Narrative review of aplastic anemia—the importance of supportive treatment

Introduction

Aplastic anemia (AA) is an acquired or congenital bone marrow failure in the production of all cell lines, without the presence of cancerous infiltrates and fibrosis, leading to pancytopenia. It is a disease that occurs rarely, however, it is fraught with serious prognosis in the absence of adequate treatment. With the development of effective therapies over the years, the prognosis has changed radically, mainly in young people with severe pancytopenia but results of specialist treatment are conditioned by appropriate supportive care.

The incidence in Europe and North America is estimated at 2–3 and 5–6 cases/million/year in Asia. AA can occur at any age, but most cases fall between 15–25 years and over 60 years, without gender or race differences. Its etiology is not sufficiently understood (1,2).

We present the following article in accordance with the Narrative Review reporting checklist (available at http://dx.doi.org/10.21037/apm-20-1957).

Diagnosis and severity of the disease

Acquired AA, resulting from exposure to ionizing radiation, chemicals, drugs with strong myelosuppressive effects, or due to viral infections (e.g., HCV, HIV, herpesviridae), systemic connective tissue disease, blood cancer, thymoma, pregnancy. In most cases, acquired AA is the result of an autoimmune reaction against hematopoietic stem cells (increased cytotoxic activity of T cells and increased production of cytokines that inhibit hematopoiesis by Th1 cells) and stimulation of apoptosis by the Fas/Fas-ligand system. Typical for this disease is the impairment of all hematopoietic lines, which in most cases coexists with anemia, leukopenia and thrombocytopenia (3,4).

Diagnosis of AA is based on the detection of pancytopenia in peripheral blood and in bone marrow trepanobioptate atrophy of normal hematopoiesis, without dysplasia. Bone marrow cellularity does not exceed 25% of age norm. In peripheral blood morphology, mono- or bipenia, erythrocyte macrocytosis, and lymphocyte count within reference limits observed in the early stages of the disease. The severity of AA are classified according to the haematological values (Table 1) (5).

Table 1 Diagnostic criteria for AA based on the results of additional tests
Full table

Clinical presentation

Signs and symptoms depend on the degree of peripheral blood cytopenia. The clinical picture may be dominated by the symptoms of haemorrhagic diathesis related to thrombocytopenia: the presence of characteristic ecchymosis on the skin and a tendency to spontaneously bruise, to bleeding from mucous membranes, bleeding from the nose, from the gums, from the digestive, genital, urinary tract. Patients often have severe atypical infections associated with severe neutropenia. The presence of tonsillitis with the presence of necrotic, ulcerative and aft-like lesions is characteristic. Typical is the lack of response to standard empirical antibiotic therapy. Patients with AA have an increased incidence of severe bacterial and fungal infections (5-7). AA may coexist with nocturnal paroxysmal hemoglobinuria (PNH) or myelodysplastic syndromes (MDS). This relationship may become evident when a patient with AA is observed to have hemolysis or thrombosis or when PNH is transformed into bone marrow hypoplasia. Abnormal blood cells are thought to initiate an immune response that damages hematopoietic stem cells and other hematopoietic precursors (8-10). In one prospective adult study, the PNH cell population in peripheral blood (range: 0.5% to 23.1%) accounted for 68% of 122 patients with newly diagnosed AA (11). Chromosomal abnormalities characteristic of MDS are observed in a smaller number of patients with AA (estimated 5–15%). Dysplastic hematopoietic stem cells in MDS may undergo immune depletion by T cells and lead to bone marrow hypoplasia, characteristic of AA. This subgroup of MDS patients presents hypoplastic bone marrow that has some features in common with AA/PNH (12,13).

Differential diagnosis of AA also includes other causes of pancytopenia, such as megaloblastic anemia, bone marrow infiltration (myelofibrosis), various cancers, sequestration/redistribution (hypersplenism), large granular lymphocytic leukemia or acute myeloid leukemia (AML). Physical examination, peripheral blood smear assessment and bone marrow biopsy allow for the diagnosis of these disorders and exclusion of AA, but more specialized tests (cytogenetic or molecular diagnostics) are often required (5,6).

Managment of patients with AA

The management of patients with AA depends on the cause and severity of pancytopenia. In patients with acquired AA, the therapeutic strategy is different compared to patients with congenital AA. In current therapy recommendations, its selection depends on the severity of symptoms, the patient’s age, the availability of a compatible donor, and comorbidities. For patients under 50 years of age with very severe and severe plastic anemia (VSAA/SAA), allogeneic hematopoietic stem cell transplantation (allo-HSCT) from a matched sibling donor remains standard first-line therapy, while for other patients with VSAA/SAA without a matched sibling donor, immunosuppressive therapy (IST) with antithymocyte globulin (ATG) and cyclosporin A (CsA) using eltrombopag, which has a beneficial effect on treatment outcomes. Appropriate supportive treatment is an integral element of therapy in patients with AA (14-16).

Supportive care

Patients after IST and allo-HSCT treatment require long-term symptomatic management including platelet cell concentrate and red blood cell concentrate transfusions and treatment of infectious complications. In very elderly people or with moderate pancytopenia, these interventions may be the only therapy used (17). For any patient for allo-HSCT, transfusions should be used selectively to reduce the risk of immunization to donor antigens. Blood preparations from siblings or a family donor should be carefully avoided in order to minimize the risk of transplant failure caused by an immune response to donor antigens (18). Basically, low-leukocyte and irradiated products (25–30 Gy dose) are used to reduce, among others risk of febrile post-transfusion reactions, likelihood of alloimmunity, as well as prevention of cytomegalovirus (CMV) infection (19,20).

The indication for the administration of red blood cell concentrate transfusions is a decrease in hemoglobin (HGB) concentration below 6 g/dL and prophylactic platelet transfusions should be performed when the patient’s platelet count (PLT) drops below 10×10⁹/L. In the presence of concomitant complications, such as fever or bleeding, the PLT number should be maintained >20×10⁹/L to reduce the risk of life threatening haemorrhage (21).

Chelating treatment

Patients with AA who receive multiple red blood cell transfusions are at risk of iron overload and associated organ damage (22). Transfusion of one unit of red blood cell concentrate provides about 150–200 mg of iron, while the daily physiological loss is about 1.5 mg. Symptoms of iron storage (secondary hemochromatosis) may occur after transfusion of 10–20 units of red blood cell concentrate. Iron overload is assessed based on serum ferritin, magnetic resonance imaging of the heart and liver, and liver biopsy histopathology. Patients undergoing allo-HSCT or IST who have responded to treatment and demonstrate signs of secondary hemochromatosis can be treated by phlebotomy (23,24). There are no specific guidelines for phlebotomy after allo-HSCT in patients with AA. According to generalny accepted principles, chelating treatment is needed if the ferritin concentration is in the range 1,000–1,500 µg/L, which corresponds to the iron content: 7 mg/g dry weight of liver tissue (25). It should be emphasized that the benefits of chelating therapy in the group of patients with AA are generally unknown and no guidelines for its use are available. The most commonly used drug is deferoxamine (Desferal), administered at an initial dose of approx. Forty mg/kg/24 h in long-term (at least 10 h) subcutaneous or intravenous drip for 5 days a week. Subcutaneous administration is usually not possible in patients with SAA due to comorbid thrombocytopenia (26). Ferritin levels should be monitored every few weeks and the dose should be adjusted accordingly. Some observations suggest a possible benefit of chelation therapy with deferasirox (Exjade), a chelating drug for oral use. To reduce iron overload, it is used chronically at a dose of 30 mg/kg/day, and preventively at 20 mg/kg/day. In a prospective 1-year study on the evaluation of iron chelation in patients receiving deferasirox (Exjade), its efficacy and safety were assessed in 116 patients with AA.

Median ferritin levels were reduced from 3,254 to 1,854 ng/mL after 1 year in both untreated and previously treated patients. The decrease in mean alanine aminotransferase over 1 year significantly correlated with the decrease in serum ferritin (27). In another report of 72 AA patients receiving deferasirox, transfusion independence was observed in 46% of patients with chronic non-severe AA, not undergoing IST therapy, and in 40% of patients who received concomitant IST. In addition to reducing iron overload, deferasirox had an effect on haematological parameters in some patients with AA (increased PLT and HGB), however, further studies are needed (28). Registered in Europe in 2018, the oral chelating drug Deferiprone (Ferriprox) is not recommended in AA, among others due to induction of neutropenia in an unknown mechanism.

Prevention/treatment of infection

There are no specific guidelines for the prophylactic antibacterial or antifungal treatment of patients with VSAA/SAA. Some experts suggest the use of prophylactic antifungal therapy with voriconazole or posaconazole in individuals with ANC (absolute neutrophil count) <500 cells/µL based on better survival after use in patients after HSCT with acute leukemia (17,29). The use of preventive antibiotic therapy is controversial, its use in some patients reduces mortality, but also increases the risk of drug resistance and causes adverse changes in the intestinal microflora; in addition, some antibacterial drugs myelosuppressive. During lymphopenia after ATG treatment, prevention of pneumonia of the etiology of Pneumocystis jirovecii should be used, choosing an alternative drug for trimethoprim-sulfamethoxazole due to its myelosuppressive effect. Antimicrobial prevention with quinolone antibiotics in patients with VSAA may reduce the risk of Gram-negative sepsis, but routine use of antibiotics in patients with higher neutrophil count not recommended to reduce the development of antibiotic resistance (30). A patient with AA with fever requires immediate hospitalization and treatment without waiting for the results of bacteriological tests. Initially, an aminoglycoside antibiotic is administered in combination with β-lactam active against Pseudomonas aeruginosa. If the patient has fever for 2 days despite antibiotic therapy, suspected fungal infection and immediately start intravenous antifungal Aspergillus (amphotericin) or voriconazole or caspofungin. Fungal cause should be suspected especially of inflammatory changes in the lungs or sinusitis (31). In the absence of response to antibiotic and antifungal agents, short-term treatment with granulocyte colony-stimulating factor (G-CSF) should be considered. Routine use of G-CSF outside of eutropenic fever episodes is controversial. For patients not responding to anti-infective therapy, a granulocyte concentrate may be used. So far, however, the clear benefits of their use have not been confirmed (32). The benefits and risks of vaccines in AA also remain controversial because of the risk of immune activation, and some AA guidelines do not recommend vaccination except for patients after allo-HSCT. Vaccination efficacy for AA patients also remains controversial due to the risk of immune activation, and some AA guidelines do not recommend vaccination except for patients after allo-HSCT (6).

The role of growth factors

The concentration of hematopoietic cytokines (growth factors) are quite high in patients with AA and are not generally used as part of routine management. Exceptions include the possibility of using G-CSF in patients with frequent or severe infections, and the use of thrombopoietin receptor agonists (i.e., Eltrombopag) initiating signaling cascades that induce proliferation and differentiation of megakaryocytes from bone marrow progenitor cells. Eltrombopag is recommended for patients with refractory disease, although it is currently also recommended for first-line treatment with IST. In contrast, G-CSF is not a standard therapy in AA. There is no evidence that G-CSF corrects a hematopoietic stem cell defect in AA (33,34). In addition, the use of G-CSF in IST was not associated with an improvement in response or survival rates. Another issue related to G-CSF administration is the fear that it may promote the development or evolution of a clonal cell population with cytogenetic abnormalities or mutations that may predispose the patient to the development of myelodysplasia or AML. The role of G-CSF in clonal evolution (if present) is difficult to determine because patients with acquired AA have an elevated baseline risk of clonal disorders. Similarly, erythropoietin is not used in AA therapy because there are not enough erythropoietic precursor cells in the bone marrow to be effective (35).

Conclusions

AA is a rare, life-threatening syndrome of bone marrow failure. Transplant-based therapies or IST recommended depending on the severity the disease and the patient’s age is crucial but the very important role of supportive treatment should be appreciated. Improved prognosis in patients with AA is associated with greater effectiveness of supportive therapy. However, there are no clear recommendations. Primarily, appropriate treatment of infections in neutropenic patients should be instituted. Intravenous broad-spectrum antibiotic therapy in combination with antifungal and antiviral agents is recommended. Treatment of severe infections with growth factors such as G-CSF is also useful in AA patients. They provide a transient increase in the number of granulocytes needed to control the infection. Erythropoietin is ineffective, therefore the use of its recombinant preparations is not justified. Supportive treatment should also include the transfusion of leukocyte-depleted and irradiated blood components, platelet and red blood cell concentrates, necessary in causally treated patients, and in elderly patients with anemia and thrombocytopenia, in whom aggressive treatment is contraindicated. Multiple blood cell transfusions are associated with iron overload, hence the need to monitor ferritin levels and implement appropriate iron overload treatment. Comprehensive therapy of a patient with AA, taking into account his causal treatment and the necessary supportive treatment, depending on the clinical condition, will guarantee the achievement of therapeutic success.

Acknowledgments

Funding: None.

Footnote

Reporting Checklist: The authors have completed the Narrative Review reporting checklist. Available at http://dx.doi.org/10.21037/apm-20-1957

Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at http://dx.doi.org/10.21037/apm-20-1957). The authors have no conflicts of interest to declare.

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