting duct

The renal collecting system serves the fine-tuning of renal acid–base secretion. Acid-secretory type-A intercalated cells secrete protons via a luminally expressed V-type H⁺-ATPase and generate new bicarbonate released by basolateral chloride/bicarbonate exchangers including the AE1 anion exchanger. Efficient proton secretion depends both on the presence of titratable acids (mainly phosphate) and the concomitant secretion of ammonia being titrated to ammonium. Collecting duct ammonium excretion requires the Rhesus protein RhCG as indicated by recent KO studies. Urinary acid secretion by type-A intercalated cells is strongly regulated by various factors among them acid–base status, angiotensin II and aldosterone, and the Calcium-sensing receptor. Moreover, urinary acidification by H⁺-ATPases is modulated indirectly by the activity of the epithelial sodium channel ENaC. Bicarbonate secretion is achieved by non-type-A intercalated cells characterized by the luminal expression of the chloride/bicarbonate exchanger pendrin. Pendrin activity is driven by H⁺-ATPases and may serve both bicarbonate excretion and chloride reabsorption. The activity and expression of pendrin is regulated by different factors including acid–base status, chloride delivery, and angiotensin II and may play a role in NaCl retention and blood pressure regulation. Finally, the relative abundance of type-A and non-type-A intercalated cells may be tightly regulated. Dysregulation of intercalated cell function or abundance causes various syndromes of distal renal tubular acidosis underlining the importance of these processes for acid–base homeostasis.     

Aldosterone stimulates surface expression of NHE3 in renal proximal brush borders

The mineralocorticoid aldosterone is one of the major regulators of extracellular volume and blood pressure. It acts by enhancing Na(+) reabsorption across tight epithelia such as renal collecting ducts and colon. In addition, it has been shown that aldosterone stimulates NaCl and volume reabsorption in renal proximal tubules by an unknown mechanism. To test the hypothesis that the application of aldosterone results in greater activity of the apical Na(+)/H(+) exchanger-3 (NHE3), we investigated the effect of aldosterone on amiloride-sensitive, proximal tubular volume reabsorption and proximal tubular NHE3 abundance in adrenalectomized rats. Aldosterone at physiological concentrations (dosage 36 microg/100 g b.w. per day) increased NHE3-dependent proximal tubular volume reabsorption and the abundance of NHE3 in brush borders without changing the total amount of NHE3 in cortical homogenates. These results indicate that renal proximal tubular NHE3 is a target for aldosterone-mediated regulation resulting in increased Na(+) reabsorption and thus extracellular volume and blood pressure. Further studies are required to determine the precise mechanism of action, especially whether the action of aldosterone on proximal tubular function is direct or indirect.     

Primärer Hypoaldosteronismus,Pseudo-Hypoaldosteronismus und distal-tubuläre Acidose

Summary Aldosterone deficiency is caused by (1) various defects of aldosterone biosynthesis in the adrenal gland or (2) hyporeninism. The most important symptoms are hyponatremia and hyperkalemia. These electrolyte disturbances are also found in pseudohypoaldosteronism. Pseudohypoaldosteronism type I is characterized by insensitivity of the distal nephron for aldosterone. Hyperabsorption of chloride in the distal nephron leads to pseudohypoaldosteronism type II, which is linked with hypertension, whereas blood pressure in the other mentioned disorders is decreased. Renal tubular acidosis, mainly type 4, with impaired production of ammonia due to hyperkalemia, is frequently observed in hypoaldosteronism and both types of pseudohypoaldosteronism as well. The therapeutic regimen is different: (1) low doses of fludrocortisone in hypoaldosteronism, (2) potassium restriction, sodium bicarbonate and loop diuretics in type I of pseudohypoaldosteronism, and (3) sodium restriction and chloruretic diuretics (thiazide) in type II of pseudohypoaldosteronism. In some cases hyperkalemia requires the use of potassium-binding resins.

Herrn Prof. Dr. Dr. H.E. Bock in Verehrung zum 80. Geburtstag gewidmet     

Ultrastructure of the Kidney in Acute Interstitial Nephritis

Fifteen percutaneous renal biopsies from patients with acute renal failure due to acute interstitial nephritis (AIN), in almost all cases due to drugs, were studied by electron microscopy. Differential counting of interstitial cells showed an average of 69% lymphocytes (small and large) and 11 % macrophages. Plasma cells and eosinophils were comparatively rare. The infiltrate resembled that of acute rejection, suggesting a cellular hypersensitivity reaction. Proximal and distal tubules were severely affected focally. Migration of lymphocytes through the tubular basement membrane of otherwise well-preserved tubules was considered to be the first phase. Other tubules showed extreme thinning of the tubular basement membrane, with still intact cellular walls. Rupture of the tubular basement membrane and necrotic disintegration of tubular epithelial cells are probably late phenomena. The non-necrotic tubules displayed severe reduction of proximal brush border and proximal as well as distal tubular basolateral infoldings. Focal tubular disintegration leading to tubular block and/or backleak as well as decrease of proximal tubular sodium resorption leading to a decreased glomerular filtration (a mechanism probably also acting in ischemic acute renal failure) may all be factors responsible for the acute renal failure in AIN.     

High prevalence of Southeast Asian ovalocytosis in Malays with distal renal tubular acidosis

Southeast Asian ovalocytosis (SAO) is a red blood cell abnormality common in malaria-endemic regions and caused by a 27 nt deletion of the band 3 protein gene. Since band 3 protein, also known as anion exchanger 1, is expressed in renal distal tubules, the incidence of SAO was examined in distal renal tubular acidosis (dRTA) in Malays in Kelantan, Malaysia. Twenty-two patients with dRTA and 50 healthy volunteers were examined for complication of SAO by both morphological and genetic analyses. SAO was identified in 18 of the 22 dRTA patients (81.8%), but only two of the 50 controls (4%). The incidence of SAO was significantly high in those with dRTA (p<0.001), indicating a dysfunctional role for band 3 protein/anion exchanger 1 in the development of dRTA.     

Proximal tubuläre Acidose bei nierentransplantierten Patienten

Zusammenfassung Plasmabicarbonatspiegel und pCO₂ sind bei nierentransplantierten Patienten häufig erniedrigt. Der gleichzeitig normale pH-Wert im Plasma weist auf eine respiratorische Kompensation hin. Als Ursache ist in erster Linie ein renaler Bicarbonatverlust anzunehmen, denn es werden trotz niedriger Bicarbonatplasmaspiegel bis zu 2% des glomerulären Loads ausgeschieden. Die gleichzeitig beobachtete Phosphatresorptionsstörung sowie normal saure Urin-pH-Werte lassen die Resorptionsstörung für Bicarbonat in den proximalen Tubulus lokalisieren. Als Ursache für diesen Defekt wird ein eingeschränkter Natrium- und Wassertransport im proximalen Tubulus angenommen.

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Summary Metabolic acidosis is a common finding in renal allograft recipients, documented by a lowered plasma bicarbonate concentration and a decreased pCO₂. This finding and a normal or subnormal pH value indicates a respiratory compensation. Since fractional renal bicarbonate reabsorption is diminished to about 98% in spite of lowered plasma bicarbonate levels, renal origin of this acidosis is suggested. Simultaneously depressed phosphate reabsorption in these patients as well as the capacity to excrete an acid urine (pH below 5.4) indicates proximal tubular acidosis, the origin of which might be depression of proximal sodium reabsorption.

     

Electrolyte content and ultrastructure of the kidney in hamsters with heart failure

Electrolyte (Na, K, Ca, Mg) concentrations were measured in the urine, serum, and renal tissues of cardiomyopathic (BIO 14.6) hamsters, during various stages of spontaneous congestive heart failure, and correlated with ultrastructural changes in renal tubules. The renal concentration of sodium was significantly elevated during the very early (subclinical) stages of congestive heart failure. Further increases paralleled the progress of the disease. The derived data indicate an intracellular location for the augmented load of sodium in the kidney. The magnesium concentrations in the kidney remained unchanged and the variations in renal potassium proved to be significant only during the advanced stages of cardiocirculatory insufficiency. Young cardiomyopathic hamsters had low renal calcium concentrations in spite of elevated serum calcium levels. However, during the terminal phase of congestive heart failure, the calcium values in the kidneys of cardiomyopathic hamsters were higher despite lower serum calcium values. The proximal and distal convoluted tubules as well as the cortical collecting tubules during severe congestive heart failure were characterized by marked widening of the extracellular spaces between the basilar interdigitating processes. The distal convoluted tubules exhibited edema and mitochondrial alterations and the intercellular spaces of the collecting tubules were dilated. These tubular changes indicate an increased flow of water and ions.     

Homozygous and compound heterozygous mutations in the ATP6V1B1 gene in patients with renal tubular acidosis and sensorineural hearing loss

Mohebbi N, Vargas‐Poussou R, Hegemann SCA, Schuknecht B, Kistler AD, Wüthrich RP, Wagner CA. Homozygous and compound heterozygous mutations in the ATP6V1B1 gene in patients with renal tubular acidosis and sensorineural hearing loss. Distal renal tubular acidosis (dRTA) is characterized by the inability to excrete acid in the renal collecting ducts resulting in inappropriately alkaline urine and hyperchloremic (normal anion gap) metabolic acidosis in the context of a normal (or near‐normal) glomerular filtration rate. Inborn dRTA can be due to autosomal dominant or recessive gene defects. Clinical symptoms vary from mild acidosis, incidental detection of kidney stones or renal tract calcification to severe findings such as failure to thrive, severe metabolic acidosis, and nephrocalcinosis. The majority of patients with recessive dRTA present with sensorineural hearing loss (SNHL). Few cases with abnormal widening of the vestibular aqueduct have been described with dRTA. Mutations in three different genes have been identified, namely SLC4A1, ATP6V1B1, and ATP6V0A4. Patients with mutations in the ATP6V1B1 proton pump subunit develop dRTA and in most of the cases sensorineural hearing loss early in childhood. We present two patients from two different and non‐consanguineous families with dRTA and SNHL. Direct sequencing of the ATP6V1B1 gene revealed that one patient harbors two homozygous mutations and the other one is a compound heterozygous. To our knowledge, this is the first case in the literature describing homozygosity in the same dRTA gene on both alleles.