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Amid A, Lal A, Coates TD, et al., editors. Guidelines for the Management of α-Thalassaemia [Internet]. Nicosia (Cyprus): Thalassaemia International Federation; 2023.
Introduction
The clinical expression of haemoglobin H (HbH) disease extends from mild asymptomatic anaemia to severe anaemia with transfusion-dependence and hydrops foetalis [1, 2]. Since phenotype is largely determined by underlying genetic changes, it is important to specify the subtype of HbH disease with the terms deletional (deletion of three α-globin genes) and non-deletional (two or three affected α-globin genes, of which one or more have point mutations) [3]. Individuals with deletional HbH disease usually have mild asymptomatic anaemia that remains unsuspected in many cases until an incidental laboratory finding of anaemia prompts diagnostic workup.
In this chapter, we review clinical presentation and management of deletional HbH disease while the more severe form of HbH disease (non-deletional HbH disease) will be discussed separately in the next chapter (Please see Chapter 3: Clinical presentation and management of non-deletional haemoglobin H disease).
Genetic basis of deletional HbH disease
Clinical presentations and complications of deletional HbH disease
Newborn infants diagnosed at birth through a screening programme have asymptomatic perinatal period and infancy. Microcytic, hypochromic anaemia is present at birth with haemoglobin generally at 110-130 g/L. On haemoglobin analysis using high performance liquid chromatography, haemoglobin Bart’s fraction of 25-35% of total haemoglobin can be identified [6, 7]. Haemoglobin follows the expected trend with nadir around 3 months of age (usually staying >75 g/L), following which it slowly increases to reach 85 - 95 g/L by 4 years. After a child reaches puberty, haemoglobin generally is at 100-120 g/L in men and 90 -105 g/L in women [1-3, 6, 8-11].
In those who are identified later in life, laboratory tests also show anaemia, microcytosis, hypochromia, anisocytosis with increase in red cell width (RDW) and target cells while nucleated red blood cells are few or absent on a peripheral blood smear. Such patients may be misdiagnosed with iron deficiency anaemia and prescribed supplemental iron, which can increase the risk of iron overload. However, there is evidence of mild haemolysis with slight increase in bilirubin and reticulocyte count. Haemoglobin electrophoresis demonstrates presence of fast-moving HbH 5-15% of the total haemoglobin. The peaks of HbH and Hb Bart’s are also identified by automatic high-performance liquid chromatography (HPLC) and capillary electrophoresis system, however, the percentage may not be accurately quantitated. HbH inclusion bodies can be visualized with a supravital stain such as methyl violet or brilliant cresyl blue. Genetic testing is essential in every patient to exclude presence of non-deletional HbH disease. Gastrointestinal iron absorption is increased, which leads to a mild iron overload in the 3rd decade or later manifesting as elevation in serum ferritin, but with normal transferrin saturation [3].
Children with deletional HbH disease demonstrate normal growth and development based on their constitutional trajectory, and their physical activity is generally indistinguishable from peers [3]. Skeletal changes that are commonly seen in β-thalassaemia syndromes are not observed in deletional HbH disease. Splenomegaly is either absent or mild [2, 3].
In keeping with the benign disease course, cholelithiasis is observed in 15-20% of adults, though a significant increase in thrombotic and vascular complications is not reported [6]. Women can go through pregnancy without an increase in obstetrical complications or the need for regular transfusion support [6, 13]. An increase in adverse perinatal outcome and foetal growth restriction is reported by some groups [13], though this was not observed in a different series [6]. The risk of haemoglobin Bart’s hydrops foetalis must be considered if the partner has α0 thalassaemia trait. Some adults may develop fatigue, although quality of life has not been formally evaluated in HbH disease [6].
Management of deletional HbH disease
The aim is to provide comprehensive haematology care and follow up to patients with deletional HbH disease at all stages of life, while recognizing that the initial diagnosis may be made in different settings and at any age.
Routine care
The initial clinic visit is used to review complete blood count, electrophoresis, and genetic tests to ensure that results are consistent with deletional HbH disease. DNA testing is strongly recommended in all cases to exclude non-deletional mutants that make the disease course more severe. While routine testing for co-existing G6PD deficiency is not recommended, this should be considered when a patient experiences haemolytic crisis. The patient and family are counselled about the expected mild clinical course. Subsequent visits are conducted every three months for the first year and then every 12 months. A complete blood count with reticulocyte count is obtained at each visit, while bilirubin and ferritin are checked once a year. All childhood vaccinations are given according to the normal schedule and patients should receive the seasonal influenza vaccine. At each visit, height and weight percentiles are checked to document normal growth that is expected in deletional HbH. Folic acid 0.4 to 1 mg per day is recommended to all patients starting around 6 months. Vitamin D status is checked to maintain sufficiency, using supplements if needed. No dietary modifications are needed and there are no specific medications or foods to avoid. In particular, there is no evidence that oxidant drugs should be avoided in the absence of known G6PD deficiency. Adhering to a reduced-iron diet is not necessary, however, supplements containing iron are discouraged unless laboratory tests show presence of iron deficiency. Starting at 10 years of age, the child’s bone mineral density is evaluated by dual-energy X-ray absorptiometry (DXA) every 2–3 years, or more frequently if needed. Maintenance of physical activity and participation in sports is encouraged.
As severe anaemia is rare even during febrile illness, the need for transfusion should be assessed based on the clinical status of the patient. In otherwise uncomplicated situations, it is appropriate to observe the patient and transfuse if the haemoglobin drops <60 g/L in younger children, or <65 g/L in adults. Avoidance of transfusions is a desirable goal in the management of deletional HbH disease in view of the risk of alloimmunization and other complications. Chronic transfusion therapy or splenectomy is not recommended for patients with typical clinical course of deletional HbH disease (Please see Chapter 9: Blood transfusion and Chapter 10: Splenomegaly and splenectomy).
Iron overload
Other complications
The risk of developing gallstones is less than observed in non-deletional HbH disease. Cholecystectomy is recommended in patients with recurrent symptoms attributable to gallstones. The role of echocardiograms to monitor pulmonary artery systolic pressure is not certain as the risk of pulmonary hypertension is very low or none.
Pregnant women with deletional HbH disease should be followed by maternal-foetal medicine due to a higher incidence of adverse foetal outcomes in some regions and the risk of Bart’s hydrops foetalis. They generally do not require additional haematology care during pregnancy. A decline in haemoglobin is anticipated, and an occasional transfusion for worsening of anaemia may be needed, but regular transfusion support is not recommended.
Older patients should be monitored for deterioration in quality of life from fatigue or difficulty in coping at work or the impact of age-related comorbidities.
Genetic counselling
Summary and recommendations
Domain | Management |
---|---|
Frequency of clinic visits | Every 3 months for first 2 years, then annually for life. |
Laboratory testing | Complete blood count, reticulocyte count, liver function: Every 6 months for first 2 years, then annually. Ferritin, transferrin saturation (TSAT): Annually starting at 1 year. TSAT is not needed after 3 years, but should be checked if ferritin >200 ng/mL. |
Febrile illness | Evaluation by paediatrician as for children without HbH disease. Check CBC if severe symptoms or development of pallor or jaundice. |
Transfusions | Regular transfusions are not required. Episodic transfusions are not needed during most febrile illnesses, unless the haemoglobin level drop below 60 g/L in young children or 65 g/L in adolescents and adults. Transfusion may be needed for surgery or other specific indications. |
Red cell phenotyping | Not needed unless there is a need for recurrent transfusions |
Iron overload assessment | Mild to moderate iron overload is observed in the 4th -5th decades of life, earlier in males than females. Check ferritin annually, check liver MRI for liver iron concentration (LIC) if ferritin >200 ng/mL. |
Iron chelation | Start if LIC >5 mg/g dry weight or ferritin >500 ng/mL. Treat until LIC <3 mg/g dry weight and ferritin <300 ng/mL, then stop. Treat at lower level of LIC in presence for specific indications. |
Splenectomy | Not indicated. |
Endocrinology evaluation | If onset of puberty is delayed >2 years or if concern for slow growth. Obtain family history and consider x-ray for bone age. |
DXA scan | Every 3 years starting at 12 years. |
ECHO | Check at 10-12 years to assess for pulmonary artery pressure. If normal, repeat every 3-5 years. |
Pregnancy and genetic counselling | Anticipate mild decline in haemoglobin, but routine transfusions are not needed. Partner testing to evaluate foetal risk for Bart’s hydrops foetalis. |
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- CLINICAL PRESENTATION AND MANAGEMENT OF DELETIONAL HAEMOGLOBIN H DISEASE - Guide...CLINICAL PRESENTATION AND MANAGEMENT OF DELETIONAL HAEMOGLOBIN H DISEASE - Guidelines for the Management of α-Thalassaemia
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