34,804views
00:00 / 00:00
of complete
Every single moment, there are trillions of biochemical reactions going on inside our bodies. These reactions are mediated by enzymes, and for these enzymes to function properly, the pH of our body fluids needs be within a tightly regulated range.
This pH depends on the ratio of the concentration of bases, mainly HCO3−, and acids, mainly CO2, and it’s calculated by a lengthy, complicated equation, known as the Henderson-Hasselbalch equation, where pH = 6.1 + log HCO3− concentration / 0.03 partial pressure of CO2.
If we focus on the pH of our arterial blood, we can design a diagram, or acid- base map, with the concentration of HCO3− on the x axis, and the partial pressure of CO2, or PCO2, on the y axis.
Using the Henderson-Hasselbalch equation, we can plot a line called an isohydric line that starts at the origin.
The term isohydric means that along these points, they all share the same or “iso-“ concentration of hydrogenated ions or same pH - “hydric”.
For example, let’s say HCO3− concentration is 24 mEq/L and PCO2 is 40 mmHg. According to the Henderson- Hasselbalch equation, this would give us a pH of 7.4. Now, we’ d have the same pH of 7.4 if there was a HCO3− concentration of 36 mEq/L and PCO2 of 60 mmHg, or with a HCO3− concentration of 12 mEq/L and a PCO2 of 20 mmHg.
In fact, we can draw out two more isohydric lines - this time for a pH of 7.35, and another for a pH of 7.45. A normal pH is between 7.35 and 7.45, so you can see that there are a lot of combinations of HCO3− concentration and PCO2 that are between these two lines that would result in a normal pH.
In fact, because it’s so important for the body to stay between these lines, the body has designed several mechanisms to maintain homeostasis or balance.
One mechanism involves the lungs, specifically the rate and depth of breathing which controls the amount of CO2 that’s breathed out.
And another mechanism involves the kidneys, which, slowly can carefully control the amount of HCO3− that’s excreted.
Now, sometimes these regulatory processes get disturbed. Specifically, if there’s a decrease in the ratio of HCO3− concentration to PCO2, the pH drops below 7.35 and we shift to the upper left part of the acid- base map, where there’s acidosis.
On the other hand, when this ratio increases, the pH rises above 7.45 and we move to the lower right part of the acid-base, where there’s alkalosis.
Acidosis and alkalosis can be classified according to their root cause as being either respiratory or metabolic.
Acid-base maps and compensatory mechanisms are great tools for managing pH levels in the body. Ideally, the body should maintain a slightly alkaline pH range of 7.35 to 7.45. However, sometimes the body's pH levels can become unbalanced, usually due to an illness, like diabetic ketoacidosis.
When this happens, the body kicks off its compensatory mechanisms to restore the normal blood pH range. One mechanism involves the lungs, which through the control of the rate and depth of breathing regulate the amount of CO2 that's breathed out; and the kidneys, which carefully control the amount of HCO3 �� that's excreted.
Copyright © 2024 Elsevier, its licensors, and contributors. All rights are reserved, including those for text and data mining, AI training, and similar technologies.
Cookies are used by this site.
USMLE® is a joint program of the Federation of State Medical Boards (FSMB) and the National Board of Medical Examiners (NBME). COMLEX-USA® is a registered trademark of The National Board of Osteopathic Medical Examiners, Inc. NCLEX-RN® is a registered trademark of the National Council of State Boards of Nursing, Inc. Test names and other trademarks are the property of the respective trademark holders. None of the trademark holders are endorsed by nor affiliated with Osmosis or this website.