acid-base homeostasis

Carbonic acid equilibria are important for acid-base homeostasis in the human body.

Drinking ionized water would not be expected to alter the body's pH, due to the acid-base homeostasis.

Boron's lifelong research interest has been acid-base homeostasis.

The kidneys maintain acid-base homeostasis by regulating the pH of the blood plasma.

It is one of four basic categories of disruption of acid-base homeostasis.

The lungs contribute to acid-base homeostasis by regulating carbon dioxide (CO) concentration.

The bicarbonate buffering system is an important buffer system in the acid-base homeostasis of living things, including humans.

Two organ systems, the kidneys and lungs, maintain acid-base homeostasis, which is the maintenance of pH around a relatively stable value.

For their contribution to acid-base homeostasis, the intercalated cells play important roles in the kidney's response to acidosis and alkalosis.

The pH of different cellular compartments, body fluids, and organs is usually tightly regulated in a process called acid-base homeostasis.

However, to date no human trials have been undertaken due to physiological implausibility as the human body tightly controls Acid-base homeostasis.

Acid-base homeostasis is the part of human homeostasis concerning the proper balance between acids and bases, also called body pH.

Intercalated cells come in α and β varieties and participate in acid-base homeostasis.

The most common disorder in acid-base homeostasis is acidosis, which means an acid overload in the body, generally defined by pH falling below 7.35.

Acid-base equilibria are important in a very wide range of applications, such as acid-base homeostasis, ocean acidification, pharmacology and analytical chemistry.

Bicarbonate is alkaline, and a vital component of the pH buffering system of the human body (maintaining acid-base homeostasis).

A knowledge of equilibrium constants is essential for the understanding of many chemical systems, as well as biochemical processes such as oxygen transport by hemoglobin in blood and acid-base homeostasis in the human body.

The relationship between diet and acid-base homeostasis, or the regulation of the acid-base status of the body, has been studied for decades, though the medical applications of this theory have largely focused on changing the acidity of urine.

Ketone bodies are acidic, but acid-base homeostasis in the blood is normally maintained through bicarbonate buffering, respiratory compensation to vary the amount of CO in the bloodstream, hydrogen ion absorption by tissue proteins and bone, and renal compensation through increased excretion of dihydrogen phosphate and ammonium ions.