Acute myeloid leukemia (AML) is the most common leukemia among the adult population and accounts for about 80% of all cases. It is characterized by clonal expansion of immature “blast cells” in the peripheral blood and bone marrow resulting in ineffective erythropoiesis and bone marrow failure. With recent advancements in the management guidelines, the cure rates have increased up to 15% in patients older than 60 years and about 40% in patients below 60 years of age. Despite advancements in therapeutic regimens, the prognosis remains very poor in the elderly population.
In the past, French-American-British system classified AML into eight subtypes, FAB M0 to M7 which are as follows:
In 2016, World Health Organization (WHO) revised the classification and categorized it into AML with recurrent genetic abnormalities, AML with myelodysplasia-related changes, therapy-related myeloid neoplasms, NOS, myeloid sarcoma, myeloid proliferations related to Down syndrome.
AML with recurrent genetic abnormalities includes-
AML not otherwise specified (NOS) includes:
Based on the etiology of the AML, it can be categorized into de novo AML, Secondary AML (s-AML) which evolves from prior MPD or MDS and Therapy related AML (t-AML) following exposure to chemotherapeutic agents or radiation therapy or toxins.
The number of new cases among men and women per year is about 4.2 per 100,000 population. The incidence is over 20,000 cases per year in the United States. The average age at the time of diagnosis is about 65 years. It is more prevalent among non-Hispanic whites. Males have more predominance compared to females with a ratio of 5:3.
AML is characterized by mutations of the genes involved in hematopoiesis. These mutations result in a clonal expansion of undifferentiated myeloid precursors (blasts) in the peripheral blood and bone marrow resulting in ineffective erythropoiesis and bone marrow failure. Recent studies also revealed that it could arise from a series of recurrent hematopoietic stem cell genetic alterations which get accumulated with age. In most of the cases, AML appears as de novo in a previously healthy person. The exact cause of genetic mutations is unclear, but few risk factors include exposure to radiation, chemotherapeutic agents, and smoking. AML can also evolve from myeloproliferative disorders (MPD), myelodysplastic syndrome (MDS), paroxysmal nocturnal hemoglobinuria, and aplastic anemia. Familial causes of genetic mutations should also be considered.
AML is a highly heterogeneous disease with a variable prognosis. It can result from genetic mutations, chromosomal translocations, or changes in molecular levels. About 97% of the cases have been studied to have genetic mutations. Despite its heterogeneity, it can be categorized into favorable, intermediate, or adverse-risk groups based on the cytogenetics. The prognosis within these categories varies widely. The chromosomal translocations t (8;21), t (15;17) or inv (16) have a favorable prognosis with 3-year overall survival (OS) rate of about 66% and 33% in patients younger than 60 and older than 60 years of age respectively. People with t (9;11), monosomy 5 or 7 and normal cytogenetics (CN-AML) have an intermediate risk. A high risk of treatment failure and death was noted in people with t (6;9), inv (3). or 11q changes. Presence of c-KIT mutations in patients with t (8;21) increases the risk of relapse and decreases the OS.
About 25% to 30% of AML patients have Nucleophosmin 1 (NPM1) mutations. This is the most common mutation found in AML and has a female predominance. Clinically, the mutation has monocytic morphology and in the absence of FMS-like tyrosine kinase 3 or FLT3-ITD, predicts favorable OS. NPM1 mutations are chemosensitive to intensive chemotherapy in both young and old patients. It is associated with other recurrent genetic abnormalities such as FLT3-ITD (40%), FLT3-TKD (10% to 15%) and IDH mutations (25%).
FLT3 is strongly expressed in hematopoietic stem cells with important roles in cell survival and proliferation. Mutations involving the Internal tandem duplications (ITD) and the tyrosine kinase domain (TKD) of the FLT3 gene have been found in 20% of AML cases and 30% to 45% of CN-AML patients. Both the mutations activate FLT3 signaling, promoting blast proliferation. Patients with FLT3 mutations can have severe leukocytosis. FLT3-ITD mutations have been associated with increased risk of relapse. Tyrosine kinase inhibitors (TKI) are being tested in FLT3 mutated AML patients. Unfortunately, when used alone, TKIs showed only a transient reduction of blasts, and even if initially effective, subsequent acquisition of secondary mutations induces resistance over time.
Runt-related transcription factor (RUNX1) is an essential component of hematopoiesis. It is also known as AML1 protein or core-binding factor subunit alpha-2 (CBFA2). RUNX1 is located at chromosome 21 and is frequently translocated with the ETO (Eight Two One)/RUNX1T1 gene located on chromosome 8q22, creating an AML-ETO or t(8;21)(q22;q22) AML which is seen in about 12% of AML cases. They are commonly associated with trisomy 13, trisomy 21 and show resistance to standard induction therapy.
Mutations in isocitrate dehydrogenase (IDH) are oncogenic. They are seen in 15% to 20% of all AML cases and 25% to 30% of patients with CN-AML. More commonly seen in older individuals.
TP53 mutations are associated with very poor prognosis and are resistant to chemotherapy.
Due to ineffective erythropoiesis and bone marrow failure, patients experience a variety of symptoms including recurrent infections, anemia, easy bruising, excessive bleeding, headaches, and bone pains. Depending on the degree of anemia, they can experience generalized weakness, fatigue, shortness of breath and chest tightness. Physical examination can reveal bruises, pallor, hepatomegaly, and splenomegaly. Lymphadenopathy is rare. DIC is common in patients with APL.
AML should be suspected in anyone with unexplained cytopenias (decreased cell count of white blood cells, hemoglobin or platelets), the presence of circulating blast cells in the peripheral blood, easy bruising or bleeding or recurrent infections. In some cases, they can present with renal failure secondary to tumor lysis syndrome which is an oncologic emergency.
Presence of at least 20% blasts in the bone marrow or peripheral blood is diagnostic of AML. It can be diagnosed with bone marrow aspiration and biopsy. Additional diagnostics include flow cytometry, cytogenetics, and fluorescence in situ hybridization (FISH). Presence of Auer rods (clumps of azurophilic granules resembling elongated needles) is diagnostic of AML. Auer rods can be seen in many subtypes of AML, but abundantly seen in APL.
Oncologic emergencies associated with AML include neurologic or respiratory distress due to leukostasis, APL-induced DIC, tumor lysis syndrome, and central nervous system (CNS) involvement.
Individuals who achieve complete remission (CR) with a blast count of less than 5% in the bone marrow after induction therapy tend to have increased survival. Despite induction therapy, there is still minimal residual disease for which consolidation therapy is initiated to prevent any risk of relapse by eliminating the residual disease. Despite many advances, the mainstay of therapy remains a combination of cytarabine-based and anthracycline-based regimens. For eligible candidates, allogeneic stem cell transplantation should be considered.
This is a standard of care for younger patients, elderly with low risk of treatment-related mortality (TRM), and ones with favorable and intermediate-risk factors. The induction therapy is highly toxic to bone marrow causing pancytopenias and bleeding complications, gastrointestinal system issues, kidney failure due to tumor lysis syndrome, and electrolyte disturbances. It may take up to 1 month for the cell counts to recover, and these patients need aggressive monitoring to manage any complications. Baseline cardiac function should be estimated before initiating the treatment, and the ejection fraction (EF) needs to be monitored carefully, as anthracyclines can cause significant cardiotoxicity. Studies have shown greater benefit with higher doses, but toxicities may limit its use. It consists of "7+3" regimen that includes continuous infusion of cytarabine for seven days along with anthracycline on days 1 to 3. Patients with the refractory disease have shown higher CR and similar overall survival (OS) by using higher doses of cytarabine or by using a combination of fludarabine, cytarabine, and idarubicin. Despite TRM in elderly, chemotherapy has shown to improve the survival rate among elderly (older than 65 years). Decitabine, a methylating agent, used in the treatment of MDS, has shown improvement in OS in the elderly population. The response should be evaluated by repeating the bone marrow aspirate and biopsy after 2 weeks of initiating the induction therapy. Reinduction can be done with high dose cytarabine or by combining with etoposide if there is persistent evidence of disease. About 60% to 80% de novo AML will achieve CR with induction therapy.
Even before the diagnosis, if APL is suspected, then the treatment should be initiated with all-trans retinoic acid (ATRA), as early use of ATRA decreases the risk of disseminated intravascular coagulation (DIC) and mortality associated with it.
After achieving CR with induction therapy, consolidation therapy is initiated with high dose cytarabine, called HiDAC and hematopoietic cell transplantation (HCT). HCT is preferred in individuals with less than 60 years of age with intermediate or unfavorable prognosis. If a donor is available, then allogenic HCT is preferred over autologous HCT. They should be Monitored for signs or symptoms of acute or chronic graft versus host disease (GVHD).
Ongoing studies with Fms-like tyrosine kinase 3 (FLT3) inhibitors, IDH inhibitors, and immune therapies.
By assessing the prognostic factors, clinicians can decide whether a standard therapy or more intense therapy would be helpful in maintaining CR and OS rates. The prognostic factors are chromosomal abnormalities (favorable abnormalities include t(8;21), t(15;17), inversion of chromosome 16), genetic mutations (NPM1 gene has a favorable prognosis, and FLT3 gene has unfavorable prognosis). Worse outcomes have been noted with older age, white blood cell count greater than 100,000 at the time of diagnosis, s-AML, t-AML, the presence of leukemic cells in the central nervous system (CNS).
Recent techniques such as PCR and flow cytometry can detect the presence of minimal residual disease among CR patients. Persistently elevated levels of RUNX1-RUNX1T1 despite induction therapy in patients with t(8;21) AML are associated with an increased incidence of relapse.
AML is a common hematological malignancy in adults. Despite many advances, the malignancy still carries a poor prognosis. Hence, it is best managed by a multidisciplinary team that includes a hematologist, oncologist. internist, pathologist, and an intensivist. The oncology nurse is vital for treatment administration and monitoring for potential complications. The pharmacist should educate the patient on potential adverse effects of the potent drugs used to treat this malignancy. The primary care physician should educate the patient on personal hygiene, hand washing, and immunization. Overall, the life expectancy has increased slightly but most patients have a markedly shortened lifespan.
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