Keywords
hepatitis - G6PD - viral - hemolysis - intravascular
Introduction
Acute viral hepatitis A is widely prevalent in India.[1] Viral hepatitis is the leading of acute hepatitis in children in our country, and
hepatitis A is the most common type of viral hepatitis. Hepatitis A does not commonly
present with severe anemia unless it is complicated by fulminant hepatic failure (FHF)
and significant blood loss. However, in patients with glucose-6-phosphate dehydrogenase
(G6PD) deficiency, the most common inherited enzyme deficiency worldwide,[2] hepatitis A may cause severe anemia in absence of major blood loss. This chance
association has been reported earlier by Sarkar et al.[3] The coincidence of acute hepatitis A and G6PD deficiency may cause acute intravascular
hemolysis, manifest as pallor, icterus, hepatosplenomegaly, and dark-colored urine.
The pathogenetic mechanism of hemolytic anemia in hepatitis A infection is ill-understood,
but it has been reported to be autoimmune mediated in at least some cases.[4]
[5] Here, we report a case of acute hepatitis A complicated by FHF and acute intravascular
hemolysis associated with G6PD deficiency.
Case Report
A 7-year-old male child born to a nonconsanguineous parent presented with moderate
grade fever, yellowish discoloration of eyes, and urine for the past 5 days before
admission. There was no history of hematemesis, melena, or any other bleeding, swelling
of body, convulsion, and drug ingestion just before present illness or any previous
blood transfusion. His urine volume was satisfactory. On examination, the child was
deeply icteric, severely anemic, and drowsy. Abdominal examination revealed soft hepatomegaly
of 6.5 cm below right costal arch on right midclavicular line and enlarged spleen
of approximately 3 cm below the left costal arch. There was no ascites. Except for
drowsiness he had no neurological deficit; his plantar reflexes were flexor. Slit
lamp examination of the eye did not reveal Keyser–Fleischer rings. On the day following
admission, his urine color changed to dark brown or blackish.
Laboratory testing on admission showed a normocytic, normochromic anemia (hemoglobin
4.5 g/dL), reticulocyte count 14.1%, and total leukocyte count 20,000/mm3 (neutrophils 80%, lymphocytes 17%, monocytes 2%, and eosinophils 1%). The platelet
count was 350 × 109/L. Prothrombin time was 15.9 seconds (control, 10.2 seconds), giving an international
normalized ratio of 1.3 (normal, 1–1.2), and activated partial thromboplastin time
was 23.5 seconds (normal, 22.6–35 seconds). The total serum bilirubin was 61.2 mg/dL
(conjugated, 32.9 mg/dL; unconjugated, 28.3 mg/dL); serum total protein was 5.9 g/dL,
and albumin and globulin were 3.6 and 2.3 g/dL, respectively, giving a albumin:globulin
ratio of 1.57:1 (normal, 2:1). Liver enzymes were elevated as follows: aspartate aminotransferase
1,474 U/L (normal, 0–40 U/L), alanine aminotransferase 680 U/L (normal, 0–41 U/L)
and alkaline phosphatase 354 U/L (normal, 100–250 U/L). Hepatitis A–specific IgM antibodies
were detected in serum; serological tests for hepatitis B, C, and E were negative.
The results of Coombs direct and indirect antiglobulin tests were negative. Serum
ceruloplasmin was 42.5 mg/dL (normal, 20–40 mg/dL), and urinary copper excretion was
45 µg during a 24-hour period (normal, 4–60 µg). Challenge with two doses of penicillamine
increased the 24-hour urine copper excretion to 150 µg. Urinalysis showed hemoglobinuria
without erythrocytes. Tests for antinuclear antibody and antismooth muscle antibody
were negative. Using the scoring system of the International Autoimmune Hepatitis
Group the objective score was < 10. A peripheral blood smear was negative for malaria,
and a dual malaria antigen test was also negative. G6PD assay showed a level of enzymatic
activity of 4.7 U/g Hb (normal, 4.6–3.5 U/g).
The child was managed with intravenous fluid and mannitol to maintain his fluid–electrolyte
balance. Cefotaxime was commenced empirically in case bacterial sepsis was the cause
of initial presentation; this was continued to protect the child from developing sepsis,
which is a common complication of FHF. The child was transfused 1 unit of concentrated
RBCs. After 48 hours, he regained full consciousness, and after 3 to 4 days the urine
discoloration improved. Two months later at outpatient follow-up, the patient had
hepatomegaly of 2.5 cm below right costal arch, but no splenomegaly, anemia, or jaundice.
Liver function test results had normalized; G6PD enzymatic activity was 1.30 U/g Hb.
Discussion
Hepatitis A virus infection is usually considered to be a mild disease, although severe,
even fatal, cases can occur.[6] In particular, G6PD deficient children are at risk of FHF, renal failure, hemolytic
anemia, and severe hyperbilirubinemia.[7] Acute hepatitis E infection with coexistent G6PD deficiency leading to acute hemoglobinuria
without acute renal failure has also been reported.[8] Likewise, hepatitis D superinfection in a chronic HBSAg carrier with G6PD deficiency
has been associated with acute hemoglobinuria.[9] Severe anemia without major blood loss is an unusual feature of hepatitis A infection.
In our case, the urine became blackish, rather than demonstrating the classic mustard
oil color of bilirubinuria. The presence of severe anemia together with the urine
appearance, severe jaundice, and splenomegaly made us suspect intravascular hemolysis.
Acute hemoglobinuria is usually associated with only a few conditions, for example,
mismatched blood transfusion, snake bite, G6PD deficiency, black water fever hemolytic
uremic syndrome, autoimmune hemolytic anemia (especially an acute variety that occurs
in children), Wilson disease. Black water fever was ruled out in this case. The G6PD
enzyme level was low-normal during acute phase of our case, but it was found to be
grossly reduced when retested during convalescence. This can occur because during
an episode of acute hemolysis, peripheral blood contains an excess of young red cells
that contain higher amounts of the G6PD enzyme. G6PD-deficient individuals usually
appear clinically normal; however, acute hemoglobinuria can be precipitated by bacterial
and viral infections, or by drugs, for example, primaquine, vitamin K, sulfonamides,
nalidixic acid. In our case, acute hepatitis A infection was the precipitating factor.
Earlier Hosnut et al[10] reported hemolysis in hepatitis A infection because of the autoimmune hemolytic
anemia and G6PD deficiency, but in their case, administration of vitamin K was considered
to have been a contributory factor.
Autoimmune hemolytic anemia was excluded in our case on the basis of negative autoimmune
antibody and direct and indirect Coombs test results. Autoimmune hepatitis was ruled
out by negative serological studies and by application of an objective scoring system.
Despite acute hemoglobinuria, this patient did not develop acute renal failure, contrary
to previous reports.[7]
[8]
G6PD catalyses the initial step in the hexose monophosphate shunt, oxidizing glucose-6-phosphate
to 6-phosphogluconolactone, and reducing NADP to NADPH. The hexose monophosphate shunt
pathway of glucose metabolism is the only red cell source of NADPH. NADPH acts as
a cofactor for conversion of glutathione to reduced glutathione, which is essential
to metabolize oxidant products within RBC. Thus, in the absence of reduced glutathione,
RBC is vulnerable to hemolysis.
In conclusion, it is suggested that all patients with acute viral hepatitis A, marked
hyperbilirubinemia and severe pallor should be assessed for acute intravascular hemolysis
and G6PD deficiency. Universal vaccination against hepatitis A, or routine newborn
screening for G6PD deficiency in Asian countries like India, would help avoid hepatitis
A–associated acute intravascular hemolysis. Evidence in the form of large clinical-
and cost-effectiveness studies is required to support a change in national policy.
