Acquired Methemoglobinemia may be acquired. Classical drug causes of methemoglobinemia include various
antibiotics (
trimethoprim,
sulfonamides, and
dapsone),
local anesthetics (especially
articaine,
benzocaine,
prilocaine, and
lidocaine), and
aniline dyes,
metoclopramide,
rasburicase,
umbellulone,
chlorates,
bromates, and
nitrites. Nitrates are suspected to cause methemoglobinemia. In otherwise healthy individuals, the protective enzyme systems normally present in red blood cells rapidly reduce the methemoglobin back to hemoglobin and hence maintain methemoglobin levels at less than one percent of the total hemoglobin concentration. Exposure to exogenous oxidizing drugs and their metabolites (such as benzocaine, dapsone, and nitrates) may lead to an increase of up to a thousandfold of the methemoglobin formation rate, overwhelming the protective enzyme systems and acutely increasing methemoglobin levels. Infants under six months of age have lower levels of a key methemoglobin reduction enzyme (
NADH-cytochrome b5 reductase) in their red blood cells. This results in a major risk of methemoglobinemia caused by nitrates ingested in drinking water, dehydration (usually caused by gastroenteritis with diarrhea), sepsis, or topical anesthetics containing benzocaine or prilocaine resulting in
blue baby syndrome. Nitrates used in agricultural fertilizers may leak into the ground and may contaminate well water. The current EPA standard of 10 ppm nitrate-nitrogen for drinking water is specifically set to protect infants.
Genetic pattern of inheritance. Due to a deficiency of the
enzyme diaphorase I (
cytochrome b5 reductase), methemoglobin levels rise and the blood of met-Hb patients has reduced oxygen-carrying capacity. Instead of being red in color, the arterial blood of met-Hb patients is brown. This results in the skin of white patients gaining a bluish hue. Hereditary met-Hb is caused by a
recessive gene. If only one parent has this gene, offspring will have normal-hued skin, but if both parents carry the gene, there is a chance the offspring will have blue-hued skin. Another cause of congenital methemoglobinemia is seen in patients with abnormal hemoglobin variants such as
hemoglobin M (HbM), or
hemoglobin H (HbH), which are not amenable to
reduction despite intact enzyme systems. Methemoglobinemia can also arise in patients with
pyruvate kinase deficiency due to impaired production of
NADH – the essential cofactor for diaphorase I. Similarly, patients with
glucose-6-phosphate dehydrogenase deficiency may have impaired production of another co-factor,
NADPH. ==Pathophysiology==