Lacticacidosis: A Clinically Significant Aspect of Shock

A study was made of the metabolic acidosis of hypotensive shock in 25 patients in an attempt to elucidate its etiology and to determine if the degree of acidosis might be a good parameter for the evaluation of treatment and prognosis.Blood lactate was elevated (> 1.3 mEq./l.) in 24 of 25 patients in hypotensive shock. There was a good correlation (r= 0.83, p < 0.01) between rising blood lactate and decrease in serum bicarbonate and arterial pH, early in shock. These data indicate that the metabolic acidosis of early shock is largely due to lactate ion. Evidence is presented that high blood lactate levels early in shock are indicative of poor prognosis.     

Lactic Acidosis in Diabetes

Lactic acidosis is occasionally responsible for metabolic acidosis in diabetics. It may occur in the presence of normal blood levels of the ketone bodies, and such cases are often described as having “non-ketotic diabetic acidosis.” Lactic acid may contribute to the metabolic acidosis in patients with true diabetic ketoacidosis, but the blood lactate concentrations in these patients are not usually very high. In some patients the ketoacidosis is replaced by a lactic acidosis during treatment. This usually occurs in association with a serious underlying disorder and is associated with a poor prognosis. A transient increase in blood lactate concentration was in fact observed in most patients after the beginning of treatment, but the significance of this finding is uncertain.     

Acid-base Balance in Acute Gastrointestinal Bleeding

Acid-base balance has been studied in 21 patients with acute upper gastrointestinal bleeding. A low plasma bicarbonate concentration was found in nine patients, accompanied in each case by a base deficit of more than 3 mEq/litre, indicating a metabolic acidosis. Three patients had a low blood pH. Hyperlactataemia appeared to be a major cause of the acidosis. This was not accompanied by a raised blood pyruvate concentration. The hyperlactataemia could not be accounted for on the basis of hyperventilation, intravenous infusion of dextrose, or arterial hypoxaemia. Before blood transfusion it was most pronounced in patients who were clinically shocked, suggesting that it may have resulted from poor tissue perfusion and anaerobic glycolysis. Blood transfusion resulted in a rise in lactate concentration in seven patients who were not clinically shocked, and failed to reverse a severe uncompensated acidosis in a patient who was clinically shocked. These effects of blood transfusion are probably due to the fact that red blood cells in stored bank blood, with added acid-citrate-dextrose solution, metabolize the dextrose anaerobically to lactic acid. Monitoring of acid-base balance is recommended in patients with acute gastrointestinal bleeding who are clinically shocked. A metabolic acidosis can then be corrected with intravenous sodium bicarbonate.     

Failure of pulmonary acidosis to increase respiratory drive.

Experiments were performed to determine whether increases in acidity isolated to the pulmonary circulation would stimulate hypothesized pulmonary chemoreceptors and increase respiratory drive in the anesthetized paralyzed mechanically ventilated cat (n = 9). Respiratory drive was assessed by measuring the frequency and amplitude of the integrated phrenic neurogram. To create an isolated pulmonary acidosis, blood returning to the lung was acidified by infusion of 0.3 M lactic acid (1.91 ml/min) into the inferior vena cava, while systemic arterial pH was restored to near normal levels by simultaneous infusion of base (0.3 M NaOH) into the left atrium. Six minutes after the start of this dual infusion of acid and base, right ventricular (pulmonary) pH decreased from 7.286 to 7.179 and PCO2 increased 7 Torr. Systemic arterial pH and PCO2 were unchanged from measurements immediately before the infusion. This level of pulmonary acidosis failed to increase respiratory drive as assessed by phrenic activity. To test the sensitivity of the preparation to known systemic arterial chemical stimuli, a combined pulmonary and systemic acidosis was elicited by infusion of 0.3 M lactic acid into the inferior vena cava and 0.3 M NaCl into the left atrium. This infusion significantly lowered both systemic arterial and pulmonary arterial pH (7.343 to 7.155 for systemic arterial pH and 7.286 to 7.067 for pulmonary pH) and increased phrenic efferent activity 45%. We conclude that phrenic efferent activity is unaffected by moderate reductions in the pH of the pulmonary circulation in the absence of a significant systemic arterial acidosis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sodium Bicarbonate Treatment during Transient or Sustained Lactic Acidemia in Normoxic and Normotensive Rats

Introduction

Lactic acidosis is a frequent cause of poor outcome in the intensive care settings. We set up an experimental model of lactic acid infusion in normoxic and normotensive rats to investigate the systemic effects of lactic acidemia per se without the confounding factor of an underlying organic cause of acidosis.

Methodology

Sprague Dawley rats underwent a primed endovenous infusion of L(+) lactic acid during general anesthesia. Normoxic and normotensive animals were then randomized to the following study groups (n = 8 per group): S) sustained infusion of lactic acid, S+B) sustained infusion+sodium bicarbonate, T) transient infusion, T+B transient infusion+sodium bicarbonate. Hemodynamic, respiratory and acid-base parameters were measured over time. Lactate pharmacokinetics and muscle phosphofructokinase enzyme''s activity were also measured.

Principal Findings

Following lactic acid infusion blood lactate rose (P<0.05), pH (P<0.05) and strong ion difference (P<0.05) drop. Some rats developed hemodynamic instability during the primed infusion of lactic acid. In the normoxic and normotensive animals bicarbonate treatment normalized pH during sustained infusion of lactic acid (from 7.22±0.02 to 7.36±0.04, P<0.05) while overshoot to alkalemic values when the infusion was transient (from 7.24±0.01 to 7.53±0.03, P<0.05). When acid load was interrupted bicarbonate infusion affected lactate wash-out kinetics (P<0.05) so that blood lactate was higher (2.9±1 mmol/l vs. 1.0±0.2, P<0.05, group T vs. T+B respectively). The activity of phosphofructokinase enzyme was correlated with blood pH (R2 = 0.475, P<0.05).

Conclusions

pH decreased with acid infusion and rose with bicarbonate administration but the effects of bicarbonate infusion on pH differed under a persistent or transient acid load. Alkalization affected the rate of lactate disposal during the transient acid load.     

In vitro activation of complement and contact system by lactic acidosis.

The activation of complement and contact systems occurs in reperfusion injuries with initial tissue hypoxia, and lactic acidosis such as mycardial infarction and birth asphyxia. The aim of our experiment was the formal proof of activation by sole lactic acidosis. Lactic acid was added to blood and plasma samples from 10 healthy volunteers. C5a and factor XIIa were measured by EIA after incubation at 37 degrees C for 1 h. Both concentrations increased (P < 0.0001 by Friedman analysis) in blood and plasma samples with increasing amount of added lactic acid. Lactic acidosis can activate C5 from the complement system and factor XII from the contact system directly, even in the absence of cellular components.     

Role of brain lactic acidosis in hypoxic depression of respiration

The role of lactic acidosis of progressive brain hypoxia (PBH) as both a central chemoreceptor stimulant and a general respiratory depressant was assessed by preventing lactate formation both locally and globally with dichloroacetate (DCA). Phrenic nerve activity (PN) and ventral medullary pH (Vm pH) responses to PBH (1% CO-40% O2-balance N2) were determined in anesthetized, paralyzed, peripherally chemodenervated, vagotomized cats while fraction of end-tidal CO2 (FETCO2) and mean arterial blood pressure (MABP) were maintained constant. Topical DCA near the central chemoreceptors prevented the progressive Vm acidosis of PBH and was associated with a slightly greater depression of PN for any given level of brain hypoxia [75 +/- 12% base-line mock cerebrospinal fluid compared with 63 +/- 11% base-line topical DCA at O2 content of arterial blood (CaO2) of 7.5 ml O2/dl]. Systemic DCA also prevented the progressive acidosis of PBH and significantly altered the profile of depression with PBH. Before DCA, PBH produced a progressive reduction in PN after reducing CaO2 by 20%. After DCA, PN was not significantly depressed until CaO2 was reduced to very low levels, whereupon there was a sharp decline in PN. Before DCA, reducing CaO2 to 6 ml O2/dl reduced PN by 41 +/- 16%, whereas after DCA there was no significant reduction in PN (4 +/- 5%). We conclude that 1) lactic acidosis near the central chemosensitive regions does produce a small stimulation of respiration during PBH but that 2) the overwhelming response to central lactic acidosis of PBH is respiratory depression.     

CO2 sensitivity of cat phrenic neurogram during hypoxic respiratory depression

The CO2 response of the phrenic neurogram before and during CO-induced isocapnic brain hypoxia was studied in peripherally chemodenervated, vagotomized, paralyzed, ventilated cats with blood pressure held constant. During inhalation of 0.5% CO in 40% O2, arterial O2 content (CaO2) was reduced to 40% and minute phrenic activity to 38.4 +/- 9.4% (SE; n = 9) of prehypoxic levels, primarily due to depression of peak phrenic amplitude (PP). CO2 response, defined as the slope of the plot of PP vs. end-tidal PCO2 during CO2 rebreathing, was unaffected by phrenic depression even to the point of total suppression of phrenic activity in two cats. The effect of the tissue metabolic acidosis associated with hypoxia on phrenic CO2 sensitivity was assessed in a separate group of cats by blocking lactate formation during hypoxia with dichloroacetate (DCA). Preventing lactic acidosis during hypoxia did not affect the CO2 response of the phrenic activity during hypoxia. We conclude that 1) hypoxic depression does not limit the ability of central respiratory neurons to respond to CO2, and 2) the failure of DCA to affect the CO2 response of the phrenic neurogram suggests that brain intracellular lactic acidosis does not modify the phrenic response to hypercapnia.     

Acid Base Disorders—The Clinical Use of the Astrup Method of Determining pH. pCO2 and Base Excess

The Astrup method for determination of arterial pH, pCO₂, and “base excess” provides a simple and accurate means for quantitation of acid-base disorders. The “base excess” value, a measure of metabolic acidosis or alkalosis, gives the clinician a valuable tool with which to estimate electrolyte replacement. The pCO₂ is a measure of respiratory acidosis or alkalosis. The pH is used as a measure of the adequacy of compensation. Several representative cases illustrate the use and interpretation of the test.     

The Acid-Base Status in Cyanotic Congenital Heart Disease

The relation between oxygen consumption, metabolic status and prognosis was studied in two infants with identically low arterial oxygen tensions (20 mm. Hg) due to cyanotic congenital heart disease. The first patient had low oxygen consumption, arterial blood acidosis and increased arterial lactate, and died at the age of 36 hours. The second had normal oxygen consumption, arterial acid-base balance, lactate and pyruvate, and survived. Since arterial oxygen tensions were similar in both, it was concluded that compensatory factors, such as cardiac output, pulmonary and systemic blood flow and increased oxygen saturation at normal pH levels (Bohr effect), are important in maintaining tissue oxidation and preventing anaerobiosis and lactate production. The importance of a knowledge of acid-base status in the immediate prognosis of cyanotic congenital heart disease is stressed. The treatment of acidosis by buffer therapy may be an important palliative, improving cardiac output and tissue oxidation, and should be undertaken as soon as possible before irreversible cellular damage has occurred.     

Acidosis-induced modifications of high-affinity choline uptake by synaptosomes: Effects of pH readjustment

Acidosis (pH 6.0) led to significant decrease in high—affinity choline uptake by rat brain synaptosomes. The effects persisted following pH readjustment (7.4) of the incubation medium, consisting of decrease in both Km and Vmax of the affinity system. pH readjustment coincided with synaptosomal leakage of lactate dehydrogenase (LDH) and with instability of the synaptosomal suspension as evidenced from turbidity modifications of the preparation. LDH leakage occurred when acidosis was performed with lactic acid, whereas it was not seen following H₃PO₄ acidosis, probably because of the rapid diffusion of the protonated form of lactic acid across membranes. Turbidity modifications of the suspension were prevented by EDTA. The present results indicate that acidosis to pH level comparable to what is observed in brain ischemia is deleterious for cholinergic mechanisms. They also suggest that alkaline pH shifts that occur after blood reperfusion of ischemic brain tissue might be critical for the survival of cells.To whom to address reprint requests.     

Carotid bodies are required for ventilatory acclimatization to chronic hypoxia

We have compared the ventilatory responses of intact and carotid body-denervated (CBD) goats to moderate [partial pressure of O2 in arterial blood; (Pao2) approximately 44 Torr] and severe (Pao2 approximately 33 Torr) many time points for up to 7 days of hypobaria. In the intact group there were significant time-dependent decreases in partial pressure of CO2 in arterial blood (PaCO2) in both moderate and severe hypoxemia (approximately-7 and -11 Torr) that were largely complete by 8 h of hypoxemia and maintained throughout. Acute restoration of normoxia in chronically hypoxic intact animals produced time-dependent increases in Paco2 over 2 h, but hypocapnia persisted relative to sea-level control. Arterial plasma [HCO3-] and [H+] decreased, and [Cl-] increased with a time course and magnitude consistent with developing hypocapnia. Chronic CBD, per se, resulted in a sustained, partially compensated respiratory acidosis, as PaCO2 rose 6 Torr and base excess rose 3 mEq/1, [Cl-] fell 1 mEq/1, and pHa fell 0.01 units. During exposure to identical levels of arterial hypoxemia as in the intact group. CBD animals showed no significant changes in PaCO2, [H+]a, or [HCO3-]a at any time during moderate or severe hypoxemia. Plasma [C1-] remained within the normal range throughout exposure to moderate hypoxia and increased in severe hypoxia. In a few instances some hypocapnia was observed, but this was highly inconsistent and was always less than one-third of that observed in intact goats. In contrast to intact goats, acute restorations of normoxia in the chronically hypoxic CBD goats always caused hyperventilation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Lactic acidosis secondary to metformin overdose: a case report

ABSTRACT: INTRODUCTION: Metformin is a commonly used treatment modality in type 2 diabetes mellitus, with a welldocumented side effect of lactic acidosis. In the intensive care setting lactate and pH levelsare regularly used as a useful predictor of poor prognosis. In this article we highlight howhigh lactate levels are not an accurate predictor of mortality in deliberate metforminoverdose. CASE PRESENTATION: We present the case of a 70-year-old Caucasian man who took a deliberate metforminoverdose of unknown quantity. He had a profound lactic acidosis at presentation with a pH of6.93 and a lactate level of more than 20mmol/L. These figures would normally correspondwith a mortality of more than 80%; however, with appropriate management this patient'scondition improved. CONCLUSION: We provide evidence that the decision to treat severe lactic acidosis in deliberate metforminoverdose should not be based on arterial lactate and pH levels, as would be the case in otheroverdoses. We also demonstrate that appropriate treatment with hemodiafiltration and 8.4%sodium bicarbonate, even in patients with a very high lactate and low pH, can be successful.     

Toxic effect of the combination of propranolol and phenformin combination in anesthetized dogs

Phenformin (20 mg/kg subcutaneously) as well as propranolol (0.3 mg/kg. i.v.) induced an increase in blood lactate level in the normal anesthetized log; with phenformin a slight decrease in the arterial pH was noted. The combined administration of phenformin (20 mg/kg subcutaneously) and propranolol (0.3 mg/kg. i.v.) induced a more rapid increase in lactate level, a slight reduction of arterial pH and led to the death of the animals in all cases. After a chronic treatment by phenformin (20 mg/kg daily orally during 7 days, the administration of phenformin (20 mg/kg subcutaneously) induced lactic acidosis in 3 out of the 8 animals and death within 150 minutes. In the animals pretreated by phenformin, the combined administration of phenformin (20 mg/kg subcutaneously) and propranolol (0.3 mg/kg i.v.) caused the death of all the animals without the occurrence of lactic acidosis. These results point to the possible toxicity of the propranolol-phenformin combination.     

Effects of the ionophores monensin and tetronasin on simulated development of ruminal lactic acidosis in vitro.

A continuous coculture of four ruminal bacteria, Megasphaera elsdenii, Selenomonas ruminantium, Streptococcus bovis, and Lactobacillus sp. strain LB17, was used to study the effects of the ionophores monensin and tetronasin on the changes in ruminal microbial ecology that occur during the onset of lactic acidosis. In control incubations, the system simulated the development of lactic acidosis in vivo, with an initial overgrowth of S. bovis when an excess of glucose was added to the fermentor. Lactobacillus sp. strain LB17 subsequently became dominant as pH fell and lactate concentration rose. Both ionophores were able to prevent the accumulation of lactic acid and maintain a healthy non-lactate-producing bacterial population when added at the same time as an excess of glucose. Tetronasin was more potent in this respect than monensin. When tetronasin was added to the culture 24 h after glucose, the proliferation of lactobacilli was reversed and a non-lactate-producing bacterial population developed, with an associated drop in lactate concentration in the fermentor. Rises in culture pH and volatile fatty acid concentrations accompanied these changes. Monensin was unable to suppress the growth of lactobacilli; therefore, in contrast to tetronasin, monensin added 24 h after the addition of glucose failed to reverse the acidosis. Numbers of lactobacilli and lactate concentrations remained high, whereas pH and volatile fatty acid concentrations were low.     

Determination of pH or lactate in fetal scalp blood in management of intrapartum fetal distress: randomised controlled multicentre trial

Objective To examine the effectiveness of pH analysis of fetal scalp blood compared with lactate analysis in identifying hypoxia in labour to prevent acidaemia at birth.Design Randomised controlled multicentre trial.Setting Labour wards.Participants Women with a singleton pregnancy, cephalic presentation, gestational age ≥34 weeks, and clinical indication for fetal scalp blood sampling. Interventions Standard pH analysis (n=1496) or lactate analysis (n=1496) with an electrochemical microvolume (5 μl) test strip device. The cut-off levels for intervention were pH <7.21 and lactate >4.8 mmol/l, respectively.Main outcome measure Metabolic acidaemia (pH <7.05 and base deficit >12 mmol/l) or pH <7.00 in cord artery blood.Results Metabolic acidaemia occurred in 3.2% in the lactate group and in 3.6% in the pH group (relative risk 0.91, 95% confidence interval 0.61 to 1.36). pH <7.00 occurred in 1.5% in the lactate group and in 1.8% in the pH group (0.84, 0.47 to 1.50). There was no significant difference in Apgar scores <7 at 5 minutes (1.15, 0.76 to 1.75) or operative deliveries for fetal distress (1.02, 0.93 to 1.11).Conclusion There were no significant differences in rate of acidaemia at birth after use of lactate analysis or pH analysis of fetal scalp blood samples to determine hypoxia during labour. Trial registration ISRCT No 1606064.     

血乳酸水平动态监测在危重症患者的应用的临床价值分析

目的:探讨动态监测动脉乳酸水平对危重患者的应用的临床价值分析。方法:对2010年2月~2011年6月间收治的危重病患者的血乳酸水平进行动态监测,通过比较死亡组患者和存活组患者乳酸水平及其它临床指标,比较不同乳酸水平组患者的临床资料来分析乳酸在危重症患者的应用价值。结果:死亡组和存活组患者在性别、年龄差异无明显的统计学意义(P>0.05);病死组乳酸水平、APACHEⅡ评分、住ICU时间(天)、机械通气时间明显高于生存组,差异有显著的统计学意义(P<0.01);严重乳酸酸中毒组患者在APACHEⅡ评分、休克发生率、MODS发生率、死亡发生率均明显高于乳酸酸中毒组和高乳酸血症组,差异有明显的统计学意义(P<0.05),乳酸酸中毒组休克发生率、MODS发生率、死亡发生率均明显高于高乳酸血症组,差异有明显的统计学意义(P<0.05)。结论:动态监测动脉乳酸水平是判断危重患者预后的一个良好指标,动脉乳酸越高,预后差。     

Effects of the ionophores monensin and tetronasin on simulated development of ruminal lactic acidosis in vitro

A continuous coculture of four ruminal bacteria, Megasphaera elsdenii, Selenomonas ruminantium, Streptococcus bovis, and Lactobacillus sp. strain LB17, was used to study the effects of the ionophores monensin and tetronasin on the changes in ruminal microbial ecology that occur during the onset of lactic acidosis. In control incubations, the system simulated the development of lactic acidosis in vivo, with an initial overgrowth of S. bovis when an excess of glucose was added to the fermentor. Lactobacillus sp. strain LB17 subsequently became dominant as pH fell and lactate concentration rose. Both ionophores were able to prevent the accumulation of lactic acid and maintain a healthy non-lactate-producing bacterial population when added at the same time as an excess of glucose. Tetronasin was more potent in this respect than monensin. When tetronasin was added to the culture 24 h after glucose, the proliferation of lactobacilli was reversed and a non-lactate-producing bacterial population developed, with an associated drop in lactate concentration in the fermentor. Rises in culture pH and volatile fatty acid concentrations accompanied these changes. Monensin was unable to suppress the growth of lactobacilli; therefore, in contrast to tetronasin, monensin added 24 h after the addition of glucose failed to reverse the acidosis. Numbers of lactobacilli and lactate concentrations remained high, whereas pH and volatile fatty acid concentrations were low.