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Synonyms: G6PD/G-6-PD deficiency, non-spherocytic haemolytic anaemia
The enzyme glucose-6-phosphate dehydrogenase (G6PD) is one of the enzymes of the pentose phosphate pathway. This pathway is involved in keeping an adequate amount of the co-enzyme nicotinamide adenine dinucleotide phosphate (NADPH) in cells. NADPH in turn maintains the levels of glutathione which protects the red cell from oxidative damage. G6PD is the rate-limiting enzyme in the pentose phosphate pathway. Thus deficiency of the G6PD enzyme results in reduced glutathione making the red cells vulnerable to oxidative damage and thus liable to haemolysis.
The disease is X-linked with about 300 variants reported. Most of the variants occur sporadically and are single amino acid defects in a protein of 515 amino acids.
Classes of G6PD deficiency enzyme variants
- Severe (I) - chronic nonspherocytic haemolytic anaemia
- Severe (II) - less than 10% of normal enzyme activity
- Moderate (III) - 10 to 60% of normal enzyme activity
- Mild to none (IV) - 60 to 150% of normal enzyme activity
- None (V) - greater than 150% of normal enzyme activity
More detailed information about variants is available under the OMIM listing.
- Most individuals with the G6PD defect are asymptomatic and unaware of their status.
- About 400 million people are affected worldwide with gene frequency between 5 and 25% in tropical Africa, the Middle East, tropical and subtropical Asia, some areas of the Mediterranean, and Papua New Guinea. This makes it the most common disease-producing enzyme deficiency in the world.
- It affects all races but is most common in those of African, Asian or Mediterranean descent. It tends to be milder in those of African origin and more severe in the Mediterranean races.
- The epidemiology of G6PD deficiency has been noted to be remarkably similar to that of malaria, adding support to the "malaria protection hypothesis". In vitro work has shown that malaria parasites grow slowest in G6PD-deficient cells.
- In an African population, possession of the defect in men or the heterozygous gene in women gave protection of between 48 and 56% against severe malaria but it was estimated from a mathematical model that, although G6PD deficiency is now regarded as a generally benign disorder, in earlier environmental conditions it could have been significantly disadvantageous and this limited its spread.
- Being X-linked, the disease affects mainly men but in areas of high frequency it is not uncommon to find homozygous women.
Factors that precipitate haemolytic crises
- Certain drugs (see below)
Drugs to watch out for in G6PD-deficient individualsDrugs with definite risksDrugs with possible risks
- Primaquine - although 30 mg weekly for 8 weeks has been found to be without undue harmful effects in African and Asian people
- Methylene blue (methylthioninium chloride)
- Nitrofurantoin and quinolones including ciprofloxacin, moxifloxacin, nalidixic acid, norfloxacin, and ofloxacin
- Sulphonamides including co-trimoxazole although some sulphonamides like sulfadiazine have been tested and found not to be haemolytic in many with G6PD deficiency
- Sulphonylureas, eg glibenclamide
- Aspirin, although a dose up to 1 gram daily is usually harmless
- Chloroquine and quinine but they may be used in acute malaria
- Vitamin K analogues like menadione and water-soluble derivatives like menadiol sodium phosphate
- Certain foods, eg eating broad beans leads to favism (see separate article Favism)
- Severe infection
- Diabetic ketoacidosis
- Acute renal failure (causes a severe crises)
- Depends upon the severity of the enzyme deficiency
- Most are asymptomatic
- May be a history of neonatal jaundice, even requiring exchange transfusion
- History of drug-induced haemolysis
- Gallstones are common
- Most often examination is unremarkable
- Pallor of anaemia
- During a crisis jaundice occurs
- Back or abdominal pain (usually occurs when >50% haemolysis occurs)
- Splenomegaly may occur
- Full blood count - anaemia
- Macrocytosis - due to reduced folic acid which is required for erythropoiesis
- Reticulocyte count - raised; gives indication of the bone marrow activity (bone marrow sampling thus not needed)
- Blood film - acute haemolysis from G6PD deficiency can produce Heinz bodies, which are denatured haemoglobin and bite cells (cells with Heinz bodies that pass through the spleen have part of the membrane removed)
- Haemolysis - reduced levels of haptoglobin and elevated levels of bilirubin; haemoglobinuria
- Direct antiglobulin test - to look for other causes of haemolysis; should be negative in G6PD deficiency
- Renal function - to ensure no renal failure as a precipitant
- Liver function tests - to exclude other causes of raised bilirubin
- G6PD enzyme activity - is definitive test (as opposed to the amount of G6PD protein)
- Performing assays for G6PD during haemolysis and reticulocytosis may affect levels and not reflect baseline values
- Ultrasound examination of the abdomen may reveal splenomegaly and gallstones
Management of acute haemolysis
- Seek specialist advice
- Blood transfusions may be needed
- Dialysis may be required in acute renal failure
- Infants - more susceptible to neonatal jaundice, especially if premature and exchange transfusion may be required
Management of chronic haemolysis or stable disease
- Splenectomy may help
- Supplementation with folic acid
- Avoidance of precipitating drugs, broad beans (usually favism occurs in the Mediterranean variety of the disease)
- Avoid naphthalene - found in mothballs
Complications and prognosis
Most people with G6PD deficiency have a normal life expectancy despite a predisposition to neonatal jaundice and sensitivity to certain drugs. There may be a hidden risk for kernicterus if neonatal jaundice is not energetically treated. However, G6PD activity is higher in premature infants born between 29 and 32 weeks' gestation than in term neonates. Even if G6PD deficiency is anticipated, prophylactic oral phenobarbital given to the baby after delivery does not decrease the need for phototherapy or exchange transfusions in G6PD-deficient neonates. Sn-mesoporphyrin (SnMP) is a potent inhibitor of bilirubin production that is effective in moderating neonatal hyperbilirubinaemia caused by ABO incompatibility, immaturity, and unspecified mechanisms and may also help in G6PD deficiency. A paper from Sardinia suggested that, as G6PD activity was present in the lens of the eye, men with the condition were less susceptible to cataracts. However a few years later, another paper, also from Sardinia, did not find this association.
Although the disease is thought to be fairly benign, where enzyme levels are severely deficient there can be inadequate leukocyte function also. This results in chronic granulomatous disease. In Saudi Arabia the G6PD status of all children aged 1 month to 14 years, who were treated for meningitis, septicaemia, osteomyelitis, or typhoid fever during a 9-year period, was reviewed. The observed frequency of G6PD deficiency was significantly higher than expected for the entire group, for females with both catalase-positive and catalase-negative infection, and for males with catalase-positive infections.
Further reading & references
- Frank JE; Diagnosis and management of G6PD deficiency. Am Fam Physician. 2005 Oct 1;72(7):1277-82.
- Glucose-6-phosphate Dehydrogenase (G6PD) Deficiency, Online Mendelian Inheritance in Man (OMIM)
- Cappellini MD, Fiorelli G; Glucose-6-phosphate dehydrogenase deficiency. Lancet. 2008 Jan 5;371(9606):64-74.
- Ruwende C, Khoo SC, Snow RW, et al; Natural selection of hemi- and heterozygotes for G6PD deficiency in Africa by resistance to severe malaria. Nature. 1995 Jul 20;376(6537):246-9.
- Weatherall DJ; ABC of clinical haematology. The hereditary anaemias. BMJ. 1997 Feb 15;314(7079):492-6.
- Kaplan M, Hammerman C; Glucose-6-phosphate dehydrogenase deficiency: a hidden risk for kernicterus. Semin Perinatol. 2004 Oct;28(5):356-64.
- Mesner O, Hammerman C, Goldschmidt D, et al; Glucose-6-phosphate dehydrogenase activity in male premature and term neonates. Arch Dis Child Fetal Neonatal Ed. 2004 Nov;89(6):F555-7.
- Murki S, Dutta S, Narang A, et al; A randomized, triple-blind, placebo-controlled trial of prophylactic oral phenobarbital to reduce the need for phototherapy in G6PD-deficient neonates. J Perinatol. 2005 May;25(5):325-30.
- Valaes T, Drummond GS, Kappas A; Control of hyperbilirubinemia in glucose-6-phosphate dehydrogenase-deficient newborns using an inhibitor of bilirubin production, Sn-mesoporphyrin. Pediatrics. 1998 May;101(5):E1.
- Orzalesi N, Sorcinelli R, Guiso G; Increased incidence of cataracts in male subjects deficient in glucose-6-phosphate dehydrogenase. Arch Ophthalmol. 1981 Jan;99(1):69-70.
- Meloni T, Carta F, Forteleoni G, et al; Glucose 6-phosphate dehydrogenase deficiency and cataract of patients in northern Sardinia. Am J Ophthalmol. 1990 Dec 15;110(6):661-4.
- Cooper MR, DeChatelet LR, McCall CE, et al; Complete deficiency of leukocyte glucose-6-phosphate dehydrogenase with defective bactericidal activity. J Clin Invest. 1972 Apr;51(4):769-78.
- Mallouh AA, Abu-Osba YK; Bacterial infections in children with glucose-6-phosphate dehydrogenase deficiency. J Pediatr. 1987 Dec;111(6 Pt 1):850-2.
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|Original Author: Dr Gurvinder Rull||Current Version: Dr Gurvinder Rull|
|Last Checked: 22/06/2011||Document ID: 2201 Version: 23||© EMIS|