An acute infusion of lactic acid lowers the concentration of potassium in arterial plasma by inducing a shift of potassium into cells of the liver in fed rats.

BACKGROUND: Potassium (K(+)) input occurs after meals or during ischemic exercise and is accompanied by a high concentration of L-lactate in plasma (P(L-lactate)). METHODS: We examined whether infusing 100 µmol L-lactic acid/min for 15 min would lead to a fall in the arterial plasma K(+) concentration (P(K)). We also aimed to evaluate the mechanisms involved in normal rats compared with rats with acute hyperkalemia caused by a shift of K(+) from cells or a positive K(+) balance. RESULTS: There was a significant fall in P(K) in normal rats (0.25 mM) and a larger fall in P(K) in both models of acute hyperkalemia (0.6 mM) when the P(L-lactate) rose. The arterial P(K) increased by 0.8 mM (p < 0.05) 7 min after stopping this infusion despite a 2-fold rise in the concentration of insulin in arterial plasma (P(Insulin)). There was a significant uptake of K(+) by the liver, but not by skeletal muscle. In rats pretreated with somatostatin, P(Insulin) was low and infusing L-lactic acid failed to lower the P(K). CONCLUSIONS: A rise in the P(L-lactate) in portal venous blood led to a fall in the P(K) and insulin was permissive. Absorption of glucose by the Na(+)-linked glucose transporter permits enterocytes to produce enough ADP to augment aerobic glycolysis, raising the P(L-lactate) in the portal vein to prevent postprandial hyperkalemia.

Occult risk factor for the development of cerebral edema in children with diabetic ketoacidosis: possible role for stomach emptying.

The incidence of cerebral edema during therapy of diabetic ketoacidosis (DKA) in children remains unacceptably high-this suggests that current treatment may not be ideal and that important risk factors for the development of cerebral edema have not been recognized. We suggest that there are two major sources for an occult generation of osmole-free water in these patients: first, fluid with a low concentration of electrolytes that was retained in the lumen of the stomach when the patient arrived in hospital; second, infusion of glucose in water at a time when this solution can be converted into water with little glucose. In a retrospective chart review of 30 patients who were admitted with a diagnosis of DKA and a blood sugar > 900 mg/dL (50 mmol/L), there were clues to suggest that some of the retained fluid in the stomach was absorbed. To minimize the likelihood of creating a dangerous degree of cerebral edema in patients with DKA, it is important to define the likely composition of fluid retained in the stomach on admission, to look for signs of absorption of some of this fluid during therapy, and to be especially vigilant once fat-derived brain fuels have disappeared, because this is the time when glucose oxidation in the brain should increase markedly, generating osmole-free water.

The inhibition by methylmalonic acid of malate transport by the dicarboxylate carrier in rat liver mitochondria. A possible explantation for hypoglycemia in methylmalonic aciduria.

We report the effects of methylmalonic acid (MMA) on the mitochondrial transport systems for malate, alpha-oxoglutarate, and isocitrate. MMA is shown to be a substrate for all three carrier systems, and an inhibitor of the malate-phosphate exchange carrier. The effects of MMA on the metabolism of malate, oxoglutarate, and isocitrate by rat liver mitochondria are demonstrated to be mediated by the influence of MMA on the transport step. A hypothesis regarding the metabolic impairments responsible for hypoglycemia and ketonemia in methylmalonic aciduria is formulated in relation to these findings.

The effect of hyperventilation on distal nephron hydrogen ion secretion.

This study was designed to determine the effect of acute hyperventilation on distal nephron hydrogen ion secretion. The blood PCO2 declined and stabilized rapidly when bicarbonate loaded rats were hyperventilated. In contrast, the urine PCO2 declined slowly, resulting in an early increase in the urine minus blood (U-B) PCO2 which could not be obliterated by carbonic anhydrase infusion. Within approximately 50 min, the U-B PCO2 in the hyperventilated and carbonic anhydrase infused rats approached zero. Consequently, equilibrium between collecting duct urine and arterial blood PCO2 was then presumed to exist. This provided the basis for the subsequent studies on a series of rats. The U-B PCO2 decreased from a control of 22+/-1 mm Hg (mean+/-SEM) to 11+/-2 mm Hg (mean+/-SEM) with hypocapnia, and rose again to its control value when the blood PCO2 returned to prehyperventilation values. This decline in U-B PCO2 with acute hyperventilation could not be attributed to changes in urine flow, phosphate, or bicarbonate excretion, suggesting, therefore, a decrease in distal nephron (probably collecting duct) hydrogen ion secretion with acute hyperventilation. Possible pitfalls in the interpretation of the UB PCO2 are illustrated.

Studies on the pathogenesis of type I (distal) renal tubular acidosis as revealed by the urinary PCO2 tensions.

This study was designed to investigate the pathogenesis of type I (distal) renal tubular acidosis. Urinary and blood Pco(2) tensions were determined when the pH of the urine was equal to or exceeded the corresponding blood pH. This provided an indication of net hydrogen ion secretion in the distal nephron. In 16 normal subjects, the Pco(2) of the urine exceeded blood values (U-B Pco(2)) by 32.7+/-3.1 mm Hg. In contrast, the urinary Pco(2) tensions in 10 patients with type I (distal) renal tubular acidosis were not significantly greater than blood values (U-B Pco(2) = 2.0+/-2.2 mm Hg). These results indicate that type I (distal) renal tubular acidosis is caused by failure of the cells of the distal nephron to secrete hydrogen ions rather than to gradient-limited hydrogen ion addition to the urine. This is suggested by the fact that urinary Pco(2) levels should be higher than blood Pco(2) levels when hydrogen ions are secreted into urine containing bicarbonate in the distal nephron and they were not in this study despite the presence of a favorable hydrogen ion gradient (tubular fluid pH exceeded blood pH).

Stimulation of ammonia production and excretion in the rabbit by inorganic phosphate. Study of control mechanisms.

The purpose of this study was to clarify the mechanism (s) responsible for regulation of ammonia production and excretion in the rabbit. The normally low ammonia excretion rate during acute metabolic acidosis was stimulated acutely and increased approximately ninefold after infusion of sodium phosphate, but remained low if sodium sulphate or Tris was substituted for phosphate. Ammonia production was increased significantly by phosphate in rabbit renal cortex slices and in isolated renal cortex mitochondria. In isolated mitochondria, mersalyl, an inhibitor of both the phosphate/hydroxyl and phosphate/dicarboxylate mitochondrial carriers, inhibited the phosphate-induced stimulation, indicating that phosphate must enter the mitochondrion for stimulation. A malate/phosphate exchange seemed to be involved since N-ethylmaleimide, an inhibitor of the phosphate/hydroxyl exchange, did not inhibit phosphate-stimulated ammonia production, whereas there was inhibition by 2-n-butylmalonate, a competitive inhibitor of the dicarboxylate carrier. Phosphate itself was not essential since malonate stimulated ammoniagenesis in the absence of added phosphate. Similarly, citrate stimulated ammoniagenesis in isolated mitochondria in the absence of inorganic phosphate provided that it induced L-malate exit on the citrate transporter associated with inhibition of citrate oxidation by fluoroacetate. Similar results were also seen in mitochondria from rat renal cortex. A fall in mitochondrial alpha-ketoglutarate level resulted in an increase in ammonia production. This could be achieved directly with malonate or indirectly via L-malate exit. Simultaneous measurements of glutamate showed that the rate of ammonia production was reciprocally related to the glutamate content. We conclude that phosphate-induced stimulation of ammoniagenesis in the rabbit kidney is mediated by removal of glutamate, the feedback inhibitor of phosphate-dependent glutaminase. Glutamate removal is linked to phosphate-induced dicarboxylate exit across the mitochondrial membrane.

A hyperglycaemic hyperosmolar state in a young child: diagnostic insights from a quantitative analysis.

This teaching exercise demonstrates how the application of principles of physiology can identify the cause of a severe degree of hyperglycaemia (plasma glucose concentration 80 mmol/l) in a very young patient with newly diagnosed diabetes mellitus, determine whether the patient has diabetic ketoacidosis, and highlight the potential risks for this patient on admission and during initial therapy. A consultation with Professor McCance was sought to determine whether this patient had an unusual degree of 'insulin resistance'. There were also uncertainties regarding the acid-base diagnosis. The patient did not appear to have an important degree of metabolic acidosis as judged from his pH of 7.39 and plasma bicarbonate concentration of 20 mmol/l in arterial blood; hence the diagnostic impression was that he had a hyperglycaemic hyperosmolar state. However, his plasma anion gap was significantly elevated, and remained so for 60 h, despite the administration of insulin. Issues in management concerning the basis for this severe degree of hyperglycaemia and how to minimize the risk of developing cerebral oedema are addressed. The missing links in this interesting story emerge during a discussion between the medical team and their mentor, Professor McCance.

Uncovering the basis of a severe degree of acidemia in a patient with diabetic ketoacidosis.

In this teaching exercise, the goal is to demonstrate how an application of principles of physiology can reveal the basis for a severe degree of acidaemia (pH 6.81, bicarbonate <3 mmol/l (P(HCO(3))), PCO(2) 8 mmHg), why it was tolerated for a long period of time, and the issues for its therapy in an 8-year-old female with diabetic ketoacidosis. The relatively low value for the anion gap in plasma (19 mEq/l) suggested that its cause was both a direct and an indirect loss of NaHCO(3). Professor McCance suggested that ileus due to hypokalaemia might cause this direct loss of NaHCO(3), and that an excessive excretion of ketoacid anions without NH(4)(+) in the urine accounted for the indirect loss of NaHCO(3). In addition, he suspected that another factor also contributing to the severity of the acidaemia was a low input of alkali. He was also able to explain why there was a 16-h delay before there was a rise in the P(HCO(3)) once therapy began. The missing links in this interesting story, including a possible basis for the hypokalaemia, emerge during the discussion between the medical team and Professor McCance.

The patient with a severe degree of metabolic acidosis: a deductive analysis.

This teaching exercise demonstrates how principles of physiology might help in identifying the cause of a particularly severe case of metabolic acidosis and making appropriate decisions about therapy. The patient's plasma pH was 7.00 and their plasma bicarbonate concentration was 2 mmol/l. Because the time course of the patient's illness was believed to be <24 h, this suggested that a large quantity of acid had been added to the body in this short time period, but the medical team managing the case could not identify any acid that could have been produced rapidly by endogenous processes, or was ingested by the patient. Moreover, there was a question about how such a very low arterial PCO(2) (8 mmHg) could be sustained. Even once the diagnosis was made, there were issues to resolve concerning therapy. These included questions about how much sodium bicarbonate to administer, and what dangers might arise during this therapy. The missing links in this interesting story emerge during a discussion between the medical team and their imaginary mentor, Professor McCance.

Unusual causes of hypokalaemia and paralysis.

We demonstrate how the application of physiological principles may help to identify unusual causes of a very low plasma potassium (K+) concentration (P(K)) and paralysis. In the two patients described, the short time course of the illness suggested that there was an acute shift of K+ into cells. The combination of a low rate of excretion of K+, the absence of a metabolic acid-base disorder, and the fact that the clinical findings occurred very soon after a large intake of carbohydrate supported this impression. Surprisingly, the P(K) remained low for many hours after these stimuli to shift K+ into cells had abated. The missing link in this story was eventually provided by the attending medical team with the help of their mentor, Professor McCance.

An improved approach to the patient with metabolic acidosis: a need for four amendments.

Clinicians should identify life-threatening issues in patients with metabolic acidosis. These threats may be present before therapy begins and/or anticipated after therapy commences. By adding four amendments, short-comings in the commonly used clinical approaches for the diagnosis of metabolic acidosis can be overcome. First, a definition of metabolic acidosis should consider not only the concentration of bicarbonate but also the content of bicarbonate in the extra cellular fluid compartment. The latter requires a quantitative estimate of the ECF volume, which can be obtained using the hematocrit and/or the total protein concentration in plasma. Second, to determine if the basis for metabolic acidosis was the addition of acids or the loss of NaHCO 3 , one must hunt for new anions, not only in plasma, but also in the urine. Third, it is important to measure the venous as well as the arterial PCO2 to assess the capacity to buffer H+ while minimizing H + binding to intracellular proteins. Fourth, to assess the role of the kidney in a patient with metabolic acidosis, the urine osmolal gap and the concentration of creatinine in the urine should be measured to provide an estimate of the rate of excretion of ammonium.

Regulation of energy metabolism in Morris hepatoma 7777 and 7800.

The pathway of fat oxidation in two experimental hepatomas was studied in order to demonstrate that a specific deficit in the energy metabolism of a tumor might contribute to the cachexia of the host. Forty-eight male Buffalo rats were divided into four groups of 12 each. One group was implanted s.c. with Morris hepatoma 7777 and one group was implanted with Morris hepatoma 7800, whereas the other two groups served as controls. All groups were fed standard rat chow diet ad libitum until the tumors reached 2 cm in diameter. The animals were then fasted for 24 hr prior to sacrifice and excision of tumor and liver for assays. During the period of tumor growth, the animals bearing the 7777 hepatoma lost weight, but the weight of the 7800 hepatoma-bearing rats did not differ significantly from that of the control animals. The livers of both groups of animals showed evidence of fatty acid oxidation in vivo and in vitro, and, as expected, during fasting, pyruvate dehydrogenase was inactivated and the rate of fatty acid synthesis was low. A qualitatively similar picture was seen with the better-differentiated 7800 hepatoma. In contrast, the 7777 hepatoma exhibited low levels of fatty acyl coenzyme CoA, no appreciable activity of carnitine palmitoyl transferase and fortified homogenates of the tumor were unable to oxidize palmitate. In keeping with these observations, pyruvate dehydrogenase remained in the active form, and fatty acid synthesis continued unabated in the fasted state in these tumors. Ketone bodies could not be oxidized by fortified homogenates of the liver or by either tumor, probably due to the lack of 3-ketoacid thiotransferase, which was undetectable in these tissues. We hypothesize that flow-through pyruvate dehydrogenase during fasting in Morris hepatoma 7777, occurring as a result of the defect in fat oxidation, contributes to the weight loss of these animals.

Selected aspects of the pathophysiology of metabolic acidosis in diabetes mellitus.

Metabolic acidosis with a normal anion gap results from either bicarbonate loss or a urine acidification defect. The bicarbonate loss may be via the gastrointestinal tract or the urine, or may be indirect due to excretion of the sodium and potassium as opposed to the ammonium salts of ketone body anions. Defects in urine acidification in the diabetic have several etiologies: first, hydrogen ion secretion may be decreased because of an intrinsic defect in the hydrogen ion pump (i.e., diseases of the renal medulla); second, there may be a failure to augment hydrogen ion secretion by a favorable electrical gradient (e.g., reduced mineralocorticoids); and third, there may be a failure to generate a favorable chemical gradient to augment hydrogen ion secretion (e.g., reduced urine ammonia). Reduced levels of aldosterone associated with hyporeninemia has been termed type IV RTA, and these patients have specific therapeutic needs.

Insulin therapy in phenformin-associated lactic acidosis; a case report, biochemical considerations and review of the literature.

A patient with phenformin-associated lactic acidosis was treated with insulin and showed marked improvement coincident with the expected onset of action of the insulin administered. Relative insulin deficiency was demonstrated although several phenomena characteristic of phenformin-associated lactic acidosis obscured its reflection in the usual indices. From data presented and a review of the literature the following pathogenesis is proposed for the observed metabolic derangement. A background of relative insulin deficiency would permit enhanced pyruvate (and hence lactate) formation from protein sources. Insulin deficiency would also lead to inhibition of pyruvate dehydrogenase which slows pyruvate removal. Phenformin accumulation (cf impaired renal function) further reduces pyruvate removal by decreasing its conversion to glucose, but in addition alters the redox state. For the lactic acidosis which results, insulin administration may thus constitute specific therapy. Diabetes 24:28-35, January, 1975.

Diagnostic approach to a patient with hyponatraemia: traditional versus physiology-based options.

The usual diagnostic approach to a patient with hyponatraemia is based on the clinical assessment of the extracellular fluid (ECF) volume, and laboratory parameters such as plasma osmolality, urine osmolality and/or urine sodium concentration. Several clinical diagnostic algorithms (CDA) applying these diagnostic parameters are available to the clinician. However, the accuracy and utility of these CDAs has never been tested. Therefore, we performed a survey in which 46 physicians were asked to apply all existing, unique CDAs for hyponatraemia to four selected cases of hyponatraemia. The results of this survey showed that, on average, the CDAs enabled only 10% of physicians to reach a correct diagnosis. Several weaknesses were identified in the CDAs, including a failure to consider acute hyponatraemia, the belief that a modest degree of ECF contraction can be detected by physical examination supported by routine laboratory data, and a tendency to diagnose the syndrome of inappropriate secretion of antidiuretic hormone prior to excluding other causes of hyponatraemia. We conclude that the typical architecture of CDAs for hyponatraemia represents a hierarchical order of isolated clinical and/or laboratory parameters, and that they do not take into account the pathophysiological context, the mechanism by which hyponatraemia developed and the clinical dangers of hyponatraemia. These restrictions are important for physicians confronted with hyponatraemic patients and may require them to choose different approaches. We therefore conclude this review with the presentation of a more physiology-based approach to hyponatraemia, which seeks to overcome some of the limitations of the existing CDAs.

Acute and fatal hyponatraemia after resection of a craniopharyngioma: a preventable tragedy.

Central diabetes insipidus developed for the first time in a 14-year-old female during the resection of a craniopharyngioma. The water diuresis persisted until a vasopressin analogue (dDAVP) was given. Professor McCance was asked to explain why hypernatraemia developed, to anticipate dangers that might develop in the salt and water area with therapy, and to provide insights into why this patient died, due to the subsequent development of hyponatraemia that caused a lethal rise in intracranial pressure. The team specifically wanted Professor McCance's opinions as to why a PNa of 124 mmol/l was uniquely dangerous for this patient, and this was a particularly challenging conundrum. Nevertheless, with the aid of a mini-experiment, a careful chart review, and creative thinking, he was able to offer a novel solution, and to suggest ways to prevent its occurrence in other patients.

Recurrent uric acid stones.

A 46-year-old female had a history of recurrent uric acid stone formation, but the reason why uric acid precipitated in her urine was not obvious, because the rate of urate excretion was not high, urine volume was not low, and the pH in her 24-h urine was not low enough. In his discussion of the case, Professor McCance provided new insights into the pathophysiology of uric acid stone formation. He illustrated that measuring the pH in a 24-h urine might obscure the fact that the urine pH was low enough to cause uric acid to precipitate during most of the day. Because he found a low rate of excretion of NH(4)(+) relative to that of sulphate anions, as well as a high rate of citrate excretion, he speculated that the low urine pH would be due to a more alkaline pH in proximal convoluted tubule cells. He went on to suspect that there was a problem in our understanding of the function of renal medullary NH(3) shunt pathway, and he suggested that its major function might be to ensure a urine pH close to 6.0 throughout the day, to minimize the likelihood of forming uric acid kidney stones.

An approach to the patient with severe hypokalaemia: the potassium quiz.

The objective of this teaching session with Professor McCance is to develop an approach to the management of patients with a very low plasma potassium (K(+)) concentration (P(K)). The session begins with a quiz based on six recent medical consultations for a P(K) < 2 mmol/l. Professor McCance outlined how he would proceed with his diagnosis and therapy, using the synopsis that described each patient. This approach was then applied to a new patient, a 69-year-old woman who had a large volume of dependent oedema and developed a severe degree of weakness and hypokalaemia during more aggressive diuretic therapy that included a K(+)-sparing diuretic. The initial challenge for Professor McCance was to deduce why the K(+)-sparing diuretic was not effective in this patient. He also needed to explain why the P(K) was so low on admission.

Quantitative analysis of glucose loss during acute therapy for hyperglycemic hyperosmolar syndrome.

Four patients with severe hyperglycemia and hyperosmolality were studied to quantitate the major mechanisms responsible for the fall in blood glucose concentration. Insulin was not administered to any of these patients during the first 15 h of therapy. In each case, there was a fall in glucose concentration due to dilution; this was quantitated by chloride space analysis and accounted for 24-34% of the fall in concentration. The size of the glucose pool decreased for two reasons. Glucosuria accounted for the majority of the reduction in the size of the glucose pool in the patients with the smallest decrease in extracellular fluid (ECF) volume [and hence the best preserved glomerular filtration rate (GFR)]. In contrast, glucosuria was a less important factor in causing glucose loss in the patients with very low GFR values. The size of the glucose pool also decreased due to glucose metabolism that did not require exogenous insulin. Thus the fall in glucose concentration in the initial therapy in patients with the hyperglycemic hyperosmolar syndrome is multifactorial and is not absolutely dependent on exogenous insulin. Furthermore, the patients grouped in this diagnostic category represent a heterogeneous population with the common features of severe hyperglycemia, hyperosmolality, and a negative or weakly reactive test for serum ketones.

The urine anion gap: the critical clue to resolve a diagnostic dilemma in a patient with ketoacidosis.

Usually, ketoacidosis presents few if any diagnostic or therapeutic problems; in this article, we report a case where ketoacidosis was clinically occult and biochemically obscure. The patient presented with acute pancreatitis associated with a modest antecedent alcohol intake. Metabolic acidosis with a normal anion gap (10 meq/L) was observed together with moderate hyperglycemia and a 2 + (but not 4 +) test for serum ketones. None of the usual causes of metabolic acidosis with a normal anion gap was identified nor was there an obvious explanation for a reduction in unmeasured anion gap (e.g., hypoalbuminemia, dysproteinemia, or the presence of abnormal halides). Despite the initial normal anion gap, ketoacidosis was suspected clinically and this was confirmed by the elevated serum B-hydroxybutyrate of 8 mmol/L. We deduced that the serum unmeasured anions, which should have been increased by at least 8 meq/L, were being underestimated because of the effect of hypertriglyceridemia on the serum chloride determination. When the serum chloride was reestimated by a method not influenced by hyperlipidemia, the value was 102 mmol/L not 112 mmol/L and, when reevaluated, the anion gap was indeed appropriately elevated. In addition, the urine anion gap (Na + K - Cl) was 103 meq/L in the absence of renal disease. This indicated that the expected large quantity of urinary ammonium must have been masked by an even greater quantity of unmeasured anion; in this case proven by direct measurement to be B-hydroxybutyrate. Finally, metabolism of the alcohol ingested, which yields hepatic NADH, could explain, in part, the modest hyperglycemia and the absence of a 4 + test for serum ketones.(ABSTRACT TRUNCATED AT 250 WORDS)