Targeted Therapies
In GeneReviews, a targeted therapy is one that addresses the specific underlying mechanism of disease causation (regardless of whether the therapy is significantly efficacious for one or more manifestation of the genetic condition); would otherwise not be considered without knowledge of the underlying genetic cause of the condition; or could lead to a cure. —ED
Beta-Thalassemia Major
Hematopoietic stem cell transplant (HSCT) represents an alternative to red blood cell transfusions and iron chelation therapy. If HSCT is successful, iron overload may be reduced by repeated phlebotomy, thus eliminating the need for iron chelation.
Gene therapy is an emerging alternative to HSCT for curative therapy. Essentially a genetically modified autologous HSCT, stem cells are collected from an affected individual, and gene-editing techniques are used to modify the stem cells ex vivo. Individuals then undergo conditioning chemotherapy before infusion of genetically modified stem cells. Gene editing can either introduce a functional beta globin chain or silence BCL11A to induce gamma globin chain production.
Betibeglogene autotemcel (beti-cel), a
gene addition via a lentiviral vector, was recently approved by the FDA. Beti-cel has been shown to yield transfusion independence in 91% of individuals who are
not homozygous for β
0 alleles [
Locatelli et al 2022b]. Response rates for β
0/β
0 individuals was slightly lower, at 86%, although sample size was small [
Langer & Esrick 2021]. Individuals who achieved transfusion independence were eventually able to stop iron chelation and sustain a normal iron profile [
Thompson et al 2021]. Acute myeloid leukemia (AML) was diagnosed in two individuals with sickle cell disease who received beti-cel, raising concerns of potential toxicity, but neither case was caused by insertional mutagenesis. Myelodysplastic syndrome or AML have not been reported in any individuals with β-thalassemia treated with
gene therapy, including beti-cel [
Hsieh et al 2020].
Exagamglogene autotemcel (exa-cel), a
BCL11A knockdown using CRISPR, was recently approved by the FDA. Exa-cel has shown promise with transfusion independence in more than 95% of individuals reported thus far [
Frangoul et al 2021,
Locatelli et al 2022a].
Supportive Care
Beta-Thalassemia Major
Red blood cell transfusions, usually every two to four weeks with a pretransfusion hemoglobin (Hb) concentration goal of 9.5-10.5 g/L, are needed to correct the anemia, suppress ineffective erythropoiesis, and inhibit increased gastrointestinal absorption of iron.
Before starting red blood cell transfusions, the following are recommended: hepatitis B vaccination; extensive red blood cell antigen typing, including Rh, Kell, Kidd, and Duffy; and serum immunoglobulin determination, which detects individuals with IgA deficiency, who need special (repeatedly washed) blood unit preparation before each transfusion.
Chelation therapy can prevent transfusional iron overload.
Deferoxamine B (DFO) is administered five to seven days a week by 12-hour continuous subcutaneous infusion via a portable pump. Recommended dosage depends on the individual's age, transfusion volume, and the serum ferritin concentration. Young children start with 20-30 mg/kg/day, increasing to up to 40 mg/kg/day after age five to six years. The maximum dose is 50 mg/kg/day after growth is completed. The dose may be reduced if serum ferritin concentration is low. By maintaining the total body iron stores below critical values (i.e., hepatic iron concentration <7.0 mg per gram of dry weight liver tissue), long-term organ damage can be prevented. Ascorbate repletion (daily dose ≤100-150 mg) increases the amount of iron removed after DFO administration. Side effects of DFO are more common in the presence of relatively low iron burden and include ocular and auditory toxicity, growth restriction, and, rarely, kidney impairment and interstitial pneumonitis. DFO also increases susceptibility to Yersinia infections. The major drawback of DFO is difficulty with adherence to subcutaneous administration, which can be particularly difficult with younger children.
Deferiprone, an oral chelator, is administered in a dose of 75-100 mg/kg/day. The main side effects of deferiprone include arthropathy, gastrointestinal symptoms, and, above all, neutropenia and agranulocytosis [
Galanello & Campus 2009], which demand close monitoring. A prospective study showed that deferiprone is more cardioprotective than DFO; compared to those treated with DFO, individuals treated with deferiprone have better myocardial MRI pattern and less probability of developing (or worsening pre-existing) cardiac disease [
Pennell et al 2006]. Different formulations exist for administration two or three times per day, with the older and more readily available formulation requiring three times per day administration. Frequency of administration can be a barrier to adherence.
Deferasirox (DFX) is a once-daily oral monotherapy for the treatment of transfusional iron overload. It is effective in adults and children and has a defined safety profile that is clinically manageable with appropriate monitoring. The most common treatment-related adverse events are abdominal pain, nausea, vomiting, diarrhea, and a mild, nonprogressive increase in serum creatinine concentration [
Cappellini 2008]. Monitoring for proteinuria is required. Kidney failure, liver failure, and gastrointestinal hemorrhage have been reported. Provided adequate doses are given, there is a good response to DFX across the full range of baseline liver iron concentration values. Prospective data demonstrate the efficacy of DFX in improving myocardial T
2* and in maintaining a normal left ventricle ejection fraction [
Pennell et al 2012,
Pennell et al 2014]. DFX has not been evaluated in formal trials for affected individuals with symptomatic heart failure or low left ventricle ejection fraction.
Combination therapies. The combination of DFO and deferiprone has been effective in individuals with severe iron overload. Retrospective, prospective, and randomized clinical studies have shown that iron chelation with combined DFO and deferiprone rapidly reduces myocardial iron deposition, improves cardiac and endocrine function, reduces liver iron and serum ferritin concentration, reduces cardiac mortality, and improves survival; toxicity is manageable [
Tanner et al 2007,
Galanello et al 2010].
An open-label single-arm prospective Phase II study evaluated combination DFX-DFO in individuals with severe transfusional myocardial iron deposition followed by optional switch to DFX monotherapy when achieving myocardial T
2* >10 ms; this approach rapidly decreased liver iron accumulation in individuals with high liver iron load and decreased myocardial iron overload in one third of individuals [
Aydinok et al 2015].
Luspatercept is a transforming growth factor beta (TGF-β) superfamily ligand trap. Inhibition of TGF-β reduced Smad 2/3 signaling, resulting in reduced ineffective erythropoiesis and apoptosis and increased survival of erythroid precursors. Luspatercept reduced transfusion volume by at least 33% in 21.4% of individuals with transfusion-dependent thalassemia (TDT) compared to 4.5% for placebo [Cappellini et al 2020]. Common side effects included transient arthralgias and headaches. A small incidence (3.6%) of both arterial and venous thrombosis was reported, exclusively in individuals with prior splenectomy. While this reflects an exciting breakthrough as the first therapy to reduce the frequency of red blood cell transfusions, the inability to eliminate the need for transfusions, low response rate, and subcutaneous administration every three weeks, which may not align with the individual's transfusion schedule, has resulted in limited uptake in clinical practice. Selected individuals with TDT benefit from a trial of luspatercept, though lack of response should prompt discontinuation.
Venous thromboembolism (VTE) occurs at an increased rate in β-thalassemia major even in spleen-intact individuals, but splenectomy is an additional significant risk factor [Cappellini et al 2000]. Indefinite anticoagulation at prophylactic dosing after an initial therapeutic course is indicated in individuals with unprovoked VTE. Individuals with provoked VTE can be considered for discontinuation, but the significant baseline risk should be considered even in individuals with provoked clot.
Cholelithiasis. Cholecystectomy should be performed in those with biliary colic. Symptoms will not resolve without surgery, and individuals will be more difficult to manage if they develop cholecystitis, as this will likely also worsen hemolysis and anemia concurrently.
Osteoporosis treatment includes hormonal replacement, red blood cell transfusions and iron chelation, vitamin D supplementation, and regular physical activity. Sufficient evidence exists to support the use of bisphosphonates in the management of β-thalassemia-associated osteoporosis (to prevent bone loss and improve bone mineral density). Further research is warranted to establish anti-fracture efficacy and long-term safety of bisphosphonates [Giusti 2014]. Denosumab and strontium ranelate have each been evaluated in only a single study, and there are no data on the effects of anabolic agents [Chavassieux et al 2014, Yassin et al 2014]. Since the origin of bone disease in β-thalassemia is multifactorial and some of the underlying pathogenic mechanisms are still unclear, further research in this field is needed to allow for the design of optimal therapeutic measures [Skordis & Toumba 2011, Dede et al 2016].
Beta-Thalassemia Intermedia
The need for and timing of splenectomy is highly variably. Many individuals will not develop significant splenomegaly until adolescence or adulthood. Indications for splenectomy include the severity of anemia (e.g., splenectomy to avoid initiation of transfusions) and symptoms from the mass effect of splenomegaly. For individuals with other indications to initiate red blood cell transfusions, splenectomy may not be needed or preferred. Deferring splenectomy during early childhood is recommended, if the degree of anemia allows, due to the increased risk of infection and sepsis in infants and young children. Splenectomy also increases the risk of venous thromboembolism and pulmonary hypertension. The decision to proceed to splenectomy should be made with a clinician experienced in β-thalassemia management and alternative approaches.
Folic acid supplementation is recommended.
Luspatercept is not yet FDA approved for individuals with non-transfusion-dependent thalassemia (NTDT) (including β-thalassemia intermedia) at the time of writing. However, clinical trial data has shown that 77% of individuals given luspatercept had a rise of at least 1 g/dL of Hb [Taher et al 2022]. For individuals with symptomatic anemia, this may become a therapeutic option in the near future.
Development of extramedullary erythropoietic masses is an indication to initiate chronic red blood cell transfusion therapy, as suppression of ineffective erythropoiesis is paramount. Alternative approaches such as radiotherapy may transiently ameliorate a mass effect but will not address the underlying cause nor prevent future growth of erythropoietic masses. Extramedullary erythropoietic masses are usually paraspinal, and the risk of nerve impingement and neurologic damage requires long-term control.
Hydroxyurea has a limited treatment role in individuals with β-thalassemia intermedia. It may increase Hb levels by increasing hemoglobin F (HbF) [Levin & Koren 2011]. However, few individuals derive significant benefit. A retrospective study found no pulmonary hypertension in 50 individuals with β-thalassemia intermedia treated with hydroxyurea for seven years [Karimi et al 2009, Taher et al 2010]. Individuals who are compound heterozygous for a β-thalassemia HBB variant and hemoglobin E (HbE) are more likely to benefit, with a clinically meaningful rise in Hb (estimated 1.3 g/dL rise in 40% of individuals) [Singer at al 2005, Algiraigri & Kassam 2017].
Individuals with β-thalassemia intermedia may develop iron overload from increased gastrointestinal absorption of iron or from occasional transfusions; chelation therapy with deferasirox has been demonstrated to be safe and effective in persons age ten years or older with a liver iron concentration ≥5 mg per gram of dry weight liver tissue or serum ferritin ≥800 ng/mL (thresholds after which the risk of serious iron-related morbidity is increased) [Taher et al 2012]. The need for chelation therapy is often intermittent due to slowly progressive iron loading or after periods of intensive transfusion such as prolonged infection or pregnancy.
Cardiac disease. For individuals with evidence of iron loading in the liver, MRI to assess myocardial iron deposition and assessment of cardiac function is vital. Iron chelation should be initiated or increased when cardiac iron deposition is identified. Deferiprone is especially effective in chelating cardiac iron and should be used alone or in combination with another chelator depending on the extent of iron loading [Belmont & Kwiatkowski 2017]. If cardiac iron deposition is rapidly addressed, preserved cardiac function is expected. If cardiac iron is controlled or prevented, additional cardiac therapy is not needed for thalassemia.
Cholelithiasis is common due to the formation of pigment gallstones in the setting of chronic hemolysis. Cholecystectomy is common and should not be deferred if biliary colic is present. There is no expectation of resolution without surgery, and individuals will be more difficult to manage if they develop cholecystitis, as this will likely also worsen hemolysis and anemia concurrently.
Osteoporosis treatment includes hormonal replacement, red blood cell transfusions and iron chelation, vitamin D supplementation, and regular physical activity. Sufficient evidence exists to support the use of bisphosphonates in the management of β-thalassemia-associated osteoporosis (to prevent bone loss and improve bone mineral density). Further research is warranted to establish the anti-fracture efficacy and long-term safety of bisphosphonates [Giusti 2014]. Denosumab and strontium ranelate have each been evaluated in only a single study, and there are no data on the effects of anabolic agents [Chavassieux et al 2014, Yassin et al 2014]. Since the origin of bone disease in β-thalassemia is multifactorial and some of the underlying pathogenic mechanisms are still unclear, further research in this field is needed to allow for the design of optimal therapeutic measures [Skordis & Toumba 2011, Dede et al 2016].
Leg ulcers. Red blood cell transfusion will help in healing. Recurrent leg ulcers are an indication for chronic transfusion therapy. Emerging therapies to raise hemoglobin may be attempted as an alternative.
Pulmonary hypertension is a vital consideration in β-thalassemia intermedia, especially for asplenic individuals. If pulmonary pressures are elevated or ambiguous on transthoracic echocardiogram, referral to a pulmonary hypertension specialist and initiation of chronic red blood cell transfusions is recommended [Fraidenburg & Machado 2016, Pinto et al 2022].
Venous thromboembolism
(VTE) occurs even in spleen-intact individuals, but splenectomy is an additional significant risk factor [Cappellini et al 2000]. Indefinite anticoagulation at prophylactic dosing after an initial therapeutic course is indicated in individuals with unprovoked VTE. Individuals with provoked VTE can be considered for discontinuation of anticoagulation, but the significant baseline risk of VTE should be considered even in individuals with a provoked clot.