Thiamine-responsive megaloblastic anaemia in a young adult with acute pancytopenia.

Thiamine-responsive megaloblastic anaemia (TRMA) is a rare autosomal recessive disorder characterised by the clinical triad of megaloblastic anaemia, sensorineural hearing loss and diabetes mellitus (DM) in young patients. We present a case of a young man with type 1 DM who presented with pancytopenia of unclear aetiology, initially attributed to a COVID-19 infection. After obtaining a bone marrow biopsy and pursuing genetic testing, two pathogenic variants of the SLC19A2 gene consistent with TRMA were discovered in this patient. Treatment with 100 mg of thiamine oral supplementation daily led to the complete resolution of his pancytopenia. It is important to consider a genetic cause of pancytopenia in a young person. Early recognition and diagnosis of TRMA can be life-altering given early treatment can reduce insulin requirements and resolve anaemia.

Severe pancytopenia at the presentation of Imerslund-Gräsbeck syndrome in a 23-month-old Italian boy.

BACKGROUND: Imerslund-Gräsbeck syndrome (IGS) is a rare autosomal recessive disorder characterized by megaloblastic anemia due to selective cobalamin malabsorption and benign proteinuria. IGS is caused by a disfunction of the cubam receptor, which mediates the reabsorption of cobalamin in the ileum and the reuptake of albumin in renal proximal tubules. CASE PRESENTATION: We describe the case of a 23-month-old-italian infant presenting with severe pancytopenia and failure to thrive in whom the diagnosis of IGS was made and vitamin B12 replacement therapy was resolutive. Genetic analysis (NGS with CNV analysis including 214 genes involved in bone marrow failure and anemia), showed the presence of two pathogenetic variants in the AMN gene (c-208-2 A > G and c.1006 + 34_1007-31del). These variants have been previously described in the literature, but their combination has never been reported. CONCLUSIONS: Imerslund-Gräsbeck syndrome should be considered in the differential diagnosis of children with severe pancytopenia even in those without neurological involvement. This case emphasizes the importance of an early diagnosis and prompt treatment, to prevent irreversible neurological injury.

Imerslund-Gräsbeck syndrome in a child with a novel compound heterozygous mutations in the AMN gene: a case report.

BACKGROUND: Imerslund-Gräsbeck syndrome (IGS) is an autosomal recessive disorder characterized by selective vitamin B12 malabsorption, resulting in vitamin B12 deficiency and impaired reabsorption of proximal tubular proteins.This case highlights a previously unidentified compound heterozygous variant in the Amnionless (AMN) gene that causes IGS syndrome and underscores the importance of long-term oral vitamin B12 replacement therapy in managing the condition. CASE PRESENTATION: In this retrospective analysis, we present the clinical data of a 3-year and 6-month-old female child diagnosed with IGS at Tongji Hospital, Tongji Medical College, Huazhong University of Science and Technology, China, in November 2018. The child was admitted to the hospital due to a history of anemia persisting for over a month. There was no previous significant medical history. The admission examination revealed megaloblastic anemia with proteinuria. Serum vitamin B12 levels were decreased, while folic acid and renal function were normal. The patient was diagnosed with megaloblastic anemia and started long-term oral vitamin B12 replacement therapy. Throughout the follow-up period, blood tests consistently showed normal results, while proteinuria persisted. In November 2019, the child and her parents underwent whole exome sequencing analysis, which revealed a novel compound heterozygous variant in the AMN gene: c.162 + 1G > A and c.922 C > T (p.Q308X) in the child, c.162 + 1G > A in the father, and c.922 C > T (p.Q308X) in the mother. Therefore, this child was further diagnosed with IGS. CONCLUSIONS: In this case, whole exome sequencing proves to be highly practical in daily healthcare for diagnosing and refining rare or ultra-rare diseases with ambiguous phenotypes or genetic diversity. It is also valuable for prognostic evaluation and personalized management. Additionally, the oral vitamin B12 treatment demonstrated positive clinical effects for the child, offering a new option for patients unable to undergo intramuscular vitamin B12 replacement therapy.

A Case of False Insulin Test Results Due to the Megaloblastic Anemia.

BACKGROUND: Megaloblastic anemia is a subtype of anemia with increased red blood cell volume. These megaloblastic cells can be easily destroyed in the bone marrow and spleen, leading to ineffective hematopoiesis. Insulin-degrading enzymes (IDE) in erythrocytes can break down the insulin into amino acid fragments; thus, when hemolysis occurs, IDE can be released into the blood, resulting in low insulin measurement values. METHODS: This article reports a case of false insulin test results due to the hemolysis resulting from megaloblastic anemia. RESULTS: The patient's first fasting glucose results indicated that the glucose and C-peptide levels were within the normal range while her insulin level was abnormally low. After hemolysis was corrected, the relevant indicators were re-evaluated and all the results were normal. CONCLUSIONS: This article reports a patient diagnosed with megaloblastic anemia, whose dysmorphic erythrocytes cause severe extravascular hemolysis. It was the occurrence of hemolysis that the IDE released into the blood, leading to the abnormal insulin test result.

Knuckle hyperpigmentation in a young male: A clinical sign of B12 deficiency not to be missed.

Vitamin B12 and folate deficiency are reversible causes of megaloblastic anemia. Strict vegetarians are at risk of megaloblastic anemia due to low cobalamin in their diet. Knuckle hyperpigmentation in patients with megaloblastic anemia is due to excess melanin synthesis in skin. Here we present a case of a young vegetarian male with megaloblastic anemia with knuckle hyperpigmentation managed successfully with intravenous followed by oral vitamin b12 and folate supplementation.

An Italian case series' description of thiamine responsive megaloblastic anemia syndrome: importance of early diagnosis and treatment.

BACKGROUND: Individuals with thiamine-responsive megaloblastic anemia (TRMA) mainly manifest macrocytic anemia, sensorineural deafness, ocular complications, and nonautoimmune diabetes. Macrocytic anemia and diabetes may be responsive to high-dosage thiamine treatment, in contrast to sensorineural deafness. Little is known about the efficacy of thiamine treatment on ocular manifestations. CASES PRESENTATION: Our objective is to report data from four Italian TRMA patients: in Cases 1, 2 and 3, the diagnosis of TRMA was made at 9, 14 and 27 months. In 3 out of 4 subjects, thiamine therapy allowed both normalization of hyperglycemia, with consequent insulin suspension, and macrocytic anemia. In all Cases, thiamine therapy did not resolve the clinical manifestation of deafness. In Cases 2 and 3, follow-up showed no blindness, unlike Case 4, in which treatment was started for megaloblastic anemia at age 7 but was increased to high doses only at age 25, when the genetic diagnosis of TRMA was performed. CONCLUSIONS: Early institution of high-dose thiamine supplementation seems to prevent the development of retinal changes and optic atrophy in TRMA patients. The spectrum of clinical manifestations is broad, and it is important to describe known Cases to gain a better understanding of this rare disease.

A New Case of Association of Megaloblastic Anemia and Pancytopenia of Infants.

BACKGROUND: Vitamin B12, or cobalamin deficiency, an infrequent clinical entity in pediatric age, is found almost solely in breastfed infants whose mothers are purely vegetarian, non-supplemented or with pernicious anemia. Megaloblastic anemia in infants presents with generalized weakness or irritability. METHODS: Diagnosis is usually centered on complete blood count, vitamin dosing, and peripheral smear, which may show macrocytes, hypersegmented neutrophils, reticulocytopenia and a raised mean corpuscular volume (MCV ˃ 100 fL). Pancytopenia has also been noted. RESULTS: We report an exclusive breastfed nine-month-old female child who presented with irritability, developmental delay, and difficulties in introducing new foods. Her initial blood count revealed pancytopenia. Vitamin B12 levels were found to be reduced. Maternal levels of Vitamin B12 were also found to be borderline low. The child was treated as per protocols, and improvement was evidenced with the return of hematological parameters to the regular and gradual advancement of milestones. CONCLUSIONS: We aim to underscore the importance of megaloblastic anemia as an important and rare cause of anemia in infancy.

Clinico-laboratory Profile and Outcomes of Megaloblastic Anemia presenting as Severe Pyrexial Illness mimicking Tropical Infection.

BACKGROUND: Anemia-causing fever has been described in patients with megaloblastic anemia. Although the exact mechanism of this is unknown, high-grade fever is relatively less reported. MATERIALS AND METHODS: This prospective observational study included all new cases of megaloblastic anemia presenting with febrile illness (>101°F) during a 3-year period. Patients with existing anemia, comorbidities, and other causes of macrocytosis were excluded. A detailed evaluation for megaloblastic anemia and workup for excluding tropical infections was done. The patients were treated with parenteral vitamin B12, folic acid, and other hematinics. RESULTS: Around 24 cases of megaloblastic anemia presenting with high-grade fever were included, with 14 (58.3%) males, mean duration of fever 7.7 days (4-18 days), and 09 (37.5%) having temperature >103°F. The mean hemoglobin (Hb) was 8.15 g/dL (3.7-11.1 g/dL), the mean corpuscular volume (MCV) was 111 ± 7.8 fL, 18 (75%) had unconjugated hyperbilirubinemia, the mean lactate dehydrogenase (LDH) was 814 ± 24 IU/L, and 21 (87.5%) had low B12 or folate levels. Most showed good therapeutic response to B12 or folic acid with defervescence in 1-5 days (mean 2.6 days) and improvement in lab parameters in 1 week. The study population was divided into those with temperature ≥103°F, and temperature <103°F it was seen that there was a significant association (p < 0.05) with leucocyte count of ≤3000/cumm, and MCV ≥110 fL, in patients with temperature ≥103°F Conclusion: Megaloblastic anemia should be considered in the differentials of a patient presenting with a febrile illness with no clinical localization and a negative initial fever workup. Early identification and prompt therapy of this easily treatable disorder are very essential.

Anemia: Macrocytic Anemia.

Macrocytic anemia is divided into megaloblastic and nonmegaloblastic causes, with the former being more common. Megaloblastic anemia results from impaired DNA synthesis, leading to release of megaloblasts, which are large nucleated red blood cell precursors with chromatin that is not condensed. Vitamin B12 deficiency is the most common cause for megaloblastic anemia, although folate deficiency also can contribute. Nonmegaloblastic anemia entails normal DNA synthesis and typically is caused by chronic liver dysfunction, hypothyroidism, alcohol use disorder, or myelodysplastic disorders. Macrocytosis also can result from release of reticulocytes in the normal physiologic response to acute anemia. Management of macrocytic anemia is specific to the etiology identified through testing and patient evaluation.

Effect of megaloblastic anemia on hemoglobin A2 and diagnosis of ß-thalassemia trait.

Context: ß-thalassemia trait is usually diagnosed by raised hemoglobin A2 (HbA2). The presence of megaloblastic anemia can cause an increase in HbA2 and create a diagnostic dilemma. Here, we have analyzed the effect of vitamin B12 and folic acid supplementation on HbA2 and diagnosis of ß-thalassemia trait in cases of megaloblastic anemia with raised HbA2. Materials and Methods: Cases of megaloblastic anemia with raised HbA2 on high-performance liquid chromatography (HPLC) were supplemented with vitamin B12 and folic acid. Post-treatment evaluation was done after 2 months. Cases showing adequate hematological response were subjected to statistical analysis. Based on post-treatment HbA2 value, the cases were diagnosed as normal, borderline raised HbA2, or ß-thalassemia trait. Pre- and post-treatment values of red cell parameters and HbA2 were analyzed. Results: There was a significant decrease in HbA2 value after vitamin B12 and folic acid supplementation. The diagnosis was changed in 70.97% of the cases after treatment. The chance of inconclusive diagnosis was decreased from more than 50% to less than 10%. Pre-treatment mean corpuscular volume (MCV) and HbA2% showed a significant difference between the thalassemic and normal groups. Conclusions: Megaloblastic anemia can lead to false-positive diagnosis of ß-thalassemia trait on HPLC. Repeat HPLC should be done after adequate supplementation of vitamin B12 and folic acid in cases of megaloblastic anemia with raised HbA2. Red cell parameters are not helpful to suspect ß-thalassemia trait in presence of megaloblastic anemia. However, HbA2% on HPLC can be a useful parameter to suspect or exclude ß-thalassemia trait in cases of megaloblastic anemia.

Thiamine responsive megaloblastic anaemia complicated with acute Parvovirus infection: A case report.

Thiamine responsive megaloblastic anaemia syndrome also known as Rogers syndrome is a very rare autosomal recessive disorder. The hallmark of the disease is the presence of the classic triad of anaemia, diabetes mellitus, and sensorineural deafness. We report the case of a 14-year-old boy who presented to us with severe megaloblastic anaemia, diabetes mellitus, and sensorineural deafness. The anaemia was further complicated by acute parvovirus infection. He was put on high doses of thiamine (vitamin B1) which led to an improvement.

Thiamine-responsive megaloblastic anaemia.

We report a 26-year-old girl who was diagnosed with diabetes mellitus in her childhood and was treated with insulin. With a history of visual disturbances during her childhood and anaemia, which was partially evaluated; the possibility of syndromic diabetes was considered. Genetic analysis was done and revealed a mutation in the SLC19A2 gene, confirming the diagnosis of thiamine-responsive megaloblastic anaemia. She was supplemented with thiamine, which dramatically improved her haemoglobin levels and glucose control. However, her vision could not be salvaged as the rod-cone dystrophy is a permanent damage.

Thiamine-Responsive Megaloblastic Anaemia With Hypothyroidism, A Puzzling Association.

Background: Thiamine-responsive megaloblastic anaemia (TRMA) is characterized by the classic trio of diabetes mellitus, sensorineural hearing loss, and megaloblastic anaemia, typically emerging subtly between infancy and adolescence. Administration of high-dose thiamine often yields improvements in anaemia and occasionally in diabetes. Uncommon manifestations include optic atrophy, congenital heart defects, short stature, and stroke. In this specific case, a 5-year-old diagnosed with insulin-dependent diabetes mellitus (IDDM) since the age of one presented with symptoms such as polyuria, fever, and vomiting, revealing an HbA1c of 10.64. Further examinations disclosed compromised hearing and vision. A negative antibody workup and a thyroid profile indicating hypothyroidism prompted additional investigations, including Brainstem Evoked Response Audiometry (BERA) and retinal examination, confirming bilateral sensorineural hearing loss and maculopathy, respectively. A comprehensive blood count unveiled megaloblastic anaemia. Genetic profiling confirmed a homozygous mutation in the SLC19A2 gene, thus diagnosing TRMA. An early diagnosis, coupled with genetic confirmation, enables timely intervention, with patients responding positively to high-dose thiamine. Genetic counselling plays a pivotal role in enlightening families about the disease and its inheritance patterns, fostering awareness and understanding.

Megaloblastic Anemia Masked by an Unrecognized Hemoglobinopathy.

BACKGROUND: Deficiency of vitamin B(12) or folate causes megaloblastic anemia (MA). The disease presents with pancytopenia due to the excessive cellular apoptosis of hematopoietic progenitor. MA is characterized by the presence of high mean corpuscular volume in the blood routine test and hyperlobulation nuclei of the granulocytes in the peripheral blood smears, and megaloblasts in the bone marrow. METHODS: We report a rare case, in which megaloblastic anemia was masked by an unrecognized hemoglobinopathy and presented with normocytic anemia and atypical morphological features of bone marrow. RESULTS: The patient was finally diagnosed with coexistence of MA and a-thalassemia minor due to determination of folate deficiency and genetic mutation for a-thalassemia. CONCLUSIONS: The case focuses on the contribution of the peripheral circulating blood smear examination in the diagnosis of anemia.

Diabetes Out-of-the-Box: Diabetes Mellitus and Impairment in Hearing and Vision.

PURPOSEOF REVIEW: This review aims to provide an update on the etiologies of diabetes that are due to genetic disorders and that co-occur with impaired hearing or vision and to compare them. The potential mechanisms, including novel treatments, will be detailed. RECENT FINDINGS: Wolfram syndrome, Kearns-Sayre syndrome, thiamine-responsive megaloblastic anemia, and maternally inherited diabetes and deafness are genetic disorders characterized by diabetes, impaired hearing, and vision. They differ in mode of inheritance, age at presentation, and the involvement of other organs; they are often misdiagnosed as type 1 or type 2 diabetes. Suspicion of a genetic diabetes syndrome should be raised when pancreatic autoantibodies are negative, other organs are involved, and family history includes diabetes. Correct diagnosis of the various syndromes is important for tailoring the most advanced treatment, preventing disease progression, and enabling proper genetic counseling.

Whole-Exome Sequencing Revealed a Pathogenic Nonsense Variant in the SLC19A2 Gene in an Iranian Family with Thiamine-Responsive Megaloblastic Anemia.

OBJECTIVE: Solute carrier family 19 member 2 (SLC19A2, OMIM *603941) encodes thiamine human transporter 1 (THTR-1), which contributes to bringing thiamine (vitamin B1) into cells. Mutations in SLC19A2 lead to a rare recessive genetic disorder termed thiamine-responsive megaloblastic anemia (TRMA) syndrome. METHODS: An Iranian family with TRMA was investigated by whole-exome sequencing (WES) to determine the genetic cause(s) of the disease. Accordingly, SLC19A2 genetic variants were gathered through literature analysis. RESULTS: WES recognized a known pathogenic variant, c.697C > T (p. Q233X), within exon 2 of SLC19A2 (NM_006996). Subsequently, the proband's parents and sister were confirmed as heterozygous carriers of the identified variant. CONCLUSION: The diagnostic utility and affordability of WES were confirmed as the first approach for the genetic testing of TRMA to verify the diagnosis. This analysis can be used to guide future prenatal diagnoses and determine the consequences in the other family members.

How I investigate acquired megaloblastic anemia.

In this review of megaloblastic anemia (MA), an overview of vitamin B12 and folate body requirements, biochemical pathways, and laboratory testing strategies will be provided. However, the focus of this review is the classic and unique features of MA in blood and bone marrow. Acquired MA is a benign disorder for many, but can be detrimental for some. The clinical presentation can vary considerably, and the spectrum of symptoms and signs is diverse and quite broad. Prompt recognition and therapy are critical to prevent potential irreversible damage and clinical sequelae, especially in patients with vitamin B12 deficiency. A delay in diagnosis of vitamin B12 deficiency can result in significant neurologic sequelae that may not fully resolve with treatment, including in neonates and young infants. The blood and bone marrow features in MA can closely mimic thrombocytopenic purpura, myelodysplasia, and other myeloid neoplasms. Both pancytopenia and normal MCV at presentation are common in MA and raise unique challenges for the diagnostician. Partially treated MA is also a significant diagnostic "trap". MA is highly responsive to treatment, and patients tend to improve rapidly upon treatment initiation. However, the broad range of clinical and hematologic features makes the rapid, successful diagnosis of MA a unique challenge for the hematopathologist. Even in the era of state-of-the-art laboratory testing, a high suspicion is required.