Quantitation of alcohol level for medical or legal purposes; test unconscious patients; used to diagnose alcohol intoxication and determine appropriate therapy; detect alcoholism and to monitor ethanol treatment for methanol intoxication. Must be tested as possible cause of coma of unknown etiology since alcohol intoxication may mimic diabetic coma, cerebral trauma, and drug overdose.

Ethanolamine is an intermediary metabolite in the serine-to-choline sequence. It can be used to synthesize phosphatidylethanolamine (PE), a very important membrane phospholipid. Ethanolamine is not only a precursor, but also a breakdown product of PE. Ethanolamine is abundant in both intestinal and bacterial cell membranes. It plays a significant role in the renewal and proliferation of intestinal cells and intestinal inflammation. Also, since ethanolamine plays a structural role in skeletal muscle cell membranes, some evidence suggests it may be a marker of skeletal muscle turnover.

Ethanolamine is an intermediary metabolite in the serine-to-choline sequence. It can be used to synthesize phosphatidylethanolamine (PE), a very important membrane phospholipid. Ethanolamine is not only a precursor, but also a breakdown product of PE. Ethanolamine is abundant in both intestinal and bacterial cell membranes. It plays a significant role in the renewal and proliferation of intestinal cells and intestinal inflammation. Also, since ethanolamine plays a structural role in skeletal muscle cell membranes, some evidence suggests it may be a marker of skeletal muscle turnover.

Ethanolamine is an intermediary metabolite in the serine-to-choline sequence. It can be used to synthesize phosphatidylethanolamine (PE), a very important membrane phospholipid. Ethanolamine is not only a precursor, but also a breakdown product of PE. Ethanolamine is abundant in both intestinal and bacterial cell membranes. It plays a significant role in the renewal and proliferation of intestinal cells and intestinal inflammation. Also, since ethanolamine plays a structural role in skeletal muscle cell membranes, some evidence suggests it may be a marker of skeletal muscle turnover.

Ethanolamine is an intermediary metabolite in the serine-to-choline sequence. It can be used to synthesize phosphatidylethanolamine (PE), a very important membrane phospholipid. Ethanolamine is not only a precursor, but also a breakdown product of PE. Ethanolamine is abundant in both intestinal and bacterial cell membranes. It plays a significant role in the renewal and proliferation of intestinal cells and intestinal inflammation. Also, since ethanolamine plays a structural role in skeletal muscle cell membranes, some evidence suggests it may be a marker of skeletal muscle turnover.

Ethanolamine is an intermediary metabolite in the serine-to-choline sequence. It can be used to synthesize phosphatidylethanolamine (PE), a very important membrane phospholipid. Ethanolamine is not only a precursor, but also a breakdown product of PE. Ethanolamine is abundant in both intestinal and bacterial cell membranes. It plays a significant role in the renewal and proliferation of intestinal cells and intestinal inflammation.

Also, since ethanolamine plays a structural role in skeletal muscle cell membranes, some evidence suggests it may be a marker of skeletal muscle turnover.

Ethanolamine is an intermediary metabolite in the serine-to-choline sequence. It can be used to synthesize phosphatidylethanolamine (PE), a very important membrane phospholipid. Ethanolamine is not only a precursor, but also a breakdown product of PE. Ethanolamine is abundant in both intestinal and bacterial cell membranes. It plays a significant role in the renewal and proliferation of intestinal cells and intestinal inflammation. Also, since ethanolamine plays a structural role in skeletal muscle cell membranes, some evidence suggests it may be a marker of skeletal muscle turnover.

Ethanolamine is an intermediary metabolite in the serine-to-choline sequence. It can be used to synthesize phosphatidylethanolamine (PE), a very important membrane phospholipid. Ethanolamine is not only a precursor, but also a breakdown product of PE. Ethanolamine is abundant in both intestinal and bacterial cell membranes. It plays a significant role in the renewal and proliferation of intestinal cells and intestinal inflammation. Also, since ethanolamine plays a structural role in skeletal muscle cell membranes, some evidence suggests it may be a marker of skeletal muscle turnover.

Ethanolamine is a metabolite of the nonessential amino acid serine. In the presence of adequate levels of functional B-6 (P-5-P) serine is enzymatically converted to ethanolamine.

Ethanolamine is a metabolite of the nonessential amino acid serine. In the presence of adequate levels of functional B-6 (P-5-P) serine is enzymatically converted to ethanolamine.

Ethanolamine, Plasma is a marker measured in an Amino Acid Profile, Quantitative (Plasma) panel, which plays an important role in various bodily functions. Ethanolamine is a key component of phospholipids, which are essential building blocks of cell membranes. This compound is involved in the synthesis of phosphatidylethanolamine, a crucial phospholipid that helps maintain the structural integrity and fluidity of cell membranes. Beyond its structural role, ethanolamine is also involved in cell signaling and neurotransmission, particularly in the central nervous system. It serves as a precursor for the synthesis of acetylcholine, a vital neurotransmitter that affects muscle contraction, memory, and learning. Normal levels of ethanolamine in the plasma indicate proper cellular function and membrane stability.

Ethinyl estradiol is an estrogen receptor agonist commonly used in combined oral contraceptives. It is a synthetic derivative of estradiol. In the liver it stimulates the synthesis of SHBG, increasing SHBG levels by 2- to 4-fold in women, which has the effect of binding more circulating testosterone and reducing free testosterone concentrations by 40-80%. The suppression of free testosterone levels may impact female sexual desire.

Ethylmalonate, together with Adipate and Suberate, gives information about your ability to process fatty acids.

Ethylmalonate, together with Adipate and Suberate, gives information about your ability to process fatty acids.

Ethylmalonate, which comes from the breakdown of butyrate, has a carnitine-dependent pathway and can accumulate with an insufficient amount of carnitine. Dietary fat, carbohydrate, and protein are all broken down to produce energy using pathways that require vitamin B2 (riboflavin).

Ethylmalonate, together with Adipate and Suberate, gives information about your ability to process fatty acids.