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Lactic acidosis
Lactic acidosis
Lactic acidosis
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Lactic acid
L-(+)-lactic acid
SpecialtyEndocrinology Edit this on Wikidata

Lactic acidosis refers to the process leading to the production of lactate by anaerobic metabolism. It increases hydrogen ion concentration tending to the state of acidemia or low pH. The result can be detected with high levels of lactate and low levels of bicarbonate. This is usually considered the result of illness but also results from strenuous exercise. The effect on pH is moderated by the presence of respiratory compensation.

Lactic acidosis is usually the result of tissue hypoxia which is not the same as arterial hypoxia. Adequate circulation of blood and perfusion of metabolizing tissue to meet demand is necessary to prevent tissue hypoxia. Lactic acidosis can also be the result of illnesses, medications, poisonings or inborn errors of metabolism that interfere directly with oxygen utilization by cells.[1]

The symptoms are generally attributable to the underlying cause, but may include nausea, vomiting, shortness of breath, and generalised weakness.

The diagnosis is made on biochemical analysis of blood (often initially on arterial blood gas samples), and once confirmed, generally prompts an investigation to establish the underlying cause to treat the acidosis. In some situations, hemofiltration (purification of the blood) is temporarily required. In rare chronic forms of lactic acidosis caused by mitochondrial disease, a specific diet or dichloroacetate may be used. The prognosis of lactic acidosis depends largely on the underlying cause; in some situations (such as severe infections), it indicates an increased risk of death.

Classification

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The CohenWoods classification categorizes causes of lactic acidosis as:[2]

  • Type A: Decreased tissue oxygenation (e.g., from decreased blood flow)
  • Type B

Signs and symptoms

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Lactic acidosis is commonly found in people who are unwell, such as those with severe heart and/or lung disease, a severe infection with sepsis, the systemic inflammatory response syndrome due to another cause, severe physical trauma, or severe depletion of body fluids.[3] Symptoms in humans include all those of typical metabolic acidosis (nausea, vomiting, generalized muscle weakness, and laboured and deep breathing).[4]

Causes

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The several different causes of lactic acidosis include:[citation needed]

Pathophysiology

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Glucose metabolism begins with glycolysis, in which the molecule is broken down into pyruvate in ten enzymatic steps. A significant proportion of pyruvate is converted into lactate (the blood lactate-to-pyruvate ratio is normally 10:1). The human metabolism produces about 20 mmol/kg of lactic acid every 24 hours. This happens predominantly in tissues (especially muscle) that have high levels of the "A" isoform of the enzyme lactate dehydrogenase (LDHA), which predominantly converts pyruvate into lactate. The lactate is carried by the bloodstream to other tissues where it is converted back to pyruvate by the "B" isoform of LDH (LDHB). Firstly there is gluconeogenesis in the liver (as well as the kidney and some other tissues), where lactate is converted into pyruvate and then into glucose; this is known as the Cori cycle. In addition, pyruvate generated from lactate can be oxidized to acetyl-CoA, which can enter the citric acid cycle to enable ATP production by oxidative phosphorylation.[3]

Elevations in lactate are either a consequence of increased production or of decreased metabolism. With regards to metabolism, this predominantly takes place in the liver (70%), which explains that lactate levels may be elevated in the setting of liver disease.[3]

In "type A" lactic acidosis, the production of lactate is attributable to insufficient oxygen for aerobic metabolism. If there is no oxygen available for the parts of the glucose metabolism that require oxygen (citric acid cycle and oxidative phosphorylation), excess pyruvate will be converted in excess lactate. In "type B" lactic acidosis the lactate accumulates because there is a mismatch between glycolysis activity and the remainder of glucose metabolism. Examples are situations where the sympathetic nervous system is highly active (e.g. severe asthma).[3] There is controversy as to whether elevated lactate in acute illness can be attributed to tissue hypoxia; there is limited empirical support for this theoretical notion.[15]

Diagnosis

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Acid-base disturbances such as lactic acidosis are typically first assessed using arterial blood gas tests. Testing of venous blood is also available as an alternative as they are effectively interchangeable.[3] Normally resulting lactate concentrations are in the range indicated below:[16]

mg/dL mM
Venous blood 4.5–19.8 0.5–2.2
Arterial blood 4.5–14.4 0.5–1.6

Lactic acidosis is classically defined as an elevated lactate together with pH < 7.35 and bicarbonate below 20 mmol/L, but this is not required as lactic acidosis may exist together with other acid-base abnormalities that may affect these two parameters.[3]

Treatment

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If elevated lactate is present in acute illness, supporting the oxygen supply and blood flow are key initial steps.[3] Some vasopressors (drugs that augment the blood pressure) are less effective when lactate levels are high, and some agents that stimulate the beta-2 adrenergic receptor can elevate the lactate further.[3]

Direct removal of lactate from the body (e.g. with hemofiltration or dialysis) is difficult, with limited evidence for benefit; it may not be possible to keep up with the lactate production.[3]

Limited evidence supports the use of sodium bicarbonate solutions to improve the pH (which is associated with increased carbon dioxide generation and may reduce the calcium levels).[3][17]

Lactic acidosis caused by inherited mitochondrial disorders (type B3) may be treated with a ketogenic diet and possibly with dichloroacetate (DCA),[18] although this may be complicated by peripheral neuropathy and has a weak evidence base.[19]

Prognosis

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Mild and transient elevations in lactate have limited impact on mortality, whereas sustained and severe lactate elevations are associated with a high mortality.[3]

The mortality of lactic acidosis in people taking metformin was previously reported to be 50%, but in more recent reports this was closer to 25%.[20]

Other animals

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Reptiles

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Reptiles, which rely primarily on anaerobic energy metabolism (glycolysis) for intense movements, can be particularly susceptible to lactic acidosis. In particular, during the capture of large crocodiles, the animals' use of their glycolytic muscles often alters the blood's pH to a point where they are unable to respond to stimuli or move.[21] Cases are recorded in which particularly large crocodiles which put up extreme resistance to capture later died of the resulting pH imbalance.[22]

Certain turtle species have been found to be capable of tolerating high levels of lactic acid without experiencing the effects of lactic acidosis. Painted turtles hibernate buried in mud or underwater and do not resurface for the entire winter. As a result, they rely on lactic acid fermentation to provide the majority of their energy needs.[23] Adaptations in particular in the turtle's blood composition and shell allow it to tolerate high levels of lactic acid accumulation. In the anoxic conditions where fermentation is dominant, calcium levels in the blood plasma increase.[23] This calcium serves as a buffer, reacting with the excess lactate to form the precipitate calcium lactate. This precipitate is suggested to be reabsorbed by the shell and skeleton, thereby removing it from the bloodstream; studies examining turtles that have been subjected to prolonged anoxic conditions have up to 45% of their lactate stored within their skeletal structure.[23]

Ruminants

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In ruminant livestock, the cause of clinically serious lactic acidosis is different from the causes described above.

In domesticated ruminants, lactic acidosis may occur as a consequence of ingesting large amounts of grain, especially when the rumen population is poorly adapted to deal with grain.[24][25][26] Activity of various rumen organisms results in accumulation of various volatile fatty acids (normally, mostly acetic, propionic, and butyric acids), which are partially dissociated.[27] Although some lactate is normally produced in the rumen, it is normally metabolized by such organisms as Megasphaera elsdenii and, to a lesser extent, Selenomonas ruminantium and some other organisms. With high grain consumption, the concentration of dissociated organic acids can become quite high, resulting in rumen pH dropping below 6. Within this lower pH range, Lactobacillus spp. (producing lactate and hydrogen ions) are favored, and M. elsdenii and S. ruminantium are inhibited, tending to result in a considerable rise of lactate and hydrogen ion concentrations in the rumen fluid.[28] The pKa of lactic acid is low, about 3.9, versus, for example, 4.8 for acetic acid; this contributes to the considerable drop in rumen pH which can occur.[27]

Because of the high solute concentration of the rumen fluid under such conditions, considerable water is translocated from the blood to the rumen along the osmotic potential gradient, resulting in dehydration which cannot be relieved by drinking, and which can ultimately lead to hypovolemic shock.[24] As more lactate accumulates and rumen pH drops, the ruminal concentration of undissociated lactic acid increases. Undissociated lactic acid can cross the rumen wall to the blood,[29] where it dissociates, lowering blood pH. Both L and D isomers of lactic acid are produced in the rumen;[24] these isomers are metabolized by different metabolic pathways, and activity of the principal enzyme involved in metabolism of the D isomer declines greatly with lower pH, tending to result in an increased ratio of D:L isomers as acidosis progresses.[28]

Measures for preventing lactic acidosis in ruminants include avoidance of excessive amounts of grain in the diet, and gradual introduction of grain over a period of several days, to develop a rumen population capable of safely dealing with a relatively high grain intake.[24][25][26] Administration of lasalocid or monensin in feed can reduce risk of lactic acidosis in ruminants,[30] inhibiting most of the lactate-producing bacterial species without inhibiting the major lactate fermenters.[31] Also, using a higher feeding frequency to provide the daily grain ration can allow higher grain intake without reducing the pH of the rumen fluid.[32]

Treatment of lactic acidosis in ruminants may involve intravenous administration of dilute sodium bicarbonate, oral administration of magnesium hydroxide, and/or repeated removal of rumen fluids and replacement with water (followed by reinoculation with rumen organisms, if necessary).[24][25][26]

References

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Lactic acidosis

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from Grokipedia
Lactic acidosis is a serious medical condition characterized by the excessive accumulation of in the bloodstream, leading to a decrease in blood and . It is typically defined as a serum lactate concentration exceeding 4 mmol/L, often accompanied by an below 7.35 and a plasma level less than 20 mmol/L. This buildup occurs when the body's tissues produce more lactate than can be cleared, primarily due to impaired oxygen delivery or utilization, and it is a common complication in critically ill patients. Lactic acidosis is classified into two main types based on underlying mechanisms. Type A lactic acidosis results from tissue hypoxia or hypoperfusion, such as in cases of , , severe , or , where inadequate oxygen supply leads to anaerobic and lactate production. In contrast, Type B lactic acidosis occurs without evident hypoxia and is associated with conditions like liver or , malignancies, or medications such as metformin and nucleoside reverse transcriptase inhibitors used in treatment. Additional causes include intense exercise, convulsions, or , though these are often transient. Clinically, lactic acidosis presents with symptoms that vary depending on the severity and underlying cause, including , , , rapid or deep breathing (Kussmaul respirations), weakness, fatigue, and altered mental status. In severe cases, patients may exhibit , , , or , with mortality rates increasing significantly when pH falls below 7.2 or lactate exceeds 7 mmol/L. Diagnosis involves measuring serum lactate levels via arterial or venous blood gas analysis, alongside calculation of the (typically >12 mEq/L, adjusted for ), to confirm the presence of and rule out other causes. Management focuses on identifying and treating the underlying , such as administering fluids and vasopressors for shock or discontinuing offending medications. Supportive measures include , if occurs, and in refractory cases, to remove lactate and correct acid-base imbalances. therapy is used cautiously and only in extreme (pH <7.1-7.2) due to potential risks like intracellular acidosis. Early recognition and intervention in an intensive care setting are crucial, as lactic acidosis signals high morbidity and mortality in acute settings.

Definition and Classification

Definition

Lactic acidosis is a metabolic disorder characterized by the accumulation of lactate in the bloodstream, leading to a decrease in blood pH and bicarbonate levels. It is typically defined as a serum lactate concentration exceeding 4 mmol/L, accompanied by an arterial pH below 7.35 and a serum bicarbonate level below 20 mEq/L. This condition reflects an imbalance between lactate production and clearance, often resulting from impaired tissue oxygenation or metabolic dysfunction. The concept of lactate buildup during anaerobic metabolism, which underlies lactic acidosis, emerged from early 20th-century biochemical research, including the 1929 description of the by Carl Ferdinand Cori and Gerty Theresa Cori, who demonstrated how lactate produced in muscles is transported to the liver for reconversion to glucose, preventing excessive accumulation under hypoxic conditions. Lactic acidosis is distinguished from , which stems from carbon dioxide retention and elevated partial pressure of arterial carbon dioxide (PaCO₂), by its metabolic origin involving a high anion gap without primary ventilatory impairment. It also differs from other metabolic acidoses, such as , where the elevated anion gap arises from ketone bodies rather than lactate. In the general population, the incidence of lactic acidosis remains low, estimated at 0.5% to 3.8% among hospitalized patients with internal diseases. However, it is far more prevalent in critically ill individuals, with hyperlactatemia (lactate ≥5 mmol/L) observed in about 13.6% of intensive care unit (ICU) admissions overall, rising to over 50% in cases of severe sepsis or septic shock, where it serves as a marker of disease severity and is associated with substantially increased mortality risk.

Types

Lactic acidosis is traditionally classified into Type A and Type B based on the underlying pathophysiology related to tissue oxygenation, a system proposed by Cohen and Woods in their seminal 1976 monograph. Type A lactic acidosis is characterized by the presence of clinical evidence of tissue hypoperfusion or hypoxia, leading to increased lactate production due to anaerobic metabolism; common examples include shock states and cardiac arrest, which account for the majority of cases encountered in intensive care settings. In contrast, Type B lactic acidosis occurs in the absence of overt hypoxia or hypoperfusion and is further subdivided into three subtypes: B1, associated with underlying systemic diseases such as malignancy or liver failure; B2, linked to drugs or toxins including metformin, ethanol, and salicylates; and B3, resulting from inborn errors of metabolism like mitochondrial disorders. D-lactic acidosis is a distinct variant primarily arising in short bowel syndrome where bacterial fermentation produces D-lactate and is generally associated with Type B mechanisms. A 2020 study highlighted hyperlactatemia without metabolic acidosis as a separate prognostic entity in critically ill individuals, associated with increased mortality independent of acid-base status.

Clinical Features

Signs and Symptoms

Lactic acidosis presents with a spectrum of clinical manifestations that vary based on severity and underlying conditions, often reflecting tissue hypoperfusion and metabolic derangement. In mild cases, symptoms may be subtle or absent, while progression to severe acidosis leads to multisystem involvement. Early symptoms commonly include nausea, vomiting, abdominal pain, fatigue, and myalgias, which can precede more overt signs and are frequently observed in conditions like metformin-associated lactic acidosis. These gastrointestinal and musculoskeletal complaints arise as nonspecific indicators of metabolic stress. As the condition advances, cardiorespiratory signs emerge, such as tachypnea with (deep, rapid respirations as a compensatory response to acidosis), tachycardia, and hypotension, particularly in cases of significant hypoperfusion. Neurological effects typically manifest as confusion and lethargy, progressing to coma in severe cases with pH below 7.2, reflecting the impact of acidemia on cerebral function. Physical examination often reveals cool extremities due to peripheral vasoconstriction, hyperventilation, and signs of organ dysfunction such as acute kidney injury evidenced by oliguria. These findings underscore the systemic nature of advanced lactic acidosis. Mild hyperlactatemia, with lactate levels below 5 mmol/L, is often asymptomatic and discovered incidentally during routine evaluations, without accompanying acidosis or clinical features. In contrast, symptomatic cases exceeding this threshold correlate with the progression described above and may be confirmed through blood tests showing elevated lactate and reduced pH.

Causes

Lactic acidosis is broadly classified into Type A, associated with clinical evidence of tissue hypoperfusion or hypoxia, and Type B, occurring in the absence of such evidence. Type A lactic acidosis arises from conditions that impair oxygen delivery to tissues. Common causes include circulatory failure, such as cardiogenic or septic shock and severe hemorrhage leading to hypovolemic shock. Severe anemia, where hemoglobin levels drop below 5 g/dL, reduces oxygen-carrying capacity and contributes to lactate accumulation. Carbon monoxide poisoning binds to hemoglobin, preventing oxygen transport and mimicking hypoxic states. Intense exercise, particularly in untrained individuals or during prolonged high-intensity efforts, can also trigger Type A lactic acidosis due to localized muscle hypoxia. Type B lactic acidosis encompasses a diverse array of etiologies without overt hypoxia. It is further categorized into subtypes based on underlying mechanisms, though these do not involve tissue oxygen deprivation. Type B1 causes involve associated diseases that either increase lactate production or impair its clearance. Malignancies, such as and , often lead to elevated lactate through rapid tumor cell metabolism. Liver cirrhosis and severe hepatic dysfunction hinder lactate metabolism by reducing hepatic clearance capacity. Renal failure, particularly acute kidney injury, limits lactate excretion and metabolism. , often linked to alcohol use, is another contributor through inflammatory processes affecting lactate handling. Type B2 causes include medications, toxins, and nutritional factors. Certain medications, such as metformin especially in the setting of renal impairment, and nucleoside reverse transcriptase inhibitors used in HIV treatment, are well-documented triggers. Toxins like cyanide, which inhibits mitochondrial respiration, and ethylene glycol, metabolized to toxic acids, can induce lactic acidosis. Alcohol intoxication, particularly from ethanol, disrupts lactate metabolism and is a frequent cause. Type B3 causes are rare and stem from inborn errors of metabolism. Genetic disorders such as pyruvate dehydrogenase deficiency impair the conversion of pyruvate to acetyl-CoA, leading to lactate buildup. Glucose-6-phosphatase deficiency (von Gierke disease), which impairs gluconeogenesis and leads to pyruvate accumulation and lactate buildup, is another example. Iatrogenic factors, such as the accumulation of propylene glycol from prolonged intravenous lorazepam infusions or linezolid administration, can result in osmotic effects and lactate elevation.

Pathophysiology

Lactate Metabolism

Lactate is primarily produced through anaerobic glycolysis in various tissues, such as skeletal muscle and erythrocytes, where glucose is metabolized to pyruvate, which is then converted to lactate by the enzyme lactate dehydrogenase (LDH). This process allows for the regeneration of NAD⁺, essential for continued glycolysis under conditions of limited oxygen availability. The formation of lactate is regulated by the NADH/NAD⁺ ratio in the cell, which reflects the redox state and energy demands. LDH catalyzes the reversible reaction: Pyruvate+NADH+H+LDHLactate+NAD+\text{Pyruvate} + \text{NADH} + \text{H}^{+} \xrightarrow{\text{LDH}} \text{Lactate} + \text{NAD}^{+}
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