Lactic acidosis and ketoacidosis: biochemical and clinical implications.

A case of lactic acidosis presented the opportunity for review of the association between lactic acidosis and ketoacidosis. The diagnosis of lactic acidosis or the combination of lactic acidosis and ketoacidosis is established clinically by the detection of a metabolic acidosis of the "unmeasured anion gap" type in the absence of significant renal failure, poison intake or a strongly positive clinical test for ketones. Before treatment can be planned the biochemical basis of lactic acidosis and ketoacidosis must be understood -- especially the fact that lactic acidosis is not a single disease entity but has many possible causes. Among important considerations is the relation between the blood concentrations of bicarbonate and organic acid anions. After recovery from metabolic acidosis of the unmeasured anion gap type, metabolic alkalosis is common. Decreased bicarbonate excretion plays an important role in the pathogenesis of the latter and may be the result of potassium or chloride loss, or both. The deficits, if present, should be corrected with appropriate therapy.     

Plasma prostaglandin levels and circulating fuel levels in rats with diabetic ketoacidosis: effects of cyclooxygenase inhibitors and of alpha and beta adrenergic blockade

We studied the effects of two structurally unrelated inhibitors of the fatty acid cyclooxygenase and of alpha and beta adrenergic blockade on the elevated plasma levels of 13,14-dihydro-15-keto-prostaglandin (PG)E2, 6-keto-PGF1 alpha and thromboxane (TX)B2, the stable derivatives of PGE2, PGI2 (prostacyclin) and TXA2, respectively, in rats with streptozotocin-induced diabetic ketoacidosis (DKA). Meclofenamic acid and indomethacin each produced a significant decrease in the elevated plasma levels of 13,14-dihydro-15-keto-PGE2, 6-keto-PGF1 alpha and TXB2. Phentolamine significantly reduced the plasma level of TXB2 but had no effect on the elevated circulating levels of glucose, free fatty acids, total ketones, 13,14-dihydro-15-keto-PGE2 or 6-keto-PGF1 alpha. Propranolol significantly reduced the elevated circulating levels of glucose, free fatty acids and total ketones but had no effect on the levels of the three prostaglandin derivatives. The ability of meclofenamic acid and indomethacin to reduce the plasma levels of 13,14-dihydro-15-keto-PGE2, 6-keto-PGF1 alpha and TXB2 confirms that the plasma levels of these three derivatives are elevated in rats with DKA. Since abnormalities in the production of PGI2 and perhaps other cyclooxygenase derivatives may contribute to the pathogenesis of certain important hemodynamic and gastrointestinal features of DKA, cyclooxygenase inhibitors may play a role in the management of selected patients with this disorder. Alpha adrenergic activity is essential for the maintenance of the elevated plasma TXB2 level in rats with DKA. The fall in the plasma TXB2 level during alpha adrenergic blockade appears to reflect inhibition of platelet aggregation and platelet TXA2 production, but other sources of the elevated plasma TXB2 level in DKA are not excluded. Beta adrenergic activity contributes to the maintenance of elevated circulating levels of glucose, free fatty acids and total ketones in experimental DKA but not to the elevated plasma levels of the prostaglandin derivatives.     

Effect of acid-base status on plasma phosphorus response to lactate

The mechanism(s) underlying the hyperphosphatemia of lactic acidosis is uncertain. We assessed the interacting influence of the acid anion and acid-base status on plasma phosphorus concentration by administering lactic acid alone, lactic acid plus sodium bicarbonate, sodium bicarbonate alone, and sodium lactate alone to four different groups of dogs. The findings of (1) no increase in plasma phosphorus concentration with lactic acid plus sodium bicarbonate versus a marked increment with lactic acid alone, and (2) no difference in the plasma phosphorus response to sodium lactate versus sodium bicarbonate indicate that acidemia is necessary for the expression of lactate-induced hyperphosphatemia. The apparent greater propensity for marked hyperphosphatemia in lactic acidosis than in other types of metabolic acidosis remains unexplained, but conceivably might relate to differences in intracellular pH and in the rate of glycolysis.     

Hypothermia: a complication of diabetic ketoacidosis.

During 1969-77, 20 episodes of severe hypothermia occurred in 19 diabetic patients in Nottingham. Thirteen were associated with ketotic hyperosmolar coma, two with lactic acidosis, and one with hypoglycaemia, while in four there was no loss of diabetic control. Ketoacidosis accounted for 11.8% of all admissions for severe accidental hypothermia and was a commoner cause than hypothyroidism (8%). Patients with ketoacidosis were younger and developed hypothermia as often during the summer as during the winter. The metabolic disturbance was characteristic, with severe acidosis (mean pH 7.04), a high blood glucose concentration (mean 56.6 mmol/l; 1020 mg/100 ml), and high plasma osmolality (mean 379.7 mmol (mosmol)/kg). Eight of the 13 episodes proved fatal. Hypothermia may aggravate ketoacidosis and complicate treatment and should be sought in all patients with severe diabetic coma.     

Diabetic ketoacidosis induces in vivo activation of human T-lymphocytes

Diabetic ketoacidosis (DKA) is an inflammatory state associated with immune responses in polymorphonuclear cells (PMN). Activation of subgroup of T-lymphocytes in PMN of DKA patients, however, is not known. We studied in vivo activation of CD4 and CD8 lymphocytes by measuring de novo growth factor receptor for insulin, IGF-1, and IL-2 in eight patients on admission and at resolution of DKA, and compared them with matched controls. The presence of these receptors was demonstrated in all patients' lymphocytes on admission, but not in control subjects. This event was associated with increased levels of thiobarbituric acid-reacting material and dichlorofluorescien, as markers of oxidative stress. Based on these new findings and works in the literature, we hypothesize that hyperglycemia/ketosis results in increased reactive oxygen species, leading to increased levels of cytokines and emergence of growth factor receptors. We propose DKA changes the T-lymphocytes to insulin sensitive tissues as a compensatory mechanism.     

Transient extreme insulin resistance in shock during diabetic ketoacidosis.

Transient extreme insulin resistance was encountered during an episode of diabetic ketoacidosis (DKA) in an insulin-treated diabetic patient. On admission, the plasma glucose level was 1241 mg dl-1 and arterial blood pH 6.895 with HCO3- 4.7 mEql-1. An intravenous bolus injection of 20 units, followed by continuous infusion of 20 units h-1 of short-acting regular human insulin, was instituted. Ischemic myocardial changes were noted on the initial electrocardiogram, therefore fluid replacement was limited to 1,000 ml of 0.9% saline solution in the first hour. As the plasma glucose level declined by only 203 mg dl-1 (41 mg dl-1 h-1) in the first 5 h, the insulin dose was doubled every 2 h. At hour 4, the patient developed circulatory shock which required vasopressor support and respiratory assistance. A plasma glucose level of 300 mg dl-1 was not achieved until the total dosage of insulin amounted to 91,580 units at hour 25. Insulin resistance was not observed from that point on. The patient had neither insulin antibodies nor anti-insulin receptor antibodies in serologic testing. The insulin binding characteristics of the patient's erythrocytes were similar to those from healthy controls both with and without experimental acidosis and with a high level of beta-hydroxybutyrate. Among multiple potential factors, the severe shock associated with DKA has been considered as a primary cause of the transient severe insulin resistance in this case.     

Effect of air breathing on acid-base and ion regulation after exhaustive exercise and during low pH exposure in the bowfin, Amia calva.

To explore a potential conflict between air breathing and acid-base regulation in the bowfin (Amia calva), we examined how individuals with access to air differed from fish without air access in their response to acidosis. After exhaustive exercise, bowfin with access to air recovered significantly more slowly from the acidosis than fish without air access. While arterial blood pH (pH(a)) of fish without air access recovered to resting levels by 8 h, pH(a) was still significantly depressed in fish having access to air. In addition, Pco(2) was slightly more elevated in fish having air access than those without it. Fish with access to air still had a significant metabolic acid load after 8-h recovery, while those without air access completely cleared the load within 4 h. These results suggest that bowfin with access to air were breathing air and, consequently, were less able to excrete CO(2) and H(+) and experienced a delayed recovery. In contrast, during exposure to low pH, air breathing seemed to have a protective effect on acid-base status in bowfin. During exposure to low pH water, bowfin with access to air developed a much milder acidosis than bowfin without air access. The more severe acidosis in fish without air access was caused by an increased rate of lactic acid production. It appears that enhanced O(2) delivery allowed air-breathing bowfin to avoid acidosis-induced anaerobic metabolism and lactic acid production. In addition, during low pH exposure, plasma Na(+) and Cl(-) concentrations of fish without air access fell slightly more rapidly than those in fish with air access, indicating that the branchial ventilatory changes associated with air breathing limited, to some degree, ion losses associated with low pH exposure.     

Plasma prostaglandin levels and circulating fuel levels in rats with diabetic ketoacidosis: Effects of cyclooxygenase inhibitors and of alpha and beta adrenergic blockade

We studied the effects of two structurally unrelated inhibitors of the fatty acid cyclooxygenase and of alpha and beta adrenergic blockade on the elevated plasma levels of 13,14-dihydro-15-keto-prostaglandin (PG)E₂, 6-keto-PGF_1α and thromboxane(TX)B₂, the stable derivatives of PGE₂, PGI₂ (prostacyclin) and TXA₂, respectively, in rats with streptozotocin-induced diabetic ketoacidosis (DKA). Meclofenamic acid and indomethacin each produced a significant decrease in the elevated plasma levels of 13,14-dihydro-15-keto-PGE₂, 6-keto-PGF_1α and TXB₂. Phentolamine significantly reduced the plasma level of TXB₂ but had no effect on the elevated circulating levels of glucose, free fatty acids, total ketones, 13,14,-dihydro-15-keto-PGE₂ or 6-keto-PGF_1α. Propranolol significantly reduced the elevated circulating levels of glucose, free fatty acids and total ketones but had no effect on the levels of the three prostaglandin derivatives. The ability of meclofenamic acid and indomethacin to reduce the plasma levels of 13,14-dihydro-15-keto-PGE₂, 6-keto-PGF_1α and TXB₂ confirms that the plasma levels of these three derivatives are elevated in rats with DKA. Since abnormalities in the production of PGI₂ and perhaps other cyclooxygenase derivatives may contribute to the pathogenesis of certain important hemodynamic and gastrointestinal features of DKA, cyclooxygenase inhibitors may play a role in the management of selected patients with this disorder. Alpha adrenergic activity is essential for the maintenance of the elevated plasma TXB₂ level in rats with DKA. The fall in the plasma TXB₂ level during alpha adrenergic blockade appears to reflect inhibition of platelet aggregation and platelet TXA₂ production, but other sources of the elevated plasma TXB₂ level in DKA are not excluded. Beta adrenergic activity contributes to the maintenance of elevated circulating levels of glucose, free fatty acids and total ketones in experimental DKA but not to the elevated plasma levels of the prostaglandin derivatives.     

Muscle glutamine production in diabetic ketoacidotic rats.

The mechanism of activation of glutamine production by the hindlimb during diabetic ketoacidosis (DKA) was investigated in rats. Muscle glutamine production was estimated to account for over 90% of the total glutamine produced by the hindlimb. DKA produced significant increases in the concentrations of NH4+ and IMP in hindlimb muscles, suggesting that AMP deaminase is activated by DKA. NH4Cl- and HCl-induced acidosis did not produce these changes, indicating either that acidosis itself is not the stimulus for increased AMP deaminase activity or that the more severe degree of acidosis accompanying DKA is necessary for activation. Muscle glutamine concentrations were depressed in DKA. Experiments with isolated epitrochlearis muscle showed that the transport and permeability properties of the muscle cells (as judged by uptake and release of alpha-aminoisobutyrate and glutamine) were not altered by DKA. However, glutamine uptake by muscle cells was significantly inhibited by L-leucine, the concentration of which, along with other branched-chain amino acids, is markedly elevated in DKA.     

Effects of metabolic acidosis and diabetes on the abundance of specific renal mRNAs

1. The effects of exogenously (NH4Cl ingestion) and endogenously (streptozotocin-diabetes) generated chronic metabolic acidosis on the abundance of rat renal mRNAs have been examined. 2. Total RNA was translated in vitro and the translation products analyzed by two-dimensional gel electrophoresis. 3. The translation product identified as phosphoenolpyruvate carboxykinase (PEPCK) increased 3.5-fold in both acidosis and diabetes. 4. This increase was not observed in diabetic rats treated with NaHCO3. 5. The abundance of one other translation product increased in acidosis. 6. That of 10 others increased in diabetes, several of which were elevated regardless of acid-base status. 7. The abundance of one translation product decreased in acidosis and diabetes but not in NaHCo3 treated diabetic rats, indicating acid-base regulation of this product. 8. The results establish that the acidosis response is limited to a small number of renal mRNAs and confirm that renal PEPCK is primarily regulated by changes in acid-base status. 9. They also indicate that diabetes affects the abundance of specific renal mRNAs through mechanisms independent of acid-base status.     

Venous Serum Bicarbonate Concentration Predicts Arterial pH in Adults with Diabetic Ketoacidosis

ObjectiveThe initial assessment of metabolic acidosis in subjects with diabetic ketoacidosis (DKA) is arterial blood gas analysis. This process is expensive, painful, and technically difficult. Furthermore, blood gas analysis may not be available in some facilities, especially in developing countries where DKA-associated morbidity and mortality remain high. Therefore, we investigated the utility of venous bicarbonate concentration obtained from a basic metabolic panel in predicting arterial pH in adults with DKA.MethodsWe performed a retrospective analysis of clinical and biochemical data of 396 adults admitted to 2 community teaching hospitals with DKA. We determined the correlation between arterial pH and venous serum parameters. Using multiple logistic regression, we obtained a predictive formula for arterial pH from serum venous bicarbonate level.ResultsThe patient population was 59.0% male and had a mean age of 36.7 ± 13.3 years. We derived that arterial pH = 6.97 + (0.0163 × bicarbonate), and by applying this equation, we determined that serum venous bicarbonate concentration of ≤ 20.6 mEq/L predicted arterial pH ≤ 7.3 with over 95% sensitivity and 92% accuracy.ConclusionVenous serum bicarbonate obtained from the basic metabolic panel is an affordable and reliable way of estimating arterial pH in adults with DKA. Validation of this formula in a prospective study would offer a more accessible means of estimating metabolic acidosis in adults with DKA, especially in developing countries where DKA incidence and mortality remain high. (Endocr Pract. 2014;20:201-206)     

The status of metformin in Canada.

During the 1970s two biguanide drugs, phenformin and metformin, were used to control hyperglycemia. Phenformin was phased out of the Canadian market because it carried an unacceptable risk of causing lactic acidosis, but metformin remains available. All documented cases of lactic acidosis associated with metformin administration, which are rare, have occurred abroad in patients who were taking the drug in spite of having contraindications to its use. The two drugs are metabolized differently, phenformin being deactivated and concentrated in the liver, and metformin being excreted rapidly, unchanged, by the kidneys. In properly selected diabetic patients therapeutic doses of metformin do not raise the blood levels of intermediary metabolites enough to induce ketoacidosis or lactic acidosis. The safety of the drug is supported by the clinical experience over about 56,000 patient-years in Canada.     

A review of 126 Caesarean sections by blood gas and the acid-base status of newborn calves

Blood gas and acid-base status was determined in 126 Caesarean-derived calves. The newborn calves were assigned by venous blood pH value at birth to three groups as follows: Group 1 (normal): pH above 7.2; Group 2 (slight acidosis): pH 7.2 to 7.0; and Group 3 (severe acidosis): pH below 7.0. Following Caesarean section births 80 (63.5%) calves had normal acid-base values, while 30 (23.8%) had a slight acidosis, and 16 (12.7%) had severe acidosis. The degree of hypoxia was similar in each group. Six calves (37.5%) in Group 3 died within 48 h of birth. The blood gas and acid-base status of Caesarean-derived. calves was not significantly influenced by any examined parameters with the exception of sex in Groups 1 and 2. The occurrence of meconium-stained calves was 9.1% (n = 11), and only two calves were slightly or severely acidotic immediately after birth.     

Renal metabolism during four types of lactic acidosis in the dog including anoxia

The present study was undertaken to evaluate the metabolic response of the kidney to lactic acidosis. Four types of lactic acidosis were induced in the dog: infusion of lactic acid, infusion of lactic acid with phenformin, administration of phenformin alone, and hypoxia by breathing 95% nitrogen. In all groups of animals, the same degree of acidosis was observed with plasma bicarbonate ranging from 12.8 to 14.9 mM. Plasma lactate concentration ranged from 3.0 to 8.1 mumol/mL. Renal ammoniagenesis failed to be influenced by lactic acidosis. As a matter of fact, it fell during anoxia. The extraction of glutamine by the kidney rose except during anoxia where it fell. The renal production of alanine rose during the infusion of lactic acid with and without phenformin. This coincided with the extraction of glutamine. The renal extraction of lactate rose in all forms of acidosis as well as the production of pyruvate. In the renal cortical tissue, the concentration of malate, pyruvate, and lactate rose. Alanine also rose except during anoxia. An important fall in cytosolic redox potential (NAD+/NADH lactate dehydrogenase) was observed, as well as a fall in mitochondrial redox (NAD+/NADH beta-hydroxybutyrate dehydrogenase). Lactate also accumulated in the liver and in the muscle. We propose that the kidney is unable to respond to lactic acidosis in terms of ammonia production and that this phenomenon is explained by transamination of pyruvate and glutamate into alanine and also by the observed fall in cytosolic redox potential. It is likely that renal gluconeogenesis is also inhibited and this is reflected by the rise in the concentration of malate in the kidney.(ABSTRACT TRUNCATED AT 250 WORDS)     

Somatostatin and insulin infusion in the management of diabetic ketoacidosis

The effect of low-dose insulin infusion (4.8 U/h) in diabetic ketoacidosis was compared to that of low-dose insulin infusion (4.8 U/h) plus somatostatin (500 microgram/h IV). Treatment with insulin only in 20 patients caused normalization of blood glucose levels within 6 hours and resolution of ketoacidosis within 5 hours. During insulin plus somatostatin infusion in 7 patients, blood glucose levels returned to normal within 4 hours and acidosis was reduced within 3 hours. Correction of acidosis is the most important problem in diabetic ketoacidosis: in the severest cases cardiovascular and cerebral complications may ensue. The data presented show that addition of somatostatin to treatment with low doses of insulin reduces and resolves acidosis in a shorter time while plasma levels of glucagon and GH were concomitantly reduced.     

Cerebrospinal fluid ions in metabolic acidosis in dogs: effects of acetazolamide

We hypothesized that, during isosmotic isonatremic HCl acidosis with maintained isocapnia in cisternal cerebrospinal fluid (CSF), acetazolamide, by inhibiting carbonic anhydrase (CA) in the central nervous system (CNS), should produce an isonatric hyperchloric metabolic acidosis in CSF. Blood and CSF ions and acid-base variables were measured in two groups of anesthetized and paralyzed dogs with bilateral ligation of renal pedicles during 5 h of HCl acidosis (plasma [HCO3-] = 11 meq/l). Mechanical ventilation was regulated such that arterial PCO2 dropped and CSF Pco2 remained relatively constant. In group I (control group, n = 6), CSF [Na+] remained unchanged, [HCO3-] and strong ions difference (SID) fell, respectively, 6.1 and 5 meq/l, and [Cl-] rose 3.5 meq/l after 5 h of acidosis. In acetazolamide-treated animals, (group II, n = 7), CSF [Na+] remained unchanged, [HCO3-], and SID fell 11 and 7.1 meq/l, respectively, and [Cl-] rose 7.1 meq/l. We conclude that during HCl acidosis inhibition of CNS CA by acetazolamide induces an isonatric hyperchloric metabolic acidosis in CSF, which is more severe than that observed in controls.     

Lactic and hydrochloric acids induce different patterns of inflammatory response in LPS-stimulated RAW 264.7 cells

Metabolic acidosis frequently complicates sepsis and septic shock and may be deleterious to cellular function. Different types of metabolic acidosis (e.g., hyperchloremic and lactic acidosis) have been associated with different effects on the immune response, but direct comparative studies are lacking. Murine macrophage-like RAW 264.7 cells were cultured in complete medium with lactic acid or HCl to adjust the pH between 6.5 and 7.4 and then stimulated with LPS (Escherichia coli 0111:B4; 10 ng/ml). Nitric oxide (NO), IL-6, and IL-10 levels were measured in the supernatants. RNA was extracted from the cell pellets, and RT-PCR was performed to amplify corresponding mediators. Gel shift assay was also performed to assess NF-kappa B DNA binding. Inc easing concentrations of acid caused increasing acidification of the media. Trypan blue exclusion and lactate dehydrogenase release demonstrated that acidification did not reduce cell viability. HCl significantly increased LPS-induced NO release and NF-kappa B DNA binding at pH 7.0 but not at pH 6.5. IL-6 and IL-10 expression (RNA and protein) were reduced with HCl-induced acidification, but IL-10 was reduced much more than IL-6 at low pH. By contrast, lactic acid significantly decreased LPS-induced NO, IL-6, and IL-10 expression in a dose-dependent manner. Lactic acid also inhibited LPS-induced NF-kappa B DNA binding. Two common forms of metabolic acidosis (hyperchloremic and lactic acidosis) are associated with dramatically different patterns of immune response in LPS-stimulated RAW 264.7 cells. HCl is essentially proinflammatory as assessed by NO release, IL-6-to-IL-10 ratios, and NF-kappa B DNA binding. By contrast, lactic acidosis is anti-inflammatory.     

CO2 mass transfer and acid-base balance under conditions of muscular activity at sea level and in the mountains

The state of the blood acid-base balance and dynamics of carbonic acid gas mass transfer were studied in sportsmen at the sea level and in mountains. It is shown that at the sea level due to an intensive muscular activity large amounts of CO2 are formed and excreted; the mass transfer of this gas is multiply accelerated, simultaneously, a pronounced decompensated metabolic acidosis is observed which in some cases is complicated respiratory acidosis. The similar exercises in mountains are followed by a more pronounced disturbance in the acid-base balance and a more intensified mass-transfer of CO2. After 12-day acclimatization and training in mountains the buffer blood capacity increases, the metabolic acidosis under conditions of muscular activity is less pronounced.     

Etiology of lactic acidosis in malaria

Lactic acidosis and hyperlactatemia are common metabolic disturbances in patients with severe malaria. Lactic acidosis causes physiological adverse effects, which can aggravate the outcome of malaria. Despite its clear association with mortality in malaria patients, the etiology of lactic acidosis is not completely understood. In this review, the possible contributors to lactic acidosis and hyperlactatemia in patients with malaria are discussed. Both increased lactate production and impaired lactate clearance may play a role in the pathogenesis of lactic acidosis. The increased lactate production is caused by several factors, including the metabolism of intraerythrocytic Plasmodium parasites, aerobic glycolysis by activated immune cells, and an increase in anaerobic glycolysis in hypoxic cells and tissues as a consequence of parasite sequestration and anemia. Impaired hepatic and renal lactate clearance, caused by underlying liver and kidney disease, might further aggravate hyperlactatemia. Multiple factors thus participate in the etiology of lactic acidosis in malaria, and further investigations are required to fully understand their relative contributions and the consequences of this major metabolic disturbance.     

Cerebral Syndromes of Diabetes Mellitus

Three labile diabetic patients had recurring episodes of altered sensorium. Each had severe cerebrovascular disease with superimposed metabolic derangements, including ketoacidosis, hyperglycemia without ketosis, mild uremia, and possibly cerebral edema. Two of the patients were examined postmortem. Severe leptomeningeal scarring, basal ganglial calcification and destruction of small intracerebral vessels without evidence of large vessel atherosclerosis were found unexpectedly in one patient, a rare occurrence in this country although recently reported from Europe. The other patient had large vessel atherosclerosis only.The clinical expression of the vascular disease was modified by concurrent abnormalities and reflected the sum total of the complexities which coexisted. The pathophysiology of the unconscious state necessarily depends on the inciting factors. Ketoacidotic coma is associated with depressed cerebral oxygen consumption. Spinal fluid pH is usually maintained during ketosis but is sometimes lowered inadvertently during bicarbonate therapy, with resultant coma. Other variables influencing the clinical expression, with or without ketosis, would include, among others, blood viscosity alterations, rapid decrements in blood sugar, and existing degrees of lactic acidosis.The increasing life-span of the juvenile diabetics, favorably influenced by improved management and recently by hemodialysis, may uncover vascular complications heretofore rarely seen and create additional diagnostic and therapeutic enigmas.