Acid-base imbalance

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	Acid-base Imbalance
Home
Overview
Approach to acid–base imbalance
Blood Gas Analysis
Compensation
Mixed Acid−Base Disorders
Related Chapters

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: Sadaf Sharfaei M.D.[2], Priyamvada Singh, M.D. [3]

Overview

Acid-base imbalance has several possible causes. An excess of acid is called acidosis and an excess in bases is called alkalosis. Acidosis is much more common than alkalosis. The imbalance is compensated by negative feedback to restore normal values. Acid-base balance is maintained by normal respiratory and renal excretions of carbon dioxide and acids respectively.

Definition

Acidosis

Acidosis occurs when the pH is less or equal to 7.35 due to excess of hydrogen ions or loss of bicarbonate ions (HCO₃^-).

Alkalosis

Alkalosis refers to a condition reducing hydrogen ion concentration of arterial blood plasma (alkalemia) through the loss of acids or retention of bicarbonate. Generally alkalosis is said to occur when pH of the blood exceeds 7.45.

Approach to acid–base imbalance

Check pH on ABG

pH < 7.35= Acidosis

pH > 7.45= Alkalosis

Check PaCO₂

PaCO₂ > 45mm Hg =
Respiratory acidosis

PaCO₂ Normal or < 35mm Hg =
Metabolic acidosis

Check PaCO₂

PaCO₂ > 45mm Hg =
Metabolic alkalosis

PaCO₂ < 35mm Hg =
Respiratory alkalosis

[HCO₃^-] > 29

Check [HCO₃^-]

Normal or slight decrease =
Acute respiratory alkalosis

Decreased < 24 =
Chronic respiratory alkalosis

The following steps can help to generate a differential diagnosis on a patient with a suspected acid/base disorder:

Evaluate the complete clinical picture and laboratory data in patients with suspected acid-base disorder.
Single acid-base disorders are common compared to double (mixed) acid-base disorders, which are more common compared to triple acid-base disorders.
A normal pH doesn't exclude an acid-base disorder as a co-existing acidosis and alkalosis may result in a normal pH.
When the clinical picture raises a suspicion of an acid-base imbalance and the pH is normal, always check for the anion gap. For e.g., patient with diabetic ketoacidosis (metabolic acidosis) and vomiting (metabolic alkalosis) will present as a normal pH but with elevated anion gap.
When the primary disorder is acidosis, the body will compensate by developing an alkalosis (and vice-verse if the primary disorder is an alkalosis). When the primary disorder is respiratory, the body compensate with a metabolic (renal) process.

Steps in determining the presence of an acid-base disorder are:

Check serum pH
- Normal is 7.40 (7.35-7.45). Values lower than normal represent an acidosis; values higher than normal represent an alkalosis.
- Serum HCO₃^- drops of 4 to 5 mEq/L (4-5 mmol/L) for each 10 mm Hg (1.3 kPa) decrease in the pCO_2.^[1]
Check the pCO₂ and the HCO₃^- to decide whether the process is respiratory vs metabolic.
- Normal serum bicarbonate is 24mEq/dl; normal serum pCO₂ is 40.
Check the anion gap: serum sodium - (serum chloride plus serum HCO₃^-).
- Normal is 10 mEq/L [10 mmol/L])
Check for respiratory compensation of metabolic acidosis. Formula for checking appropriate respiratory compensation to metabolic acidosis include:
- Arterial pCO₂ = 1.5 x serum HCO₃^- + 8 ± 2 (Winters' formula)
- Arterial pCO₂ = Serum HCO₃^- + 15
- Arterial pCO₂ = (pH − 7) × 100. This is the coincidence rule^[2].
- For each increase in the PaCO₂ of 10 mmHg, the pH decreases by 0.08.
Calculate the corrected bicarbonate to check for any coexistent metabolic acidosis (see below delta-delta formula).^[3]
Measure the osmolar gap (online calculator). A high osmolar gap (online calculator) suggestions intoxication with osmotically active agents such as methanol, ethylene glycol, isopropyl alcohol, and toluene.

Coexistent elevated anion gap and normal anion gap metabolic acidosis

An elevated anion gap can coexist with a normal anion gap metabolic acidosis.
Delta-Delta equation: Change in anion gap = Change in bicarbonate.
- Change in gap (current gap - 12 mEq/L [12 mmol/L])^[3]
- Change in bicarb (current bicarb - 24 mEq/L [24 mmol/L])
- If the anion gap increases less and than the serum bicarbonate decreases suggests that there is another metabolic acidosis present, which is decreasing the the serum bicarbonate, but not affecting the anion gap i.e. normal anion gap metabolic acidosis is also present.

Respiratory compensation of metabolic acidosis

For 1 meq/L fall of serum HCO₃^- levels there is a 1.2 mmHg fall in arterial pCO₂.
The respiratory compensation of metabolic acidosis is fast and begins within half an hour of metabolic acidosis.
In cases where the metabolic acidosis develops slowly, the respiratory compensation occurs simultaneously with the metabolic acidosis.
The respiratory compensation usually completes within 12 to 24 hours.
A failure to develop adequate respiratory response indicates an acute underlying respiratory diseases, neurologic disease or a very acute development of metabolic acidosis.
Formula for checking appropriate respiratory compensation to metabolic acidosis include:
- Arterial pCO₂ = 1.5 x serum HCO₃^- + 8 ± 2 (Winters' formula)
- Arterial pCO₂ = serum HCO₃^- + 15
- If the measured pCO₂ is not close to predicted, a second disorder coexists.
- If the pCO₂ is less than predicted, respiratory alkalosis is present; if the pCO₂ is higher than predicted, respiratory acidosis is present.
- The maximum limit of respiratory compensation for a metabolic acidosis is pCO₂ of 20.

Role of the urine anion gap in the patient with a normal anion gap metabolic acidosis

Urine anion gap helps to differentiate renal tubular acidosis (specifically a Type 1 or Type 4 RTA) from other causes of normal anion gap acidosis.
The urine anion gap is calculated as the urine sodium plus urine potassium, minus the urine chloride
Urine anion gap = (Urine Na⁺ + Urine K⁺) - Urine Cl^-
The pathophysiology behind this is:
- When kidney is exposed to acidosis, the normal response of the kidney is to excrete acid.
- Kidney excretes the excess acid in the form of ammonium, NH₄⁺.
- To maintain neutrality, Cl^- is excreted along with ammonium, NH₄⁺.
- Thus, urine chloride act as a surrogate marker for urine ammonium (acidosis).
- In Types 1 and 4 renal tubular acidosis, the kidney's function of acid excretion is compromised (decreased excretion of NH₄⁺ and Cl^-).
- Thus, in renal tubular acidosis (specifically a Type 1 or Type 4 RTA) urine anion gap will be high (> than zero).
- A urine anion gap less than zero in the normal anion gap metabolic acidosis suggests the kidney is excreting acid, making renal tubular acidosis less likely.

Role of osmolar gap in differential diagnosis of elevated anion gap

Methanol, ethylene glycol, isopropyl alcohol, toluene are osmotically active substances.
Ingestion of these substances may lead to disturbances that have significant overlap.
They can be differentiated because of these following characteristics:
- Methanol
  - Also called wood alcohol
  - Used in antifreeze and solvents
  - Presentation: Delirium, papilledema, and retinal hemorrhages
  - Elevated anion gap metabolic acidosis
- Ethylene glycol
  - Used in antifreeze and solvents
  - Presentation: Delirium
  - Elevated anion gap metabolic acidosis
  - Presence of oxalate crystals in urine
- Isopropyl alcohol
  - Also called rubbing alcohol
  - No acid-base disorder
  - Metabolism causes increase acetone in the blood
  - Other conditions with elevated acetones in blood are: diabetes and starvation
- Toluene
  - Initial elevated anion gap followed with normal anion gap
Estimated serum osmolality = (2 * serum sodium + BUN/2.8 + Glucose/18)

Blood Gas Analysis

Venous blood gas sampling should not replace arterial blood gas sampling, but may supplement arterial blood gas monitoring as a mechanism of trending results and minimizing arterial sampling. Central venous blood is preferable to peripheral venous blood, as it more accurately represents the arterial blood gas results. Venous blood is more acidic than arterial blood, so venous pH is lower than arterial pH.

Blood gas analysis	Vessel	Range	Interpretation
Oxygen Partial Pressure (pO₂)	Arterial	80 to 100 mmHg	Normal
	Arterial	<80  mmHg	Hypoxia
	Venous	35 to 40 mmHg	Normal
Oxygen Saturation (SO₂)	Arterial	>95%	Normal
	Arterial	<95%	Hypoxia
	Venous	70 to 75%	Normal
pH	Arterial	<7.35	Acidemia
		7.35 to 7.45	Normal
		>7.45	Alkalemia
	Venous	7.26 to 7.46	Normal
Carbon Dioxide Partial Pressure (pCO₂)	Arterial	<35 mmHg	Low
		35 to 45 mmHg	Normal
		>45 mmHg	High
	Venous	40 to 45 mmHg	Normal
Bicarbonate (HCO₃^-)	Arterial	<22 mmol/L	Low
		22 to 26 mmol/L	Normal
		>26 mmol/L	High
	Venous	19 to 28 mmol/L	Normal
Base Excess (BE)	Arterial	<−3.4	Acidemia
		−3.4 to +2.3 mmol/L	Normal
		>2.3	Alkalemia
	Venous	−2 to −5 mmol/L	Normal
Osmolar gap = Osmolality – Osmolarity		>10	Abnormal
Anion gap = Na⁺ - [Cl⁻+ HCO₃^-] Corrected AG = (measured serum AG) + (2.5 x [4.5 − Alb])		<8	Low
		8 to 16	Normal
		>16	High

Compensation

There are compensation mechanisms in the body in order to normalizing the pH inside the blood.^[4]
The amount of compensation depends on proper functioning of renal and respiratory systems. However, it is uncommon to compensate completely. Compensatory mechanisms might correct only 50–75% of pH to normal.
Acute respiratory compensation usually occurs within first day. However, chronic respiratory compensation takes 1 to 4 days to occur.
Renal compensation might occur slower than respiratory compensation.

Primary disorder	pH	PaCO₂	[HCO₃^-]	Compensation	Compensation formula
Metabolic acidosis	↓	↓	↓	Respiratory	Expected paCO₂ = 1.5 x serum HCO₃^- + 8 ± 2 (Winters' formula) Expected paCO₂ = Serum HCO₃^- + 15
Metabolic alkalosis	↑	↑	↑	Respiratory	Expected paCO₂ = 0.5 − 1 increase/ every 1 unit increase in serum HCO₃^- from 24
Respiratory acidosis	↓	↑	↑	Renal	Acute: HCO₃^- increases by 1mEq/L for every 10 mmHg increase in paCO2 above 40 Chronic: HCO₃^- increases by 3.5mEq/L for every 10 mmHg increase in paCO2 above 40
Respiratory alkalosis	↑	↓	↓	Renal	Acute: HCO₃^- decreases by 2mEq/L for every 10 mmHg derease in paCO2 above 40 Chronic: HCO₃^- decreases by 5mEq/L for every 10 mmHg decrease in paCO2 above 40

Mixed Acid−Base Disorders

Disorder	Key features	Examples
Metabolic acidosis & respiratory alkalosis	High− or normal−AG metabolic acidosis PaCO₂ below predicted value	Lactic acidosis Sepsis in ICU
Metabolic acidosis & respiratory acidosis	High− or normal−AG metabolic acidosis PaCO₂ above the predicted value	Severe pneumonia Pulmonary edema
Metabolic alkalosis & respiratory alkalosis	PaCO₂ does not increase as predicted pH higher than expected	Liver disease Diuretics
Metabolic alkalosis & respiratory acidosis	PaCO₂ higher than predicted pH normal	COPD on diuretics
Metabolic acidosis & metabolic alkalosis	Only detectable with high−AG acidosis ∆AG >> ∆HCO₃^-	Uremia with vomiting
Metabolic acidosis & metabolic acidosis	Mixed high−AG & normal−AG acidosis ∆HCO₃^- accounted for by combined change in ∆AG and ∆Cl⁻	Diarrhea and lactic acidosis Toluene toxicity Treatment of diabetic ketoacidosis

Related Chapters

References

↑ American College of Physicians. Medical Knowledge Self-Assessment Program
↑ Liu GS, Bhalla V (2017). "Explaining the Coincidence Rule for Estimating Respiratory Compensation in Metabolic Acid-Base Disorders". Ann Intern Med. 166 (8): 610. doi:10.7326/L16-0470. PMID 28384697.
↑ ^3.0 ^3.1 Goodkin DA, Krishna GG, Narins RG (1984). "The role of the anion gap in detecting and managing mixed metabolic acid-base disorders". Clin Endocrinol Metab. 13 (2): 333–49. PMID 6488577.
↑ Sood P, Paul G, Puri S (April 2010). "Interpretation of arterial blood gas". Indian J Crit Care Med. 14 (2): 57–64. doi:10.4103/0972-5229.68215. PMC 2936733. PMID 20859488.

Template:WikiDoc Sources

[1] American College of Physicians. Medical Knowledge Self-Assessment Program

[pmid28384697-2] Liu GS, Bhalla V (2017). "Explaining the Coincidence Rule for Estimating Respiratory Compensation in Metabolic Acid-Base Disorders". Ann Intern Med. 166 (8): 610. doi:10.7326/L16-0470. PMID 28384697.

[pmid6488577-3] 3.0 ^3.1 Goodkin DA, Krishna GG, Narins RG (1984). "The role of the anion gap in detecting and managing mixed metabolic acid-base disorders". Clin Endocrinol Metab. 13 (2): 333–49. PMID 6488577.

[pmid20859488-4] Sood P, Paul G, Puri S (April 2010). "Interpretation of arterial blood gas". Indian J Crit Care Med. 14 (2): 57–64. doi:10.4103/0972-5229.68215. PMC 2936733. PMID 20859488.

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