General disease information
Acute myeloid (or nonlymphocytic) leukaemia (AML) is a malignant disease that arises within the haematopoietic system. AML usually originates from the bone marrow, where the blood cells are produced. It is characterised by an overproduction of impaired white blood cells.
Healthy blood cells reproduce and regenerate at a normal, balanced rate. They undergo a complex maturation process. AML interferes with this process:
The white blood cells (leukocytes) are unable to mature into functional cells and instead multiply rapidly and uncontrollably. This disturbs normal blood cell formation, so that healthy white blood cells, red blood cells (erythrocytes), and platelets (thrombocytes) can no longer be produced to the extent that is necessary.
Anaemia, infections, and bleeding tendencies can result and may be the first signs of acute leukemia. Since AML is not limited to one specific region of the body, but can spread from the bone marrow into the blood and the lymphatic system, it can affect all organs and organ systems and is therefore – like all leukaemias – known as a malignant systemic disease.
AML progresses rapidly. The spread of leukaemia cells and the resulting damage to other body parts can cause serious diseases, which –without the appropriate treatment – are lethal within a few weeks or months.
Incidence
Comprising about 20 % of childhood leukaemia, acute myeloid leukaemia (AML) is, following acute lymphoblastic leukaemia (ALL), the second most frequent leukaemia in children and adolescents. AML accounts for about 4.5 % of all cancers in this age group.
According to the German Childhood Cancer Registry in Mainz, about 80 children and adolescents aged between 0 and 14 years are newly diagnosed with AML every year. Counting all paediatric patients up to 18 years of age (i.e. before their 18th birthday), the incidence is about 110 new diagnoses per year.
In general, AML can occur at any age. The frequency of childhood AML is highest during the first two years of life, with boys being slightly more affected than girls. After that, incidence decreases and remains stable throughout childhood. It shows a mild increase again during adolescence. During adulthood, and particularly beyond age 55, there is a dramatic increase in the incidence of AML.
Types of acute myeloid leukaemia
AML is caused by a malignant transformation of immature “myeloid cells”. These are blood precursor cells in the bone marrow, which finally develop either into red blood cells (erythrocytes), certain groups of white blood cells (leukocytes like granulocytes or monocytes), or platelets (thrombocytes), depending on which kind of precursor myeloid cell is involved.
AML is mainly characterised by a malignant transformation of granulocyte precursor cells (so-called myeloblasts). However, AML can derive from any immature myeloid cell, i.e. from monocytes, young red blood cells or platelets, and even from the very young precursor (stem) cell of all of them. Furthermore, the development of immature into mature blood cells of any kind comprises several developmental stages, each of which can be affected by malignant transformation.
This is why there are different forms of AML, such as acute myeloblastic, monocytic, erythroid, or megacaryocytic leukaemia and many more, including various mixed forms.
Historically, the classification of AML was mainly based on how the cells looked like (“morphology”) under the microscope, and which bone marrow precursor cell they had derived from. Today, subsets of AML are also defined by the alterations that can be found in the genetic material (cytogenetic characteristics) of the malignant cells.
Good to know: Various subtypes of childhood AML have been characterised so far, the courses and prognoses of which can differ significantly. Current treatment strategies for children and adolescents with AML consider these different subtypes. Therefore, children and adolescents with AML do not all receive the same treatment.
Causes
The causes of acute myeloid leukaemia (AML) are largely unknown. It is known so far that the disease arises from the malignant transformation of certain (myeloid) precursor blood cells in the bone marrow, and also, that this transformation can be associated with genetic alterations of these cells.
Why these genetic alterations exist and why they cause the disease in some children but not in others, remains to be discovered. Most certainly, AML is caused by a specific combination of many genetic factors, that have not yet been identified.
It is known that children with certain inherited or acquired immunodeficiencies as well as young patients with chromosomal abnormalities (such as Down syndrome or Fanconi anaemia) have a higher risk of developing acute leukaemia than their healthy peers.
Also (prenatal exposition to) ionising irradiation or X-ray and to certain genotoxic chemicals and drugs, prenatal exposition to parental nicotine or alcohol abuse, and maybe certain viruses have been reported to play a role in the development of leukaemia. However, for most of the patients, no specific risk-factor for the development of AML has been identified yet.
Symptoms
The health problems (symptoms) caused by of most children and adolescents with AML develop within only a few weeks. They mainly occur due to the increase of malignant cells within the bone marrow as well as their spread into other organs and tissues. The uncontrolled production of leukaemia cells in the bone marrow increasingly suppresses the production of normal blood cells.
Children and adolescents suffering from AML initially experience general symptoms such as fatigue, pain, and pallor. This is due to the lack of red blood cells (anaemia), the function of which it is to carry oxygen to cells throughout the body.
The lack of functional white blood cells (i.e. lymphocytes and granulocytes) prevents pathogens from being attacked and eliminated properly, thereby causing infections and fever. Another frequent symptom is bleeding, for example, under the skin (bruises, petechiae) or from mucous membranes such as the gums, owing to impaired blood coagulation as a result of low platelet counts.
The growth of leukaemia cells in the marrow of the long bones can cause bone and joint pain, especially in the limbs (arms and legs) and back. This pain can be so intense that the affected child may refuse to walk or run.
The malignant cells can also spread into the liver, spleen, and lymph nodes. Therefore, these organs may enlarge and subsequently cause problems, such as abdominal pain. In general, all organs can potentially be affected by AML. If AML spreads to the brain and its meninges, patients may suffer from headache, visual disturbances, nausea, vomiting, and other central nervous system impairments.
Presenting symptoms in patients with AML are as follows:
Very frequent (over 60 % of patients):
- fatigue, exhaustion, weariness, malaise, pallor (caused by the lack of red blood cells, anaemia)
- fever and/or frequent nonspecific infections (due to the lack of white blood cells, neutropaenia)
- abdominal pain and loss of appetite (due to the enlargement of spleen and/or liver)
Frequent (between 20 and 60 % of patients)
- increased risk of bleeding, for example, frequent spontaneous nose bleeding, gum bleeding (for example while brushing teeth), excessive bruising, pinpoint, round and red spots on the skin (petechiae); rare: cerebral haemorrhage (due to lack of platelets)
- enlarged lymph nodes (for example, in neck, armpits, groin)
- bone and joint pain (mostly limbs and back)
Rare (under 20 % of patients)
- headache, visual disturbances, vomiting, cranial nerve palsies (due to involvement of the central nervous system)
- shortness of breath (in case of high count of white blood cells, hyperleukocytosis)
- skin changes and chloroma (myeloid blastoma or myeloud sarcoma): tumour-like local masses of leukaemia cells in the skin, lymph nodes, bone, and, sometimes around the eyes; coloured, partly bluish-green in colour
- gingival (gum) enlargement (gingival hyperplasia)
- enlargement of testicles
Good to know: The type and degree of symptoms of AML vary individually. It is also important to know that a child or teenager showing one or more of these symptoms does not necessarily suffer from AML. Many of the symptoms described above, such as fever, fatigue, or headaches, are also regularly seen with frequent and rather harmless childhood diseases, like common colds and other viral infections. Nevertheless, if these symptoms recur frequently or persist,a doctor should be consulted as soon as possible. If acute leukaemia is diagnosed, treatment must be started promptly.
Diagnosis
If the doctor, based on the young patient’s history and physical examination, suspects acute leukaemia, he or she will first initiate a blood test. If the results promote the diagnosis of an acute leukaemia, a sample of the bone marrow (bone marrow biopsy) is required for confirmation.
For bone marrow tests and other diagnostic procedures, the doctor will refer the patient to a children’s hospital with a childhood oncology program (paediatric oncology unit) and childhood cancer specialists.
Blood and bone marrow tests
Blood and bone marrow tests are needed to confirm the diagnosis of leukaemia as well as to determine the type. The tests include microscopic (cytomorphological), immunological, and genetic laboratory analysis of blood and bone marrow samples that distinguish AML from other kinds of leukaemia (such as ALL) and, furthermore, allow to define the specific subtype of AML.
Knowing the subtype of AML is necessary for appropriate therapy planning, because different forms of AML have different biological characteristics and also vary regarding their response to treatment and, thus, prognosis.
Staging
Following the diagnosis of AML and its subtype, it is important for treatment planning to know whether the leukaemia cells have spread to additional body compartments (other than the bone marrow), including the brain, liver, spleen, lymph nodes, testicles, or bones. Therefore, various imaging techniques, such as ultrasound, X-ray, magnetic resonance imaging (MRI), computed tomography (CT), and/or bone scintigraphy, may be used to evaluate spread of the disease.
To find out whether the central nervous system (brain and spinal cord) is affected, a sample of cerebrospinal fluid is taken and analysed for leukaemia cells (lumbar puncture).
Additional diagnostics before treatment begins
To prepare the patient for the intensive treatment, several organ functions must be checked, since certain anticancer agents have specific side effects that can damage different organs. To have an initial assessment later helps to detect and appropriately interprete potential functional changes.
These preparatory diagnostics usually include various tests of the heart function (such as electrocardiography (ECG) and echocardiography) and the brain function (electroencephalography, EEG) as well as a variety of different blood tests that will give information on how well liver, bone marrow, and kidneys are working. Furthermore, the patient’s blood group will be defined, which is essential in case a blood transfusion may be necessary during the course of treatment.
Good to know: Not all the tests listed above need to be done for every patient. Contrariwise, the patient’s individual situation may require additional diagnostic procedures that have not been mentioned in this chapter. Therefore, you should always ask your doctor, based on the information above, which test your child needs and why.
Treatment
If acute myeloid leukaemia (AML) is being suspected or has been diagnosed, treatment should be started as soon as possible in a children’s hospital with a paediatric oncology program. Only in such a treatment centre, highly experienced and qualified staff (doctors, nurses and many more) is guaranteed, since they are specialised and focus on the diagnostics and treatment of children and teenagers with cancer according to the most advanced treatment concepts.
The doctors (such as oncologists, radiologists, surgeons) in these centres collaborate closely with each other. Together, they treat their patients according to treatment plans (protocols) that are continuously optimised. The goal of the treatment is to achieve high cure rates as well as low rates of side effects.
Treatment methods
Chemotherapy is the major backbone of AML treatment. It uses drugs (so-called cytostatic agents) that can kill fast-dividing cells, such as cancer cells, or inhibit their growth, respectively. Since one cytostatic agent alone may not be capable of destroying all the leukaemia cells, a combination of cytostatics that function in different ways are usually given (polychemotherapy).
Specific treatment concepts for patients with Down syndrome or APL: AML patients with Down syndrome do not require a chemotherapy as intensive as other patients with AML do. Patients with acute promyeolocytic leukaemia (APL) – a subtype of AML – may do completely without chemotherapy. They receive other substances instead.
Radiation therapy of the brain (cranial irradiation) is performed in few cases in addition to chemotherapy to treat central nervous system involvement. High-dose chemotherapy followed by stem cell transplantation may be an option for patients who do not respond to treatment from the very beginning or who develop recurrent disease.
The major goal of treatment is to eliminate the leukaemia cells in the body as extensively as possible, so that the bone marrow can resume its function as a blood cell-producing organ. In order to prevent or adequately manage the side effects of the intensive therapy, specific supportive care regimens have been established and now represent an important and efficient component of AML treatment.
Good to know: The intensity and duration of chemotherapy, the need for radiotherapy and/or stem cell transplantation, as well as the prognosis of the disease, depend on the subtype of AML, on how extensively the leukaemia cells have spread throughout the body, whether the patient tolerates the treatment, and whether the leukaemia responds to it. Based upon these risk factors, the doctors decide which therapy group a patient should be assigned to (standard, mediate, or high risk) in order to guarantee he or she will receive the most appropiate (risk-adapted) treatment.
Treatment courses
In general (i.e.apart from above-mentioned specific concepts), therapy of childhood AML consists of various treatment phases, duration, drug combinations, and goals of which are quite different. Major treatment elements are:
In general (i.e. apart from for above-mentioned specific cases), treatment of children and teenagers with AML consists of different steps. These steps (or phases) have different purposes. Therefore, they vary regarding their duration, treatment intensity, and the drug combinations applied. Major treatment elements are:
- Induction therapy: Induction consists of an intensive chemotherapy with various anticancer agents (polychemotherapy). It aims at achieving remission, i.e. elimination of most of the leukaemia cells, in a relatively short period of time. Induction therapy usually takes about two months, comprising two courses of chemotherapy, with a phase of recovery in between.
- Consolidation therapy: Consolidation follows induction therapy. It includes three courses of intensive chemotherapy, however, partially with different agents than those used during induction. With consolidation therapy, which takes about three to four months, the remaining leukaemia cells are to be further reduced, thus minimising the patient’s risk of developing recurrent disease.
- CNS-directed therapy: Treatment of the central nervous system (CNS-directed therapy) is recommended for all patients with AML. It is meant to either prevent a spread of leukaemia cells to the CNS (prophylactic treatment) or, in case the CNS is already affected, to stop them from being dispersed any further (therapeutic treatment). In any case, CNS-treatment includes the application of anticancer drugs into the spinal canal via a lumbar puncture (intrathecal chemotherapy). If the CNS is definitely involved, radiotherapy of the brain is recommended in addition to intrathekal chemotherapy. Radiation takes about two to three weeks and is carried out subsequent to consolidation therapy.
- Maintenance therapy: Maintenance therapy consists of a less intense polychemotherapy. It is mostly given orally while the children are out-patients. The goal of performing maintenance therapy is to fight all leukaemia cells that might have survived the intensive treatment over a long period of time, usually about a year after cessation of intensive therapy.
Some patients, for example children with high numbers of leukaemia cells (high white blood cell counts) at diagnosis or patients with severe involvement of other organs, receive a so-called pretreatment prior to the induction therapy (cytoreductive preliminary phase). The treatment consists of a short, approximately one week long, phase of chemotherapy using moderate dosages of one or two different agents.
The purpose of this phase is to reduce the often initially heavy burden of leukaemia cells gradually. This relatively gentle start helps the doctors to keep the metabolic products released by the dying leukaemia cells under control, which is important, because such metabolites can seriously harm the patient’s organs, especially the kidneys (so-called tumor lysis syndrome).
The overall treatment time for patients not receiving stem cell transplantation is about one and a half years. It is longer in cases of nonresponse to therapy or recurrent disease.
Therapy optimising trials and registries
In Germany, diagnosis and treatment of almost all children and adolescents with first diagnosis of acute myeloid leukaemia (AML) are performed according to the treatment plans (protocols) of “therapy optimising trials”, so named because the treatment concepts of such trials are continously being optimised based on the respective current status of medical knowledge.
Therapy optimising trials are standardised, controlled studies which aim at steadily developing and improving treatment possibilities for cancer patients. With many treatment centres being involved, such trials are also called “multicenter” or “multicentric” trials, and most often many countries participate.
Patients who are not included in any trial, either because they suffer disease while there is no trial available or because they do not, for some reason, fit into one of the existing trials, are often included in so-called registries. The patients are generally treatet according to the recommendations of the trial centre, thus receiving the current best therapy available.
Currently, the following therapy optimising trials and registries are available for children and adolescents with AML in Germany:
- Trial AML-BFM 2012: International, multicentric therapy optimising trial for the treatment of children and adolescents under 18 years of age with first diagnosis of AML (not included: patients with acute promyelocyte leukaemia, Down syndrome, and/or a transient myeloproliferative syndrome). The trial is open since 31/12/2014, following trial AML-BFM 2004, which was closed in 2012. Numerous treatment centres throughout Germany as well as in Switzerland, Austria, the Czech Republic, and Slovakia participate in this trial.
- Registry AML-BFM 2012: This registry includes patients with AML who are not treated within a trial. The registry was opened in 2012 after completion of trial AML-BFM 2004 with the aim to guarantee newly diseased patients the best diagnosis and therapy while there was not Trial available. Now, after the opening of the new trial (see above), the registry serves to record patients who do not meet the inclusion criteria of trial AML-BFM 2012. The registry also includes children and teenagers with AML and Down syndrome (who used to be part of the registry ML-DS 2006) as well as newborns with Down syndrome who suffer from a transient myeloproliferative syndrome (TMD), which frequently transforms into AML.
- Trial AML SCT-BFM 2007: International, multicentric therapy optimising trial for children, teenagers, and young adults (age: 0 to 20 years), who, for some reason (such as non-response to standard therapy or recurrent disease), are meant to receive a stem cell transplantation. This trial is performed by numerous treatment centres in Germany, Austria, Switzerland, the Czech Republic, and Slovakia.
- Registry AML Relapsed 2009: Children and adolescents (under 18) with recurrent disease or therapy-resistant AML, who are not treated within above-mentioned SCT trial, are included in the international registry AML Relapsed 2009. Treatment recommended by the trial centre is based on the results of the previous active trial (Relapsed AML 2001/01). A new trial will start shortly.
Note: Registry AML SCT-BFM and trial SCT-BFM 2007 are supervised by Prof. Dr. med. Martin Sauer (University Hospital Hannover). The trial centre for the remaining trials and registries (see above) is located at the University Hospital Essen (principal investigator: Prof. Dr. med. Dirk Reinhardt).
Prognosis
Thanks to the immense progress in diagnostics and treatment over the last four decades, the chances of cure for children and adolescents with acute myeloid leukaemia (AML) have significantly improved.
Today’s modern diagnostic procedures and the use of intensive, standardised polychemotherapy protocols combined with optimised supportive care regimens result in current 5-year survival rates of more than 70 %.
However, this also means that in approximately 30 % of the young patients the disease cannot be controlled due to nonresponse to therapy or recurrent disease (about 10 % of patients do not attain remission after the intensive treatment phase; nearly one third of the children and adolescents diagnosed with AML in Germany per year suffer recurrent disease).
Prognosis is generally worse in case of a relapse, in particular, if the disease comes back early, such as within a year after achievement of the first remission. This also applies to patients with no response to therapy. However, prognosis after relapse has improved during the last decade due to better therapy regimens including stem cell transplantation.
The 5-year survival rates in children and adolescents with AML relapse are currently in the range of 40 %. The major goal of the current therapy optimising trials and future studies is to find ways to further improve the chances of cure for all AML patients, including those with recurrent disease.
Note: The survival rates mentioned in the text above are statistical values. Therefore, they only provide information on the total cohort of patients with childhood AML. They do not predict individual outcomes. Acute leukaemias can show unpredictable courses, in both patients with favourable and patients with unfavourable preconditions.
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