Acid–base imbalance

Acid–base imbalance
Classification and external resources
Specialty	endocrinology
ICD-10	E87.2-E87.4
ICD-9-CM	276.2-276.4
MeSH	D000137

Blood gas, acid-base, and gas exchange terms
P_aO₂	Arterial oxygen tension, or partial pressure
P_AO₂	Alveolar oxygen tension, or partial pressure
P_aCO₂	Arterial carbon dioxide tension, or partial pressure
P_ACO₂	Alveolar carbon dioxide tension, or partial pressure
P_vO₂	Oxygen tension of mixed venous blood
P_(A-a)O₂	Alveolar-arterial oxygen tension difference. The term formerly used (A-a DO2) is discouraged.
P_(a/A)O₂	Alveolar-arterial tension ratio; P_aO₂:P_AO₂ The term oxygen exchange index describes this ratio.
C_(a-v)O₂	Arteriovenous oxygen content difference
S_aO₂	Oxygen saturation of the hemoglobin of arterial blood
S_pO₂	Oxygen saturation as measured by pulse oximetry
C_aO₂	Oxygen content of arterial blood
_pH	Symbol relating the hydrogen ion concentration or activity of a solution to that of a standard solution; approximately equal to the negative logarithm of the hydrogen ion concentration. pH is an indicator of the relative acidity or alkalinity of a solution

Acid–base imbalance is an abnormality of the human body's normal balance of acids and bases that causes the plasma pH to deviate out of the normal range (7.35 to 7.45). In the fetus, the normal range differs based on which umbilical vessel is sampled (umbilical vein pH is normally 7.25 to 7.45; umbilical artery pH is normally 7.18 to 7.38).^[1] It can exist in varying levels of severity, some life-threatening.

Classification

A Davenport diagram illustrates acid–base imbalance graphically.

An excess of acid is called acidosis or acidaemia and an excess in bases is called alkalosis or alkalemia. The process that causes the imbalance is classified based on the etiology of the disturbance (respiratory or metabolic) and the direction of change in pH (acidosis or alkalosis). This yields the following four basic processes:

process	pH	carbon dioxide	compensation
metabolic acidosis	down	down	respiratory
respiratory acidosis	down	up	renal
metabolic alkalosis	up	up	respiratory
respiratory alkalosis	up	down	renal

Mixed disorders

The presence of only one of the above derangements is called a simple acid–base disorder. In a mixed disorder more than one is occurring at the same time.^[2] Mixed disorders may feature an acidosis and alkosis at the same time that partially counteract each other, or there can be two different conditions affecting the pH in the same direction. The phrase "mixed acidosis", for example, refers to metabolic acidosis in conjunction with respiratory acidosis. Any combination is possible, except concurrent respiratory acidosis and respiratory alkalosis, since a person cannot breathe too fast and too slow at the same time...

Calculation of imbalance

The traditional approach to the study of acid–base physiology has been the empirical approach. The main variants are the base excess approach and the bicarbonate approach. The quantitative approach introduced by Peter A Stewart in 1978^[3] is newer.

Causes

There are numerous reasons that each of the four processes can occur (detailed in each article). Generally speaking, sources of acid gain include:

Retention of carbon dioxide
Production of nonvolatile acids from the metabolism of proteins and other organic molecules
Loss of bicarbonate in feces or urine
Intake of acids or acid precursors

Sources of acid loss include:

Use of hydrogen ions in the metabolism of various organic anions
Loss of acid in the vomitus or urine
Gastric aspiration in hospital
Severe diarrhea
Carbon dioxide loss through hyperventilation

Compensation

Acids and bases
pH Reaction Titration Extraction Dissociation constant (acid) Acid strength Acidity function Buffer solutions Proton affinity Self-ionization of water Amphoterism
Acid types
Brønsted Lewis Mineral Organic Strong Superacids Weak Monobasic acid Dibasic acid Tribasic acid
Base types
Brønsted Lewis Organic Strong Superbases Non-nucleophilic Weak

The body's acid–base balance is tightly regulated. Several buffering agents exist which reversibly bind hydrogen ions and impede any change in pH. Extracellular buffers include bicarbonate and ammonia, while proteins and phosphate act as intracellular buffers. The bicarbonate buffering system is especially key, as carbon dioxide (CO₂) can be shifted through carbonic acid (H₂CO₃) to hydrogen ions and bicarbonate (HCO₃⁻) as shown below.

{\rm {HCO_{3}^{-}+H^{+}\leftrightarrow H_{2}CO_{3}\leftrightarrow CO_{2}+H_{2}O}}

Acid–base imbalances that overcome the buffer system can be compensated in the short term by changing the rate of ventilation. This alters the concentration of carbon dioxide in the blood, shifting the above reaction according to Le Chatelier's principle, which in turn alters the pH. For instance, if the blood pH drops too low (acidemia), the body will compensate by increasing breathing, expelling CO₂, and shifting the reaction above to the right such that fewer hydrogen ions are free – thus the pH will rise back to normal. For alkalemia, the opposite occurs.

The kidneys are slower to compensate, but renal physiology has several powerful mechanisms to control pH by the excretion of excess acid or base. In responses to acidosis, tubular cells reabsorb more bicarbonate from the tubular fluid, collecting duct cells secrete more hydrogen and generate more bicarbonate, and ammoniagenesis leads to increased formation of the NH₃ buffer. In responses to alkalosis, the kidney may excrete more bicarbonate by decreasing hydrogen ion secretion from the tubular epithelial cells, and lowering rates of glutamine metabolism and ammonia excretion.

References

↑ Yeomans, ER; Hauth, JC; Gilstrap, LC III; Strickland DM (1985). "Umbilical cord pH, PCO2, and bicarbonate following uncomplicated term vaginal deliveries (146 infants)". Am J Obstet Gynecol. 151 (6): 798–800. doi:10.1016/0002-9378(85)90523-x. PMID 3919587.
↑ "Mixed Acid Base Disorders: Acid Base Tutorial, University of Connecticut Health Center". Archived from the original on 26 April 2009. Retrieved 2009-05-09.
↑ Stewart P (1978). "Independent and dependent variables of acid-base control". Respir Physiol. 33 (1): 9–26. doi:10.1016/0034-5687(78)90079-8. PMID 27857.

External links

Cardiopulmonary therapy

Diagnostic	Pulmonary function testing Polysomnography

Disease	Asthma Bronchiectasis COPD Cystic fibrosis Tuberculosis Pneumonia

Therapy	Hyperinflation therapy Pulmonary hygiene Mechanical ventilation Oxygen therapy

See also	Health care

Water–electrolyte imbalance and acid–base imbalance (E86–E87, 276)

Volume status

Electrolyte

Sodium	High Hypernatremia Salt poisoning Low Hypotonic Isotonic

Potassium	High Low

Chloride	High Low

Calcium	High Low

Acid–base

Acidosis	Metabolic: High anion gap Ketoacidosis Diabetic ketoacidosis Lactic Normal anion gap Hyperchloremic Renal tubular Respiratory

Alkalosis	Metabolic Contraction alkalosis Respiratory

Both	Mixed disorder of acid-base balance

Physiology of the kidneys and acid-base physiology

Renal function

Secretion	clearance Pharmacokinetics Clearance of medications Urine flow rate

Reabsorption	Solvent drag sodium chloride urea glucose oligopeptides protein

Renal function	Glomerular filtration rate Creatinine clearance Renal clearance ratio Urea reduction ratio Kt/V Standardized Kt/V Measures of dialysis Hemodialysis product PAH clearance (Effective renal plasma flow Extraction ratio)

Filtration	Renal blood flow Ultrafiltration Countercurrent exchange Filtration fraction

Hormones

Acid-base balance

Body water: Intracellular fluid/Cytosol

Buffering

Other

Human homeostasis

Blood composition	Blood sugar Osmoregulation Pressure: Renin–angiotensin system Acid–base Fluid balance Hemostasis

Other	Thermoregulation

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