Evaluation of children with macrocytosis: clinical study
Hakan Sarbay, Yılmaz Ay
Corresponding author: Hakan Sarbay, Diyarbak1r Children Hospital, Paediatric Hematology and Oncology, Dakap1, Diyarbak1r, Turkey
Received: 18 Mar 2018 - Accepted: 04 Sep 2018 - Published: 25 Sep 2018
Domain: Pediatric hematology,Pediatric oncology
Keywords: Macrocytosis, bone marrow failure, acute leukemias
©Hakan Sarbay et al. Pan African Medical Journal (ISSN: 1937-8688). This is an Open Access article distributed under the terms of the Creative Commons Attribution International 4.0 License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Cite this article: Hakan Sarbay et al. Evaluation of children with macrocytosis: clinical study. Pan African Medical Journal. 2018;31:54. [doi: 10.11604/pamj.2018.31.54.15498]
Available online at: https://www.panafrican-med-journal.com//content/article/31/54/full
Evaluation of children with macrocytosis: clinical study
Hakan Sarbay1,&, Yılmaz Ay2
1Diyarbakır Children Hospital, Paediatric Hematology and Oncology Diyarbakır, Turkey, 2Pamukkale University Faculty of Medicine, Paediatric Hematology and Oncology, Turkey
&Corresponding author
Hakan Sarbay, Diyarbakır Children Hospital, Paediatric Hematology and Oncology,
Diyarbakır, Turkey
Introduction: in this study, it is aimed to emphasize the causes and importance of macrocytosis in paediatric practice.
Methods: in the paediatric hematology and oncology clinic, 1752 patients evaluated in 2017, patients with macrocytosis were examined retrospectively with clinical and laboratory findings. Patients with macrocytosis were compared with the frequency of severe hematologic diseases such as acute leukemia and bone marrow failure in patients with normocytic and microcytic mean corpuscular volume.
Results: macrocytosis was detected in 72 out of 1752 patients (4.1%) in the study. Acute lymphoblastic leukemia in 11(15.2%), acute myeloid leukemia in 3(4.1%), Fanconi aplastic anemia in 7(9.7%), Diamond-Blackfan anemia in 2(2.7%), aplastic anemia in 1(1.3%), congenital diseritropoetic anemia in 1(1.3%), deficiency of vitamin B12 in 14(19.4%) were diagnosed. Down syndrome was presented in 33 cases (45.8%). The number of patients with acute leukemia diagnosis was 14(0.8%) in the group in which the mean corpuscular volume was either microcytic or normocytic. The incidence of acute leukemia and bone marrow failure was significantly higher in the group with macrocytosis compared between the two groups.
Conclusion: although vitamin B12 deficiency is considered firstly in patients who have undergone cytopenia and macrocytosis in our country, haematological malignancies, bone marrow failures, myelodysplasia and myeloproliferative diseases should be remembered especially in the individuals with Down syndrome at the same time.
Erythrocytes are classified into three morphological groups by their mean cell volume (MCV): microcytic, normocytic, and macrocytic. Macrocytosis is the enlargement of erythrocytes more than 2 standard deviations than the normal value of the age group. The classification by MCV also constitutes the foundation of anemia classification used mostly in clinical practice. Although MCV values vary by age and sex, reticulocyte count and other series are considered important for the examination of patients [1]. Macrocytic anemias are classified into two groups: one is associated with the megaloblastic changes in bone marrow and the other is non-megaloblastic anemia characterized by macrocytosis. Ninety five percent of megaloblastic anemias are caused by deficiency of vitamin B12 and/or folate. Whereas the most frequent causes of non-megaloblastic macrocytosis are neonatal period, reticulocytosis, liver dysfunction, aplastic anemias, and myelodysplastic syndromes [2, 3]. The aim of the present study is to underline the causes and significance of macrocytosis in clinical paediatric practice in Pamukkale University Faculty of Medicine and Diyarbakir Children Hospital Paediatric Hematology-Oncology clinics.
Retrospective analysis of the clinical and laboratory findings of 1752 patients, who were examined in the paediatric hematology and oncology outpatient clinics in a one year period during January-December 2017 were included. To identify the etiology, blood count, peripheral smear, bone-marrow aspiration and biopsies, erythrocyte sedimentation rate, kidney-liver-thyroid function tests, a-fetoprotein (AFP), hemoglobin F (HbF), vitamin B12 and folate levels were evaluated. Patients whose MCV values were more than 2 standard deviations than the normal value of the age group were grouped in macrocytosis. Etiology was investigated in these patients. There was any exclusion criteria in the study and variable datas are collected from our clinic archive. Prevalence rates of any severe hematological diseases such as acute leukemia and bone marrow deficiency were compared between macrocytic and normocytic or microcytic groups. Ethics committee approval was obtained for the study (30.01.18/03).
Statistical analyses: all the descriptive analyses were performed by Statistical Package for the Social Sciences 22.0 (SPSS Inc.; Chicago, IL, USA). For the comparison of the categorical variables, Fisher Chi-Square test was used.
Macrocytosis was detected in 72 of 1752 patients. The mean age of patients with macrocytosis were 5.7 (3 months to 17 years) years and 44(61.2%) were male and 28(38.2%) were female. Eleven patients (15.2%) were diagnosed with acute lymphoblastic leukemia (ALL), 3(4.1%) with acute myeloid leukemia (AML), 7(9.7%) with Fanconi aplastic anemia (FAA), 2(2.7%) with Diamond-Black fan anemia (DBA), one (1.3%) with aplastic anemia, one (1.3%) with congenital dysery thropoietic anemia (CDA), and 14(19.4%) with vitamin B12 deficiency. In 33(45.8%) of the cases, the diagnosis of Down syndrome (DS) was present. Patients with ALL consisted of 3 T-cell ALL and 8 pre-B cell ALL. Types of patients with AML were M0, M6 and M7. The most frequent cause for presentation and referral is the suspected cytopenia and malignancy. No history of a chronic disease except DS and no established drug use in the etiology of macrocytosis were present. Vitamin B12 and folate deficiency diagnosis was based on serum levels of vitamin B12 (normal value >200 pg/ml), folate (normal value>4.1 ng/ml), hemogram, and the findings of peripheral smear (hypersegmented neutrophils-the presence of neutrophils with six or more lobes or the presence of more than 3% of neutrophils with at least five lobes) and clinical evaluation. When 10 patients with bone marrow deficiency were evaluated, the high levels of HbF were detected in all, only mild high levels of AFP was found in only 2 patients with FAA.
In the clinical and laboratory investigations of three (4.1) cases, no underlying cause that may lead to macrocytosis and no associated cytopenia were established. In 28 (84.8%) of 33 patients with DS and two (14.2%) of 14 patients with vitamin B12 deficiency no signs for cytopenia were observed. Of 25 patients with acute leukemia and bone marrow deficiency one had isolated mild thrombocytopenia, three had anemia, one neutropenia-leukopenia, and the remaining 20(80%) had either bicytopenia or pancytopenia. While one patient with acute leukemia had a moderate increase in liver function tests, one patient with DS was having treatment for hypothyroidism (Table 1). The number of patients diagnosed with acute leukemia was 14(0.8%) in microcytic or normocytic group (n=1680) by MCV values. Although patients with pancytopenia or bicytopenia, caused by infections were included, they were not given the diagnosis of bone marrow deficiency. In the comparison of the macrocytic group to microcytic or normocytic group by MCV values, the prevalence of acute leukemia and bone marrow deficiency was found significantly higher in macrocytosis group (p< 0.001) (Table 2). In the evaluation of the patients with Down syndrome within itself, of 106 patients with DS, 33(33.1%) had macrocytosis. Two patients with macrocytosis were diagnosed with AML-M6 and ALL at the time of the first admission. One patient was diagnosed with myelofibrosis based on bone marrow biopsy examined upon cytopenia and hypocellularity of bone marrow aspiration confirmed at outpatient follow up visit. This patient developed AML-M7, identified at follow up after 7 months. The comparison between the groups with and without macrocytosis showed that the prevalence of acute leukemia was significantly higher in patients with DS (Table 3).
Macrocytosis is caused by four main mechanisms. These include nutritional deficiencies, bone marrow disorders, medication, and chronic diseases [4]. Macrocytosis is rarely observed in children compared to normocytic or microcytic conditions, based on MCV [5]. In our study, the prevalence of macrocytosis was 4.1% in 1752 patients. Although there are no studies on frequency in children in the literature, macrocytosis prevalence estimates ranging from 1.7% to 3.6% in adults [5, 6]. Our study had almost similar results when compared to the literature. Macrocytic anemias are classified as megaloblastic and non-megaloblastic. Non-megaloblastic anemia is associated with liver disease, hypothyroidism, bone marrow deficiencies, and MDS. The most common cause of megaloblastic anemia in children is vitamin B12 deficiency [5]. In our study, patients diagnosed with vitamin B12 deficiency were either suffering from accompanying iron deficiency or carriers of thalassemia, macrocytosis could only be identified in 14 patients. Failing to assess the utilization tests for vitamin B12 such as the measurements of serum concentrations of homocysteine and methylmalonic acid is considered as limitation in diagnosing vitamin B12 deficiency. Pappo et al. [7] in their study in 146 children identified the causes of macrocytosis as medication (51 patients), congenital heart disease (20), Down syndrome (12), bone marrow deficiency or MDS (6), and various chronic diseases (21). However, in 24 of them the cause of anemia could not be determined. In our study, acute leukemia, bone marrow deficiency, Down syndrome, and vitamin B12 deficiency were the leading causes. No history of medication was present. The reason the distribution of diagnoses differed in our study than that of Pappo et al. study has been considered as the result of overlooking of MCV values in patients without cytopenia and failing to refer them to paediatric hematology outpatient clinics. Erythrocytes in neonatal period tend to be physiologically macrocytic. In post neonatal period the upper limit of MCV decreases to 85 fL; over 6 months of age, the upper limit is calculated with MCV=84+0.6xAGE formula [8]. Patients in neonatal period were not included in our study. Individuals with Down syndrome also constitute a patient group with high prevalence for macrocytosis. In evaluation studies, macrocytosis was the most frequently obtained hematological finding in DS [9]. In a study by Prasher et al., macrocytosis was identified as the most frequent symptom in 147 adult patients [10]. In our cases, 33 of 106 patients with DS were determined to have macrocytosis. Two patients with macrocytosis had lower levels of vitamin B12. Since the levels of vitamin B12 and folic acid measurements were not performed in all DS cases with macrocytosis, no correlation between vitamin B12 and folic acid in this group of patients could be established. However, in previous studies, vitamin B12, and folic acid deficiency, and increased levels of hemoglobin F have not been determined as the underlying cause of macrocytosis in individuals with DS [11].
Macrocytosis may be encountered as the earliest symptom in bone marrow deficiencies, and in MDS. Macrocytosis may be detected even in cases with normal blood count, and responsive to treatment [12]. Macrocytosis and thrombocytopenia FAA are the most frequently obtained laboratory findings. Cytopenias usually occur at around the age of 5-10 years with a mean age of 7. In patients presenting with a congenital anomaly, and growth and developmental delay, if macrocytosis is present in blood count, then FAA should be suspected [13]. DBA and CDA are bone marrow deficiency syndromes, of which the former is associated with erythroid cell aplasia, and the latter is characterized by morphological abnormalities in erythrocytes and by ineffective erythropoiesis that affects isolated erythroid series. Majority of the patients have macrocytic anemia [14]. In our study, seven FAA, two DBA, one aplastic anemia, and one CDA patient had cytopenia and macrocytosis in their blood counts performed for diagnostic assessment (Table 1). Acute leukemia is the most common malignity of childhood accounts for 1/3 of all childhood malignancies. Although the etiology of acute leukemia has not been understood clearly, genetical abnormalities mainly include aberrations in karyotypes, chromosomal translocations, and deletions. Typical examples are Down syndrome and FAA. Laboratory findings may include leukocytosis, leukopenia, thrombocytopenia, and anemia. Anemia usually takes the form of normochromic normocytic anemia accompanied with reticulocytopenia [14]. In our study, of 28 patients diagnosed with acute leukemia, 14 (50%) had macrocytosis, and 14 (50%) had microcytic or normocytic MCV values. The prevalence for acute leukemia was higher in patients with macrocytosis (Table 2). Compared to normal population, children with DS have an increased risk of developing acute leukemia and MDS [15]. Majority of the patients with lymphoid leukemia show immuno-phenotypic features of precursor B cell ALL. In patients with DS, unlike the myeloid leukemia, lymphoid leukemias are not observed during the period of infancy. Due to intrinsic drug resistance and treatment related mortalities, prognosis was worse than that of lymphoid leukemia, which occurs sporadically [16, 17]. The incidence of AML was found to be 150 times more in children with DS. The most common form of AML in children with DS is the AML-M7 acute mega karyoblastic leukemia [18]. AML-M6 and AML-M1/M2 are less frequent than AML-M7 in patients with DS [19, 20]. In our 106 cases with DS, three of them developed acute leukemia. They were diagnosed with AML-M6, AML-M7 and ALL. Within the patients with DS, comparison between the groups with and without macrocytosis showed a significantly higher incidence of acute leukemia (Table 3).
Macrocytosis is a significant symptom in the diagnosis of bone marrow diseases and acute leukaemia in childhood. Although, given the present conditions of our country, vitamin B12 deficiency is the first suspect in patients with cytopenia and macrocytosis, yet haematological malignancies, bone marrow deficiencies (congenital or acquired), myelodysplasia, and myeloproliferative diseases should be borne in mind especially in the individuals with Down syndrome, as well.
What is known about this topic
- Macrocytosis is rarely observed in children compared to normocytic or microcytic conditions, based on MCV;
- The most common causes in the literature are drugs and chronic diseases;
- The number of studies done on children about macrocytosis and etiology is not enough.
What this study adds
- Macrocytosis can be an alarm finding for suspicion of bone marrow pathologies;
- In individuals with Down syndrome, patients with macrocytosis should be more closely monitored for myelodysplastic syndrome and acute leukemia.
Authors declare no competing interests.
All authors participated in the design of the study. Hakan Sarbay performed the collection, statistical analysis and interpretation of the data. Yılmaz Ay participated to the interpretation of data. All authors have read and approved the final document.
Table 1: characteristics of patients with macrocytosis, acute leukemia and bone marrow failure
Table 2: comparison of the incidence of acute leukemia and bone marrow failure
Table 3: comparison of the incidence of acute leukemia and myelodysplastic syndrome between patients with macrocytosis and without macrocytosis in Down syndrome
- Hubbard J. Megaloblastic and non-megaloblastic macrocytic anemias: in clinical laboratory hematology. Ed: Mc Kenzie SB. 2003; 263-288.
- Whitehead VM, Rosenblatt DS, Cooper BA. Megaloblastic anemia. In hematology of infancy and childhood (Eds: Nathanand Oski). Sixth Edition WB Saunders Co. 2003; 419-456.
- Lanskovsky P. Classification and diagnosis of anemia in children. In: P. Lanskovsky (ed). Manual of paediatric hematology and oncol, 5th ed, Academic Press, London, 2011:1-86. Google Scholar
- Savage DG, Ogundipe A, Allen RH, Stabler SP, Lindenbaum J. Etiology and diagnostic evaluation of macrocytosis. Am J Med Sci. 2000; 319(6): 343-352. PubMed | Google Scholar
- Aslinia F, Mazza JJ, Yale SH. Megaloblastic anemia and other causes of macrocytosis. Clin Med Res. 2006; 4(3): 236-241. PubMed | Google Scholar
- Colon-Otero G, Menke D, Hook CC. A practical approach to the differential diagnosis and evaluation of the adult patient with macrocytic anemia. Med Clin North Am. 1992; 76(3):581-597. PubMed | Google Scholar
- Pappo AS, Fields BW, Buchanan GR. Etiology of red blood cell macrocytosis during childhood: impact of new diseases and therapies. Paediatrics. 1992 Jun; 89(6Pt 1): 1063-106. PubMed | Google Scholar
- Herminston ML, Mentzer WC. A practical approach to the evaluation of the anemic child. Pediatr Clin North Am. 2002 Oct; 49(5): 877-91. PubMed | Google Scholar
- David O, Fiorucci GC, Tosi MT, Altare F, Valori A, Saracco P et al. Hematological studies in children with Down syndrome. Paediatric Hematology Oncology. 1996; 13(3): 271-275. PubMed | Google Scholar
- Prasher VP. Screening of medical problems in adults with Down syndrome. Down Syndrome Research and Practice. 1994; 2(2): 59-66. Google Scholar
- Bruwier A, Chantrain CF. Hematological disorders and leukemia in children with Down syndrome. Eur J Pediatr. 2012 Sep; 171(9): 1301-1307. PubMed | Google Scholar
- Shimamura A, Nathan DG. Acquired aplastik anemia and purered cell aplasia. In Nathan DG, Orkin SH, Ginsburg D, Look AT, Fisher DE, Lux SE (eds). Nathan and Oski’s Hematology of infancy and childhood, 7th ed. Philadelphia, WB Saunders, 2009; 275-305. Google Scholar
- Kutler DI, Singh B, Satagopan J, Batish SD, Berwick M, Giampietro PF et al. A 20-years perspective on the International Fanconi Anemia Registry (IFAR). Blood. 2003; 101(4): 1249-1256. Google Scholar
- Wartenberg GF, Adelman AS. Acute lymphoblastic leukemia: Epidemiology and etiology. In: Estey EH, Faderl SH, Kantarjian H (eds), Hematologic Malignancies: Acute Leukemias. Berlin Heidelberg. 2008; 77-95. Google Scholar
- Maligne S, Izraeli S, Crispino JD. Insights into the manifestations, outcomes, and mechanisms of leukemogenesis in Down syndrome. Blood. 2009; 113(12): 2619-2628. PubMed | Google Scholar
- Hasle H, Clemmensen IH, Mikkelsen M. Risks of leukemia and solid tumours in individuals with Down's syndrome. Lancet. 2000; 355(9199): 165-169. Google Scholar
- Buitenkamp TD, Izraeli S, Zimmermann M, Forestier E, Heerema NA, van den Heuvel-Ei-brink MM et al. Acute lymphoblastic leukemia in children with Down syndrome: a retrospective analysis from the Pontedi Legno study group. Blood. 2014; 123(1):70-77. PubMed | Google Scholar
- Webb D, Roberts I, Vyas P. Haematology of Down syndrome. Arch Dis Child Fetal Neonatal Ed. 2007; 92(6): F503-F507. PubMed | Google Scholar
- Zeller B, Gustafsson G, Forestier E, Abrahamsson J, Clausen N, Heldrup J et al. Acute leukaemia in children with Down syndrome: a population-based Nordic study. Br J Haematol. 2005; 128:797-804. PubMed | Google Scholar
- Talsma CE, Boyer DF. Myeloid leukemia associated with Down syndrome. Blood. 2017; 130(2): 230. PubMed | Google Scholar