Biochemistry at The Biology Project

Clinical Correlates of pH Levels
Problem Set

Introduction

Bicarbonate as a buffer

The major buffering systems in the body are proteins (his, asp, glu), phosphate and bicarbonate. All three of these have pKa values lower than physiological pH. As a consequence, buffering capacity increases as the pH is lowered from the physiological range. Most physiological pH excursions occur in the acid direction. Hence, the low pKa of these buffering systems is poised to respond to metabolic acidosis.

Of these three, only bicarbonate is in steady-state between production and removal, and this has important consequences. Thus, pH changes (or buffering) via this dynamic bicarbonate system are taking place on a background provided by the more static protein and phosphate systems.

Production of Bicarbonate
The components of the bicarbonate buffering system are produced in large quantities metabolically. Hence, the body is not dependent on ingestion of exogenous compounds or complex syntheses to maintain this buffering system.

Removal of Bicarbonate
The bicarbonate buffering system is in volatile equilibrium (via breathing) with the external environment (lungs and air). Thus it is able to respond rapidly to endogenous alterations. It can also be positively (or negatively) affected by environmental manipulation.

The acid components of the bicarbonate system (i.e. H+ and CO2) cross biological membranes rapidly, thus do not depend on complex transport kinetics.

The anion (base) component (HCO3-) is transported rapidly in all cells via anion exchange. Consequently, the bicarbonate buffering system helps to maintain intracellular, as well as extracellular, pH.

These acid components of the bicarbonate system are transported from the tissues to the lungs by Hemoglobin. Thus, this important protein participates in both the production and removal of metabolic acid.

Clinical Correlates: Acidosis & Alkalosis

CO2 produced by metabolism is normally balanced by CO2 expired from the lungs, resulting in no net production of H2CO3. However, certain medically significant circumstances can throw the equation out of balance.

Condition Possible causes
respiratory acidosis apnea or impaired lung capacity, with a build-up of CO2 in the lungs.
metabolic acidosis ingestion of acid, production of ketoacids in uncontrolled diabetes, or kidney failure. (These all result in build-up of H+ from sources other than excess CO2. )

Condition Possible causes
respiratory alkalosis hyperventilation, with a net loss of CO2 from the blood.
metabolic alkalosis ingestion of alkali, prolonged vomiting (loss of HCl), or extreme dehydration leading to kidney retention of bicarbonate. (The common thread is loss of H+ for reasons other than depletion of CO2.)

Treatment

Although a slight drop in pH from 7.4 to 7.2 does not sound 

significant, this involves an increase in H<SUP>+</SUP> concentration from 3.9 to x 10<SUP>-8</SUP> M to 6.3 x 10<SUP>-8</SUP> M, an increase of > 60%!

Because respiratory problems are caused by alterations in CO2, the best treatment involves ventilation. If bicarb is used to raise the pH in cases of respiratory acidosis, the result can be fatal, since compensation is also working to increase the blood bicarb concentration.

Because metabolic problems involve HCO3-, the best treatment is either bicarbonate infusion (for acidosis) or NH4Cl infusion (for alkalosis). NH4Cl dissociates into NH4+ and Cl-. The NH4+ (ammonium) is in equilibrium with NH3 (ammonia) and H+. Because ammonia is volatile, it is respired through the lungs, leaving behind H+ and Cl1 or hydrochloric acid, which lowers the pH. Often, metabolic acidosis is found in combination with respiratory alkalosis (e.g. compensated). This is a fragile situation because the buffering power is significantly reduced.


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The University of Arizona
January 14, 1999
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