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In the health sciences, '''metabolic acidosis''' refers to a pathological state of systemic [[acid-base physiology]], a state that manifests as an abnormal chemical composition of the body, a state that, when uncomplicated by masking acid-base pathophysiological conditions, clinicians characterize as abnormally increased [[acidity]] &mdash; measured as decreased [[pH]] or increased [[hydrogen ion]] concentration (the concentration symbolized as [H<sup>+</sup>]) &mdash; accompanied by abnormally decreased [[bicarbonate]] concentration (the concentration symbolized as [HCO<sub>3</sub><sup>−</sup>]) &mdash; the abnormalities of composition judged by comparison with reference values in persons judged in 'normal' health, the abnormalities detectable in the [[extracellular fluid]] (ECF) compartment of the body, usually through measurements on samples taken from the blood compartment, the clinicians acknowledging that, with few notable exceptions, a similar paired pH and [HCO<sub>3</sub><sup>−</sup>] compositional abnormality exists in the [[intracellular fluid]] (ICF) compartment as well.
::''See also'': [[Acidosis]]
::''See also'': [[Acidosis]]
{{TOC|right}}
Metabolic acidosis refers to any one of numerous pathological conditions affecting systemic acid-base physiology, conditions that manifest as an abnormal chemical compositional state of the body, a state that, when uncomplicated by masking acid-base pathophysiological conditions, clinicians characterize as abnormally increased [[acidity]] &mdash; measured as decreased [[pH]] or increased [[hydrogen ion]] concentration (the concentration symbolized as [H<sup>+</sup>]) &mdash; accompanied by abnormally decreased [[bicarbonate]] concentration (the concentration symbolized as [HCO<sub>3</sub><sup>–</sup>]) &mdash; the abnormalities of composition judged by comparison with references values in persons judged in 'normal' health, the abnormalities detectable in the [[extracellular fluid]] (ECF) compartment of the body, usually through measurements on samples taken from the blood compartment, the clinicians acknowledging that, with few notable exceptions, a similar paired pH and [HCO<sub>3</sub><sup>–</sup>] compositional abnormality exists in the intracellular compartment (ICF) as well.


The pathological conditions that cause metabolic acidosis categorize as follows:
The pathological conditions that cause metabolic acidosis categorize as follows:


*habitual consumption of a diet who metabolism by the body yields a net load of non-carbonic acids as end-products;
*habitual consumption of a diet who metabolism by the body yields a net load of non-carbonic acids as end-products (e.g., a [[ketogenic diet]] used in the treatment of certain types of [[epilepsy]] ;
*conditions that cause the body's metabolic processes to produce abnormally increased amounts of non-carbonic acids (e.g., lactic acid, beta-hydroxybutyric acid);
*conditions that cause the body's metabolic processes to produce abnormally increased amounts of non-carbonic acids (e.g., [[β-hydroxybutyric acid]] in [[diabetic ketoacidosis]]);
*conditions that cause the body to waste bicarbonate through the urine or feces;
*diseases of the kidneys that abnormally decrease generation, and delivery to the systemic circulation, of bicarbonate, in amounts over and above that filtered from, and reabsorbed back into, the circulation, amounts sufficient to neutralize the non-carbonic acids produced by habitual consumption of a diet whose metabolism by the body yields a net load of non-carbonic acids as end-products (e.g., certain disorders of the renal tubules);
*diseases of the kidneys that abnormally decrease their generation, and delivery to the systemic circulation, of bicarbonate, in amounts over and above that filtered from, and reabsorbed back into, the circulation, amounts sufficient to neutralize the non-carbonic acids produced by habitual consumption of a diet whose metabolism by the body yields a net load of non-carbonic acids as end-products;
*conditions that cause the body to abnormally increased amounts of bicarbonate through the feces (e.g., diseases causing diarrhea);
<!--
<blockquote>
<p style="margin-left: 2.0%; margin-right: 6%; font-size: 1.0em; font-family: Gill Sans MT, Trebuchet MS;">Metabolic acidosis occurs as a result of a marked increase in endogenous production of acid (such as L-lactic acid
and keto acids), loss of HCO3− or potential HCO3− salts (diarrhea or renal tubular acidosis [RTA]), or progressive
accumulation of endogenous acids, when excretion is impaired because of renal insufficiency.[''cites'':<ref name=krapf3rd>Krapf R, Alpern RJ, Seldin DW. Clinical syndromes of metabolic acidosis. In: Seldin DW, Giebisch G, ed. The Kidney,  3rd ed. Philadelphia: Lippincott Williams and Wilkins; 2000:2055-2072.</ref>]<ref name=dubosedoabb>DuBose TD Jr. (2008) ''Disorders of Acid-Base Balance''. In: Brenner BM (editor) ''Brenner and Rector's The Kidney''. 8th ed. Volume I, Chapter 14. Elsevier Saunders: Philadelphia.  ISBN 978-1-4160-3105-5.</ref></p>
</blockquote> -->


==Overview==
==Overview==
Clinicians distinguish between metabolic acidosis and [[respiratory acidosis]]. In the latter, the [[acid]], [[carbonic acid]], or H<sub>2</sub>CO<sub>3</sub>, deriving from the hydration reaction with the metabolic waste product, [[carbon dioxide]] (CO<sub>2</sub>),
Clinicians distinguish between metabolic acidosis and [[respiratory acidosis]]. In the latter, the [[acid]], [[carbonic acid]], or H<sub>2</sub>CO<sub>3</sub>, deriving from the hydration reaction with the metabolic waste product, [[carbon dioxide]] (CO<sub>2</sub>),
::CO<sub>2</sub> + H<sub>2</sub>0 = H<sub>2</sub>CO<sub>3</sub> = H<sup>+</sup> + HCO<sub>3</sub><sup>–</sup>
::CO<sub>2</sub> + H<sub>2</sub>0 = H<sub>2</sub>CO<sub>3</sub> = H<sup>+</sup> + HCO<sub>3</sub><sup>–</sup>
tends to accumulate in body fluids due to insufficient rates of excretion of carbon dioxide (exhalation by the [[lung]]s) relative to the rates of carbon dioxide production by cellular [[metabolism]]. Abnormally increased acidity results from dissociation of carbonic acid, which occurs rapidly spontaneously, yielding hydrogen ions, the bicarbonate concentration also ''increasing'' to abnormally increased levels, inasmuch as the dissociation of carbonic acid also yields bicarbonate.   
tends to accumulate in body fluids when the rates of excretion of carbon dioxide (exhalation by the [[lung]]s) falls below the rates of carbon dioxide production by cellular [[metabolism]]. Abnormally increased acidity results from dissociation of carbonic acid, which occurs rapidly spontaneously, yielding hydrogen ions, the bicarbonate concentration also ''increasing'' to abnormally increased levels, inasmuch as the dissociation of carbonic acid also yields bicarbonate.  Under ordinary physiological conditions, metabolism produces on the order of 15,000 mmol carbon dioxide per day, which in the healthy steady-state the lungs exhale.


Thus, abnormally increased acidity characterizes both metabolic acidosis and respiratory acidosis, but an abnormally reduced bicarbonate concentration characterizes only metabolic acidosis.  Some clinicians define metabolic acidosis in terms of a primary decrease in blood plasma or serum bicarbonate concentration [HCO<sub>3</sub><sup>–</sup>&nbsp;]<sub>p</sub>.
Abnormally increased acidity characterizes both metabolic acidosis and respiratory acidosis, but an accompanying abnormally reduced bicarbonate concentration characterizes only metabolic acidosis.  Some clinicians define metabolic acidosis in terms of a primary decrease in blood plasma or serum bicarbonate concentration [HCO<sub>3</sub><sup>–</sup>&nbsp;]<sub>p</sub>.


Metabolic acidosis involves only non-carbonic acids, of which numerous such acids can underlie the compositional abnormality characteristic of metabolic acidosis.
Metabolic acidosis involves only non-carbonic acids, of which numerous such acids can underlie the compositional abnormality characteristic of metabolic acidosis.  In healthy adult humans consuming typical American diets, net production of non-carbonic acids ranges between 20 and 120 mmol per day, matched by kidney excretion of an equal amount of net acid per day.


Common examples of metabolic acidosis include:
Common examples of metabolic acidosis include:
* Diabetic [[ketoacidosis]], caused by abnormally high rates of liver production of [[ketoacid]]s, ultimately due to severe [[insulin]] deficiency;
* Diabetic [[ketoacidosis]], caused by abnormally high rates of liver production of [[ketoacid]]s, ultimately due to severe [[insulin]] deficiency;
* [[Lactic acidosis]], caused by abnormally high rates of lactic acid production, often due to reduced oxygen delivery to body tissues; prolonged exercise; liver failure;
* [[Lactic acidosis]], caused by abnormally high rates of hydrogen ion and lactate anion production, often due to reduced oxygen delivery to body tissues; prolonged exercise; liver failure;<ref name=robergs2004/>
* [[Renal acidosis]], caused by diseased [[kidney]]s that fail to deliver sufficient renally-generated bicarbonate to the body in the circumstances of bicarbonate losses due to:
* [[Renal acidosis]], caused by diseased [[kidney]]s that fail to deliver sufficient renally-generated bicarbonate to the body in the circumstances of bicarbonate losses due to:
** titration of bicarbonate by non-carbonic acids produced during metabolism foods from diets that consist of more acid-producing than base-producing foods;
** titration of bicarbonate by non-carbonic acids produced during metabolism foods from diets that consist of more acid-producing than base-producing foods;
** down-setting of the plasma bicarbonate concentration threshold at which the kidneys return to the body all the bicarbonate filtered by the kidneys from the blood.
** down-setting of the plasma bicarbonate concentration threshold at which the kidneys return to the body all the bicarbonate filtered by the kidneys from the blood;
** defects of renal tubules impairing hydrogen ion secretion into the tubule lumens.


==Acid-Base homeostasis==
==Acid-Base homeostasis==
Homeostatic mechanisms regulating the acid-base status of the ECF and ICF appear to target the concentration of the positively charged hydrogen ion [H<sup>+</sup>], a proton, the concentration often expressed in terms of the common acidity index, pH.<ref name=bevensee2008>Bevensee MO, Boron WF. (2008) Control of Intracellular pH. Volume 2. Chater 51. Page 1429. In: Alpern RJ, Hebert SC, Seldin DW, Giebisch GH. (editors) (2008) Seldin and Giebisch's The Kidney: Physiology & Pathophysiology. 2 volumes. Elsevier Inc., Academic Press: Amsterdam. ISBN 9780120884896. 2871 pages</ref>  That homeostatic target makes sense from a biological chemistry perspective for the following reasons: Hydrogen ions, protons, in aqueous solution bind to water molecules, molecules of H<sub>2</sub>O, forming so-called hydronium ions, H<sub>3</sub>O<sup>+</sup>.  By hopping from one water molecule to an adjacent one, kicking a proton off the adjacent molecule, which repeats the hop, which kicks another proton on &mdash; a kind of concerted transport through water, similar to the way electrons conduct along a copper wire &mdash; protons  diffuse along their concentration gradients through the solution very rapidly. In their attachment to the tiny water molecule &mdash; tiny by comparison to the numerous macromolecules (proteins, nucleic acids, lipids) present in body fluids &mdash; they jiggle and swirl vigorously, driven by the thermal (heat) energy of the body fluids.  Accordingly, they frequently encounter a macromolecule, their small size giving them access to the interstices of the macromolecule as well as their outer surfaces, and their charged status giving them the ability to disrupt the charges on the macromolecules, charges that importantly help maintain the convoluted structure of the macromolecule critical for its normal biological/biochemical function.  Small changes in pH can exert large or small functional disruptions of proteins, leading to acute serious biological disturbances in such activities as enzyme catalysis, cell signaling, gene regulation, and many others, very many more in the ICF than in the ECF.<ref name=bevensee2008/>
Homeostatic mechanisms regulating the acid-base status of the ECF and ICF appear to target the concentration of the positively charged hydrogen ion [H<sup>+</sup>], a proton, the concentration often expressed in terms of the common acidity index, pH.<ref name=bevensee2008/>  That homeostatic target makes sense from a biological chemistry perspective for the following reasons: Hydrogen ions, protons, in aqueous solution bind weakly to water molecules, molecules of H<sub>2</sub>O, forming so-called hydronium ions, H<sub>3</sub>O<sup>+</sup>. Through thermal agitation, the protons diffuse along their concentration gradients through the solution very rapidly by hopping from one water molecule to an adjacent one, in the process electrically kicking a proton off the adjacent molecule, which repeats the hop, which kicks another proton on &mdash; a kind of concerted transport through water, similar to the way electrons conduct along a copper wire.
 
In their attachment to the tiny water molecule &mdash; tiny by comparison to the numerous macromolecules (proteins, nucleic acids, lipids) present in body fluids &mdash; they jiggle and swirl vigorously, driven by the thermal (heat) energy of the body fluids.  Accordingly, they frequently encounter a macromolecule, their small size giving them access to the interstices of the macromolecule as well as their outer surfaces, and their charged status giving them the ability to interact with the charges on the macromolecules, charges that importantly help maintain the convoluted structure of the macromolecule critical for its normal biological/biochemical function.  Small changes in pH can exert large or small functional disruptions of proteins, potentially leading to acute serious biological disturbances in such activities as enzyme catalysis, cell signaling, gene regulation, and many others, very many more in the ICF than in the ECF.<ref name=bevensee2008/>
 
 
==References==


==References and notes cited in text as superscripts==
{{reflist3 test|refs=
 
<ref name=bevensee2008>Bevensee MO, Boron WF. (2008) Control of Intracellular pH. Volume 2. Chapter 51. Page 1429. In: Alpern RJ, Hebert SC, Seldin DW, Giebisch GH. (editors) (2008) ''Seldin and Giebisch's The Kidney: Physiology & Pathophysiology''. 2 volumes. Elsevier Inc., Academic Press: Amsterdam. ISBN 9780120884896. 2871 pages</ref>
 
<ref name=robergs2004>Robergs RA, Ghiasvand F, Parker D. (2004)[http://dx.doi.org/10.1152/ajpregu.00114.2004 Biochemistry of exercise-induced metabolic acidosis]. ''Am J Physiol Regul Integr Comp Physiol'' 287:R502-R516.</ref>
 
}}
<!--==References and notes cited in text as superscripts==-->
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<references />
<br><hr>[[Category:Suggestion Bot Tag]]

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In the health sciences, metabolic acidosis refers to a pathological state of systemic acid-base physiology, a state that manifests as an abnormal chemical composition of the body, a state that, when uncomplicated by masking acid-base pathophysiological conditions, clinicians characterize as abnormally increased acidity — measured as decreased pH or increased hydrogen ion concentration (the concentration symbolized as [H+]) — accompanied by abnormally decreased bicarbonate concentration (the concentration symbolized as [HCO3]) — the abnormalities of composition judged by comparison with reference values in persons judged in 'normal' health, the abnormalities detectable in the extracellular fluid (ECF) compartment of the body, usually through measurements on samples taken from the blood compartment, the clinicians acknowledging that, with few notable exceptions, a similar paired pH and [HCO3] compositional abnormality exists in the intracellular fluid (ICF) compartment as well.

See also: Acidosis

The pathological conditions that cause metabolic acidosis categorize as follows:

  • habitual consumption of a diet who metabolism by the body yields a net load of non-carbonic acids as end-products (e.g., a ketogenic diet used in the treatment of certain types of epilepsy ;
  • conditions that cause the body's metabolic processes to produce abnormally increased amounts of non-carbonic acids (e.g., β-hydroxybutyric acid in diabetic ketoacidosis);
  • diseases of the kidneys that abnormally decrease generation, and delivery to the systemic circulation, of bicarbonate, in amounts over and above that filtered from, and reabsorbed back into, the circulation, amounts sufficient to neutralize the non-carbonic acids produced by habitual consumption of a diet whose metabolism by the body yields a net load of non-carbonic acids as end-products (e.g., certain disorders of the renal tubules);
  • conditions that cause the body to abnormally increased amounts of bicarbonate through the feces (e.g., diseases causing diarrhea);

Overview

Clinicians distinguish between metabolic acidosis and respiratory acidosis. In the latter, the acid, carbonic acid, or H2CO3, deriving from the hydration reaction with the metabolic waste product, carbon dioxide (CO2),

CO2 + H20 = H2CO3 = H+ + HCO3

tends to accumulate in body fluids when the rates of excretion of carbon dioxide (exhalation by the lungs) falls below the rates of carbon dioxide production by cellular metabolism. Abnormally increased acidity results from dissociation of carbonic acid, which occurs rapidly spontaneously, yielding hydrogen ions, the bicarbonate concentration also increasing to abnormally increased levels, inasmuch as the dissociation of carbonic acid also yields bicarbonate. Under ordinary physiological conditions, metabolism produces on the order of 15,000 mmol carbon dioxide per day, which in the healthy steady-state the lungs exhale.

Abnormally increased acidity characterizes both metabolic acidosis and respiratory acidosis, but an accompanying abnormally reduced bicarbonate concentration characterizes only metabolic acidosis. Some clinicians define metabolic acidosis in terms of a primary decrease in blood plasma or serum bicarbonate concentration [HCO3 ]p.

Metabolic acidosis involves only non-carbonic acids, of which numerous such acids can underlie the compositional abnormality characteristic of metabolic acidosis. In healthy adult humans consuming typical American diets, net production of non-carbonic acids ranges between 20 and 120 mmol per day, matched by kidney excretion of an equal amount of net acid per day.

Common examples of metabolic acidosis include:

  • Diabetic ketoacidosis, caused by abnormally high rates of liver production of ketoacids, ultimately due to severe insulin deficiency;
  • Lactic acidosis, caused by abnormally high rates of hydrogen ion and lactate anion production, often due to reduced oxygen delivery to body tissues; prolonged exercise; liver failure;[1]
  • Renal acidosis, caused by diseased kidneys that fail to deliver sufficient renally-generated bicarbonate to the body in the circumstances of bicarbonate losses due to:
    • titration of bicarbonate by non-carbonic acids produced during metabolism foods from diets that consist of more acid-producing than base-producing foods;
    • down-setting of the plasma bicarbonate concentration threshold at which the kidneys return to the body all the bicarbonate filtered by the kidneys from the blood;
    • defects of renal tubules impairing hydrogen ion secretion into the tubule lumens.

Acid-Base homeostasis

Homeostatic mechanisms regulating the acid-base status of the ECF and ICF appear to target the concentration of the positively charged hydrogen ion [H+], a proton, the concentration often expressed in terms of the common acidity index, pH.[2] That homeostatic target makes sense from a biological chemistry perspective for the following reasons: Hydrogen ions, protons, in aqueous solution bind weakly to water molecules, molecules of H2O, forming so-called hydronium ions, H3O+. Through thermal agitation, the protons diffuse along their concentration gradients through the solution very rapidly by hopping from one water molecule to an adjacent one, in the process electrically kicking a proton off the adjacent molecule, which repeats the hop, which kicks another proton on — a kind of concerted transport through water, similar to the way electrons conduct along a copper wire.

In their attachment to the tiny water molecule — tiny by comparison to the numerous macromolecules (proteins, nucleic acids, lipids) present in body fluids — they jiggle and swirl vigorously, driven by the thermal (heat) energy of the body fluids. Accordingly, they frequently encounter a macromolecule, their small size giving them access to the interstices of the macromolecule as well as their outer surfaces, and their charged status giving them the ability to interact with the charges on the macromolecules, charges that importantly help maintain the convoluted structure of the macromolecule critical for its normal biological/biochemical function. Small changes in pH can exert large or small functional disruptions of proteins, potentially leading to acute serious biological disturbances in such activities as enzyme catalysis, cell signaling, gene regulation, and many others, very many more in the ICF than in the ECF.[2]


References

  1. Robergs RA, Ghiasvand F, Parker D. (2004)Biochemistry of exercise-induced metabolic acidosis. Am J Physiol Regul Integr Comp Physiol 287:R502-R516.
  2. 2.0 2.1 Bevensee MO, Boron WF. (2008) Control of Intracellular pH. Volume 2. Chapter 51. Page 1429. In: Alpern RJ, Hebert SC, Seldin DW, Giebisch GH. (editors) (2008) Seldin and Giebisch's The Kidney: Physiology & Pathophysiology. 2 volumes. Elsevier Inc., Academic Press: Amsterdam. ISBN 9780120884896. 2871 pages