Metabolic acidosis

Last updated: August 08, 2023

Metabolic acidosis

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Flashcards

Metabolic acidosis

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Questions

USMLE® Step 1 style questions USMLE

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Start
A 21-year old woman is brought to the emergency room after intentionally ingesting 60 tablets of an unknown medication in a suicide attempt. She says that her life has become unbearable, and she is constantly depressed. She notices a ringing in her ears and feels nauseated. Her medical history is significant for two prior suicide attempts and inpatient psychiatric treatment for bipolar disorder. Her temperature is 37.1°C (98.8°F), pulse is 86/min, respirations are 16/min, and blood pressure is 124/90 mmHg. Physical examination shows a disheveled, lethargic female; external auditory canals are normal bilaterally with pinkish-grey, translucent tympanic membranes in the neutral position. Laboratory studies show the following:


Which of the following best describes this patient’s acid-base status?

Transcript

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With metabolic acidosis, “acidosis” refers to a process that lowers blood pH below 7.35, and “metabolic” refers to the fact that it’s a problem caused by a decrease in the bicarbonate HCO3− concentration in the blood.

Normally, blood pH depends on the balance or ratio between the concentration of bases, mainly bicarbonate HCO3−, which increases the pH, and acids, mainly carbon dioxide CO2, which decrease the pH.

The blood pH needs to be constantly between 7.35 and 7.45, and in addition the blood needs to remain electrically neutral, which means that the total cations, or positively charged particles, equals the total anions, or negatively charged particles.

Now, not all of the ions are easy or convenient to measure, so typically the dominant cation, sodium Na+, which is typically around 137 mEq/L and the two dominant anions, chloride Cl−, which is about 104 mEq/L, and bicarbonate HCO3−, which is around 24 mEq/L, are measured.

The rest are unmeasured. So just counting up these three ions, there’s usually a difference, or “gap” between the sodium Na+ concentration and the sum of bicarbonate HCO3− and chloride Cl− concentrations in the plasma, which is 137 minus 128 (104 plus 24) or 9 mEq/L.

This is known as the anion gap, and normally it ranges between 3 and 11 mEq/L. The anion gap largely represents unmeasured anions like organic acids and negatively charged plasma proteins, like albumin.

So, basically, metabolic acidosis arises either from the buildup of acid in our blood, which could be because it’s produced or ingested in increased amounts, or because the body can’t get rid of it, or from excessive bicarbonate HCO3− loss from the kidneys or gastrointestinal tract.

The main problem with all of this is that they lead to a primary decrease in the concentration of bicarbonate HCO3− in the blood.

They can be broken down to two categories, based on whether the anion gap is high or normal. So, the first category of metabolic acidosis is a high anion gap metabolic acidosis.

In this case, the bicarbonate HCO3− ion concentration decreases by binding of bicarbonate HCO3− ions and protons H+, which results in the formation of H2CO3 carbonic acid, which subsequently breaks down into carbon dioxide CO2 and water H2O.

These protons can come from organic acids which have accumulated in the blood, but they can also come from increased production in our body.

One such example is lactic acidosis, which is where decreased oxygen delivery to the tissues leads to increased anaerobic metabolism and the buildup of lactic acid.

Another example is diabetic ketoacidosis, which can occurs in uncontrolled diabetes mellitus, where the lack of insulin forces cells to use fats as primary energy fuel instead of glucose.

Fats are then converted to ketoacids, such as acetoacetic acid and β-hydroxybutyric acid.

Another way acids can build up in our blood is due to an inability of the kidneys to throw them away, although they are produced in normal amounts.

This can happen in cases of chronic renal failure, in which organic acids such as uric acid or sulfur- containing amino acids can accumulate because they aren’t excreted normally.

In other cases, organic acids don’t come from inside our bodies at all, but, instead, they are accidentally ingested.

These include oxalic acid which can build up after an accidental ingestion of ethylene glycol, which is a common antifreeze, formic acid, which is a metabolite of methanol, a highly toxic alcohol, or hippuric acid, which comes from toluene, which is found in paint and glue.

All of these organic acids have protons, and at a physiologic pH, these organic acids dissociate into protons H+ and corresponding organic acid anions.

The protons H+ attach to bicarbonate HCO3− ions floating around, decreasing its plasma concentration and shifting the pH towards the acidic range.

The key is that the plasma maintains its electroneutrality, because for each new negatively charged organic acid anions, there’s one less bicarbonate HCO3− ion, and because the organic acid anions are not part of the anion gap equation, the anion gap will be high.

Key Takeaways

Metabolic acidosis is a condition in which the body produces too much acid (e.g. acetic acid or ketones), or excessively loses bicarbonate ions (e.g. diarrhea or renal failure). In metabolic acidosis, the respiratory center is stimulated in order to compensate for the acidosis and the individual hyperventilates, leading to dyspnea. Other associated symptoms are related to the underlying cause, for example, in diabetic ketoacidosis there's nausea and vomiting.

Sources

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