Serum creatinine (a blood measurement) is an important indicator of
kidney function, because it is an easily measured byproduct of muscle metabolism that is excreted unchanged by the kidneys. Creatinine itself is produced via a biological system involving
creatine,
phosphocreatine (also known as creatine phosphate), and
adenosine triphosphate (ATP, the body's immediate energy supply). Creatine is synthesized primarily in the liver by methylation of
glycocyamine (guanidino acetate, synthesized in the kidney from the
amino acids
arginine and
glycine) by
S-adenosyl methionine. It is then transported in the blood to other organs, muscles, and the brain, where it is
phosphorylated to phosphocreatine, a high-energy compound. Creatinine is removed from the blood chiefly by the kidneys, primarily by
glomerular filtration, but also by proximal
tubular secretion. Little or no
tubular reabsorption of creatinine occurs. If filtration in the kidney is deficient, blood creatinine concentrations rise. Therefore, creatinine concentrations in blood and urine may be used to calculate the
creatinine clearance (CrCl), which correlates approximately with the
glomerular filtration rate (GFR). Blood creatinine concentrations may also be used alone to estimate the GFR (eGFR). The GFR is clinically important as a measurement of
kidney function. However, in cases of severe kidney dysfunction the CrCl rate will overestimate the GFR, because hypersecretion of creatinine by the proximal renal tubules will account for a larger fraction of the total creatinine cleared.
Ketoacids,
cimetidine, and
trimethoprim reduce creatinine tubular secretion and therefore increase the accuracy of the GFR estimate, in particular in severe kidney dysfunction. (In the absence of secretion, creatinine behaves like
inulin.) An alternative estimation of kidney function can be made when interpreting the blood plasma concentration of creatinine along with that of
urea.
BUN-to-creatinine ratio (the ratio of
blood urea nitrogen to creatinine) can indicate other problems besides those intrinsic to the kidney; for example, a urea concentration raised out of proportion to the creatinine may indicate a prerenal problem, such as volume depletion. Counterintuitively, supporting the observation of higher creatinine production in women than in men, and putting into question the algorithms for GFR that do not distinguish for sex, women have higher muscle protein synthesis and higher muscle protein turnover across their life span. As HDL supports muscle anabolism, higher muscle protein turnover links increased creatine to the generally higher serum HDL in women compared with serum HDL in men.
Antibacterial and potential immunosuppressive properties Studies suggest that creatinine can be effective in killing bacteria of many species, both
Gram positive and
Gram negative, as well as diverse
antibiotic-resistant bacterial strains. Creatinine appears not to affect the growth of fungi and yeasts; this can be used to isolate slower growing fungi free from the normal bacterial populations found in most environmental samples. The mechanism by which creatinine kills bacteria is not currently known. Some reports also suggest that creatinine may have
immunosuppressive properties. ==Diagnostic use==