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Article

Prenatal Manifestation of Transient Abnormal Myelopoiesis: Case Report and Review of the Literature

by
Izabela Walasik
,
Ewelina Litwińska-Korcz
,
Monika Szpotańska
,
Paweł Stanirowski
,
Aleksandra Księżopolska
,
Artur Ludwin
and
Magdalena Litwińska
*
I Department of Obstetrics and Gynecology, Medical University of Warsaw, 02-091 Warsaw, Poland
*
Author to whom correspondence should be addressed.
J. Clin. Med. 2024, 13(16), 4584; https://doi.org/10.3390/jcm13164584
Submission received: 2 June 2024 / Revised: 27 July 2024 / Accepted: 29 July 2024 / Published: 6 August 2024
(This article belongs to the Special Issue Advances in Prenatal Diagnosis and Maternal Fetal Medicine)
Browse Figure
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Abstract

:
Background: Congenital malignancies are unusual fetal conditions, and therefore, the data on their prenatal manifestation are limited. Transient abnormal myelopoiesis (TAM) is a hematologic disorder characteristic for babies with trisomy 21 and based on the transient appearance of blast cells in peripheral blood. Methods: This paper presents prenatal manifestation of congenital TAM in a newborn with normal karyotype and reviews the literature on prenatal manifestation of this disorder. Results: A pregnant woman in her third pregnancy referred herself to the hospital for reduced fetal movements at 30 weeks of gestation. Admission’s ultrasound scan showed an increased middle cerebral artery peak systolic velocity together with hepatomegaly. The patient was admitted to the labor ward for cardiotocography monitoring which showed acute fetal distress with repeated unprovoked decelerations. An emergency cesarean section was conducted and a phenotypically normal female newborn with low Apgar score was delivered. Further examination of the peripheral blood revealed anemia and leukocytosis with high blast proportion. A bone marrow aspirate revealed 70.2% of blasts in a sample with an abnormal karyotype of 47 XX+21. Cytogenetic analysis of the blasts with later microarray comparative genomic hybridization confirmed the presence of GATA1 mutation. However, the buccal smear showed a normal karyotype in the infant. The disease was classified as TAM. Conclusions: Our study demonstrates a rare case of prenatal manifestation of TAM in a neonate with a normal karyotype. Obstetricians should pay attention to symptoms like high MCA PSV and hepatosplenomegaly as possible causes of fetal hematological disorders and differentiate it with infection or isoimmunization.

1. Introduction

Congenital malignancies are unusual fetal conditions. Considering their rarity, data on prenatal symptoms and prognosis are limited to case reports or small case series. The most common congenital malignancies are neuroblastoma, leukemia, and retinoblastoma [1].
Transient abnormal myelopoiesis (TAM) is a hematologic disorder that occurs in the perinatal period in up to 10% of infants with down syndrome (DS) or mosaic trisomy 21. TAM is characterized by the transient appearance of the blast cells with megakaryoblastic and/or erythroblastic characteristics in the peripheral blood and it is related to GATA1 pathogenic variants [2,3,4,5]. In most cases, TAM resolves spontaneously within the first months of life. However, one in five children who survive the disease will develop another myelodysplastic disease in the future [6].
Prenatal manifestation of hematologic disorders varies from asymptomatic to life-threatening which includes hepatosplenomegaly, hydrops fetalis, as well as intrauterine death [7,8,9,10]. It can be also reflected in easily accessible and routinely assessed fetal dopplers. The middle cerebral artery (MCA) is an important vessel which is commonly used in the assessment of fetal condition. The fetal MCA peak systolic velocity (PSV) is crucial in diagnosing fetal anemia [11]. The common causes of fetal anemia are isoimmunization, infection, fetomaternal hemorrhage, as well as fetal hematological diseases [12].
This paper presents the prenatal manifestation of congenital transient abnormal myelopoesis (TAM) in a newborn with a normal karyotype and reviews the literature on prenatal manifestation of this disorder, emphasizing only one similar case with TAM.

2. Materials and Methods

Searches of PubMed, Scopus, Embase, and Web of Science (year 1988) were performed to identify all English language studies that reported prenatal presentation of TAM. Studies were identified using the key words “transient abnormal myelopoesis”, “transient myeloproliferative disorder” and “prenatal manifestation”. We collected only cases with symptoms of TAM described prenatally. The reference lists of retrieved articles were reviewed to locate additional studies. Reviews and articles written in languages other than English were excluded from further analysis.
After the initial literature search, publications were analyzed by title and abstract to exclude studies that did not meet the inclusion criteria. A review was undertaken by two independent researchers for articles published between 1988 and 2023 including, firstly, titles and abstracts, and then, full texts of the papers. Following abstract selection, the remaining full-text articles were screened for eligibility. Inclusion criteria included the prenatal manifestation of TAM with or without DS. The exclusion criteria were cases with postnatal manifestation, articles with missing data, and publication other than Polish or English. Agreement before and after discrepancies between researchers were compared (73% vs. 96%) Figure 1.

3. Case Presentation

A 29-year-old woman in her third pregnancy, with two previous early miscarriages, referred herself for reduced fetal movements at 30 weeks of gestation. She had gestational diabetes, treated with diet; otherwise, the pregnancy was uneventful. Her routine first trimester scan together with the combined test for aneuploidies showed a low-risk result and the second trimester ultrasound examination showed no fetal abnormalities. The routine third trimester growth scan was scheduled in two weeks. Her blood group was A rhesus positive and no antibodies were detected. At admission’s ultrasound (Voluson E10, GE Healthcare, Chicago, IL, USA), doppler studies showed an increased middle cerebral artery peak systolic velocity (MCA PSV) with the 2.2 multiple of median (MoM). Also, the liver and spleen appeared enlarged. No fetal movements were visualized on the scan. The patient was admitted to the labor ward for cardiotocography monitoring (CTG). CTG (EDAN F9, Guangzhou, China) showed an acute fetal distress with repeated unprovoked decelerations and STV 2.2–3.4 ms. An emergency cesarean section was offered and a female newborn weighing 1600 g with low Apgar score (2/6/6/6 at 1 and 5 min) was delivered. The infant was admitted to the neonatal intensive care unit (NICU) showing difficulties in breathing and incorrect umbilical artery gas analysis (pH 7.12). The first physical examination showed no dysmorphic features. Abdominal palpation revealed enlargement of the liver and spleen.
After admission, blood and urine cultures were taken. An automatic measurement of peripheral blood sample revealed a hemoglobin level of 5.4 g/dL, hematocrit 15.5%, elevated white blood cells 124 − 128 × 103/dL, and normal platelets level. Blood smear analysis showed it was 44% blasts. Based on these results, acute leukemia was suspected. The baby urgently received a red cells transfusion. Because of suspected oncological disease, the patient was transferred to a reference neonatal unit. Subsequent blood analysis showed increased white cell level 161 × 103/uL and biochemical markers of tumor lysis syndrome. Blood smear analysis showed it was 80% blasts. Abdominal ultrasound confirmed hepatosplenomegaly. Antimetabolic agents were administered in order to treat tumor lysis syndrome. A bone marrow aspirate revealed 70.2% blasts in a sample with an abnormal karyotype of 47 XX+21 in a phenotypically normal female neonate. The cytogenetic analysis classified the blasts as FAB M7- megakarioblastic leukemia (AMKL) or TAM. Considering the karyotype of the blast cells and possible diagnosis of Down syndrome (DS), the first line diagnosis was TAM. Knowing that TAM resolves spontaneously in most cases, antimetabolic therapy was discontinued. In order to verify the DS diagnosis, the buccal smear was taken for microarray comparative genomic hybridization (aCGH) (Thermofisher scientific and GATA1 genetic test including three fragments of GATA1 gene (exons 2, 3, 4) which collocated introns using Sanger sequencing (ABI3500). The test was positive for exon 2 GATA1 variant for c.49dupC (p.Gin17ProfsTer23). A test for genetic mosaicism from fibroblasts was not performed.
On the 60th day of life, the female infant was discharged home in a good general condition, hemodynamically stable, feeding with breast milk. Blast cells were no longer detectable.
The child has normal mental and physical development.

4. Literature Review

The literature review identified 23 articles that included a total of 43 cases presenting prenatal manifestation of TAM (Table 1). The genetic abnormality that was present in the vast majority of cases was trisomy 21 (42/43 cases).
The diagnosis of TAM was established at a mean gestation age of 31 weeks (23–37 weeks), placing the onset of prenatal manifestation of the disease in the third trimester. A variety of symptoms were identified in the literature. The most common prenatal manifestation of TAM was hepatosplenomegaly (31/43; 72%). Hydrops fetalis was described in 49% of cases (21/43).
Less common prenatal manifestations of TAM included abnormal dopplers indicative of fetal anemia (4/43), polyhydramnios (4/43), oligohydramnios (1/43), and pathologic cardiotocograph (4/43). TAM diagnosed postnatally is defined as a disease that usually resolves spontaneously. However, the presence of prenatal symptoms seems to worsen the prognosis. Among the 43 cases of TAM presenting prenatally, 24 fetuses had fatal outcomes (12 IUD, 12 NND). In three cases, parents opted for a termination of pregnancy. Only 16 fetuses had a normal follow-up. Among the 12 fetuses who died prenatally, the most common symptoms, present in 10 cases, were hepatomegaly and hydrops fetalis. The most common manifestation of TAM among fetuses who died postnatally was hepatomegaly (11/12, 92%). Also, all fetuses with high MCA PSV died before or after birth (4 cases). Three of them had fetal blood sampling which showed anemia, leukocytosis, and provided material for karyotyping. In two cases, intrauterine blood transfusion was performed. In the other two cases, the procedure was abandoned due to acute deterioration of fetal condition and immediate delivery.
The above mentioned data prove that TAM is characteristic for DS fetuses and can manifest with a variety of symptoms. The diagnosis of TAM in a neonate with a normal karyotype is rare. A child with a normal karyotype born with TAM and trisomy 21 in blast cells was described by Dosedla et al. The fetus presented symptoms of mild hepatosplenomegaly, polyhydramnios, and hydrops at 36 weeks of gestation. Fetal dopplers were normal and there was no anemia after birth. Cytogenetic examination with further molecular confirmation of GATA1 gene mutation established the final diagnosis of TAM [31].

5. Discussion

This study demonstrates prenatal manifestation of fetal hematopoietic disorder. This is a unique case of TAM in a child with a normal karyotype based on buccal smear and trisomy 21 present in the blast cells only. This study demonstrates prenatal manifestation of TAM with reduced fetal movements, abnormal doppler studies with high MCA PSV, as well as hepatosplenomegaly.
In the presented case, the patient was admitted to the hospital because of reduced fetal movements. Counting fetal movement during pregnancy is a simple method to assess fetal well-being [35]. Periods of decreased fetal activity can be physiological, especially with fetal sleep, and usually last up to 90 min in a full-term fetus [36]. On the other hand, reduced fetal activity is associated with adverse pregnancy outcomes like fetal growth restriction, anemia, infection or even intrauterine fetal death [37,38,39,40]. In the presented case, both admission’s ultrasound and CTG showed abnormal results. It is therefore advisable to perform both CTG and ultrasound whenever pregnant women report reduced fetal activity [41].
In the presented case, high middle cerebral artery peak systolic velocity (MCA PSV) was the main prenatal manifestation of TAM. Middle cerebral artery (MCA) is a vessel commonly used to diagnose fetal anemia [11]. The background of fetal anemia includes isoimmunization, infection, fetomaternal hemorrhage, and, less frequently, fetal hematological diseases [12].
Peripheral blood leukocytosis is a common abnormality described in TAM cases; however, it is impossible to diagnose with ultrasound. While analyzing hemoglobin level in TAM cases, patients are mostly normocythemic, but they can be polycythemic [24] or anemic [7,26]. In the presented case, the red blood cell count after birth was low, which was reflected in high MCA PSV (Hb 5.4 g/dL, hematocrit 15.5%). Fetal anemia led to pathological CTG and prompted immediate delivery.
The literature review (Table 1) on prenatal manifestation of TAM found only four articles describing fetuses with high MCA PSV suggestive of fetal anemia [27,32,33,42]. However, the majority of newborns included in the literature review were found to be anemic after birth without prenatal suspicion of anemia (12/43). Among the fetuses with incorrect MCA blood flow that had fetal blood sampling, hemoglobin level varied from 2.8 to 9.7 g/dL. All fetuses with high MCA PSV reported in the literature died in utero or immediately after birth. In the presented case, the newborn was born in a severe overall condition receiving two points in the Apgar score. It can be, therefore, assumed that the presence of fetal anemia reflected in high MCA PSV is a significant factor that worsens the prognosis. Tamblyn et al., in a systematic review of cases with TAM, suggested that hepatosplenomegaly is a fatal factor for fetuses with TAM, reporting an associated mortality rate of 87.5% (21/24) [43]. Based on our review, together with the case presentation, fetal anemia should be considered as another important risk factor in fetuses with TAM.
According to the literature review (Table 1), hepatosplenomegaly is a common symptom of TAM (31/43 cases). Differential diagnosis of enlarged fetal liver or spleen includes isoimmunization disorders, fetal anemia, cytomegalovirus or parvovirus B19 infection, congestive heart failure, and hepatic tumors [21]. In the presented case, hepatosplenomegaly was a manifestation of TAM. Hepatomegaly in fetuses with TAM results from liver fibrosis, infiltration of blast cells to the liver, as well as extramedullary hematopoiesis [26,42].
In the presented case, the decision to deliver the baby was made based on the pathological indices of CTG which was nonreactive with repeated unprovoked late decelerations and short-term variability of 2.2–3.4 ms. Hartung et al. presented a similar case of a patient at 31 weeks of gestation admitted to the hospital because of reduced fetal movements, reversed end-diastolic flow in the umbilical fetal arteries, and decreased indices in the middle cerebral artery suggestive of the brain-sparing effect. Two days later, an urgent cesarean section was performed due to late decelerations in CTG. The neonate had a genotype of DS with incorrect peripheral blood examination that was later classified as TAM [14]. The presented cases highlight the need for considering fetal hematological disorders when reduced fetal movements are accompanied by hepatosplenomegaly on ultrasound and incorrect CTG.
The postnatal diagnosis of TAM in neonates with a normal karyotype is extremely rare. In order to diagnose this condition, assessment of the total blood count and blast proportion has to be performed. The final diagnosis of TAM is established after cytogenetic analysis and classification of the blast cells with further testing for GATA1 mutation [44,45].
The strength of this study is the sharing of data on symptoms of TAM in a fetus with a normal karyotype. The presented case emphasizes the need to put special attention on the fetal symptoms mentioned above, even if the karyotype is normal based on the initial tests and not to reject TAM diagnosis in a newborn which requires close follow-up for possible development of AML.
The limitations of this study are related to its nature of a case report and the rarity of the condition. Also, fetal blood sampling was not performed since the condition of the fetus prompted urgent delivery. However, the case highlights the importance of performing an ultrasound evaluation upon admission of a patient referred for reduced fetal movements. The examination should include doppler examination also in normally grown fetuses. Another limitation is lack of data on fetal mosaicism. The blood tests usually performed to diagnose TAM are new generation sequencing or whole exome sequencing. These tests are not accurate for detecting newborn mosaicism. The final diagnosis should be based on the tests from newborn fibroblasts as well as analysis of blast cells, which is crucial in post-therapeutic monitoring of AML development.

6. Conclusions

Even though the literature reports good prognoses and the self-limiting nature of TAM, fetuses presenting high MCA PSV or hepatosplenomegaly seem to have a fatal outcome. Our study demonstrates the rare manifestation of TAM in a neonate with a normal karyotype and prenatal presentation of hepatosplenomegaly and anemia.
The literature reports leukocytosis as a typical disorder in TAM cases, but this cannot be detected prenatally with noninvasive tolls. Anemia often coexists in TAM cases and is easily detectable by noninvasive MCA doppler examination. This can be an accessory marker for suspected hematological disorders, especially in fetuses presenting hepatosplenomegaly.
Obstetricians should pay attention to symptoms like high MCA PSV and hepatosplenomegaly as possible causes of fetal hematological disorders and differentiate it with infection or isoimmunization. The CTG together with ultrasound examination should be routinely offered if a pregnant woman reports decreased fetal movements. To confirm the TAM diagnosis, it is recommended to perform fetal blood sampling with analysis of the blast karyotype.

Implication for Clinical Practice

  • High MCA PSV without infection or immunization can be a symptom of TAM in fetuses presenting hepatosplenomegaly.
  • TAM is a possible cause of non-immune hydrops fetalis, fetal anemia, and hepatosplenomegaly.
  • This case illustrates the importance of performing an ultrasound examination that includes doppler studies even if the fetus is growing normally in patients presenting with reduced fetal movements.
  • Do not assume that TAM occurs only in DS neonates.

Author Contributions

Conceptualization, M.L. and E.L.-K.; methodology, E.L.-K., I.W., and M.L.; data collection, I.W. and M.L.; writing—original draft preparation, E.L.-K., M.L., and I.W.; writing, review and editing, M.L., M.S., P.S., A.K., and A.L.; supervision, E.L.-K. and M.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Ethical approval was obtained from the Ethics Committee of the Medical University of Warsaw AKBE/88/2024, approval date: 14 April 2024.

Informed Consent Statement

Written informed consent was obtained from the patient involved in this study to publish this paper. All data related to the patient have been anonymized and do not allow identification of the patient.

Data Availability Statement

The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.

Conflicts of Interest

The authors declare no conflicts of interest.

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Jcm 13 04584 g001
Figure 1. Literature review.
Figure 1. Literature review.
Jcm 13 04584 g001
Table 1. Data of 43 fetuses diagnosed with TAM with prenatal symptoms of the disease.
Table 1. Data of 43 fetuses diagnosed with TAM with prenatal symptoms of the disease.
AuthorGA (w)Hydrops
Fetalis		HepatosplenomegalyDopplersIntrauterine
Intervention		Birth (w)OutcomeFetal KaryotypeBlast KaryotypeComplete Blood Count
Baschat et al., 1998 [13]26yesyesN/AN/A31IUDTrisomy 21Trisomy 21Anemia, Leukocytosis
Hartung et al., 1988 [14]31noyesIncreased PI UA
Decreased PI MCA		N/A32AliveTrisomy 21N/ALeukocythosis
Hendricks et al., 1993 [15]26yesnoN/AC blood transfusion29IUDTrisomy 21N/AAnemia
Hendricks et al., 1993 [15]29yesnoN/AFBS31IUDTrisomy 21N/ALeukocytosis Anemia Thrombocytopenia
Macones et al., 1995 [16]28yesyesN/AFBS29IUDTrisomy 21N/ALeukocytosis Thrombocytopenia
Macones et al., 1995 [16]30yesyesN/AFBS33AliveTrisomy 21N/ALeukocytosis Anemia
Strobelt et al., 1995 [17]31noyesN/AFBS35AliveTrisomy 21Trisomy 21Leukocytosis
Siva et al., 1999 [18]N/AnonoN/AN/A38AliveTrisomy 21N/AN/A
Hirashima et al., 2000 [19]34nonoN/AN/A35AliveTrisomy 21N/AN/A
Smercek et al., 2001 [20]30yesyesUA AEDVFBSN/AIUDTrisomy 21Trisomy 21/CD 34+Leukocytosis Anemia Thrombocytopenia
Smercek et al., 2001 [20]26yesyesHigh UA PIFBS31IUDTrisomy 21Trisomy 21/CD 34Leukocytosis Anemia Thrombocytopenia
Smercek et al., 2001 [20]28yesyesNAFBSN/AIUDMosaic Trisomy 21Trisomy 21Leukocytosis Anemia Thrombocytopenia
Smercek et al., 2001 [20]29yesyesN/AN/A29IUD-N/AN/A
Hamada et al., 2001 [21]35noyesN/AN/A36NNDTrisomy 21N/AN/A
Hamada et al., 2001 [21]35noyesN/AN/A38NNDTrisomy 21Trisomy 21N/A
Vimercati et al., 2003 [22]23noyesN/AFBSN/ATOPTrisomy 21N/Anormal
Azancot et al., 2003 [23]31nonoN/AFBS32TOPTrisomy 21CD 13, CD 33, CD 34, CD 7Leukocytosis
Thrombocytopenia
Ogawa et al., 2004 [24]28noyesN/AN/A30AliveTrisomy 21N/AN/A
Ogawa et al., 2004 [24]32noyesN/AN/A39AliveTrisomy 21N/AN/A
Ogawa et al., 2004 [24]28nonoN/AN/A37AliveTrisomy 21N/AN/A
Kikuchi et al., 2007 [25]34noyesUA AEDVN/A35NNDTrisomy 21N/AN/A
Kikuchi et al., 2007 [25]37noyesN/AN/A38NNDMosaic Trisomy 21N/AN/A
Kikuchi et al., 2007 [25]28noyesN/AN/A40AliveTrisomy 21N/AN/A
Kikuchi et al., 2007 [25]31noyesN/AN/A40AliveTrisomy 21N/AN/A
Hojo et al., 2007 [26]33nonoN/AFBS35AliveTrisomy 21N/ALeukocytosis Thrombocytopenia
Hojo et al., 2007 [26]28yesnoN/AFBS32AliveTrisomy 21N/ALeukocytosis
Thrombocytopenia
Hojo et al., 2007 [26]33yesnoN/AFBS37AliveTrisomy 21N/ALeukocytosis
Thrombocytopenia
Hojo et al., 2007 [26]28yesyesN/AFBS30IUDTrisomy 21N/ALeukocytosis
Anemia Thrombocytopenia
Hojo et al., 2007 [26]28yesyesN/AFBS31NNDTrisomy 21N/ALeukocytosis
Anemia
Hojo et al., 2007 [26]37yesyesN/AFBS37NNDTrisomy 21N/ALeukocytosis
Anemia Thrombocytopenia
Hojo et al., 2007 [26]32yesyesUA AEDVN/A32NNDTrisomy 21N/ALeukocytosis
Anemia
Gwang et al., 2009 [27]28yesyesHigh MCA PSVFBS29IUDTrisomy 21N/ALeukocytosis
Anemia Thrombocytopenia
Chen et al., 2009 [28]32noyesN/AFBS36IUD46,XX,der(13; 21)(q10;q10),+21 (mosaic trisomy)N/ALeukocytosis
Malin et al., 2010 [27]29yesnoMCA PSV highC blood transfusion32NNDTrisomy 21CD 34 CD 33 CD117 CD 41 CD 42 CD 61
GATA 1 +		Leukocytosis
Anemia Thrombocytopenia
Mancuso et al., 2014 [29]32yesyesN/AN/A36NNDTrisomy 21N/A-
Traisrisilp et al., 2016 [30]31yesyesPulsation UVFBS33NNDTrisomy 21N/ALeukocytosis
Anemia Thrombocytopenia
Dosedla et al., 2019 [31]35noyesN/AN/A35AliveNormalGATA 1 +N/A
Rizzo et al., 2017 [32]32noyesHigh MCA PSVN/A34NNDTrisomy 21GATA 1 +N/A
Rizzo et al., 2017 [32]33noyesincorrectN/A35AliveTrisomy 21GATA 1 +N/A
Rizzo et al., 2017 [32]N/AnonoN/AN/A39AliveTrisomy 21GATA 1 +N/A
Muraoka et al., 2022 [33]30yesyesHigh MCA PSVThoracocentesisN/ANNDTrisomy 21N/AN/A
Tang et al., 2023 [34]36noyesN/AFBSN/AIUDTrisomy 21GATA 1 +Leukocytosis
Thrombocytopenia
Tang et al., 2023 [34]36yesnoN/AFBSN/ATOPTrisomy 21GATA 1 +Leukocytosis
Thrombocytopenia
GA: gestational age; C: cordocentesis; FBS: fetal blood sampling; NND: neonatal death; TOP: termination of pregnancy; IUD: intrauterine death; PI: pulsatility index; UA: umbilical artery; MCA: middle cerebral artery; PSV: peak systolic velocity; AEDV: absent end diastolic flow.
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Walasik, I.; Litwińska-Korcz, E.; Szpotańska, M.; Stanirowski, P.; Księżopolska, A.; Ludwin, A.; Litwińska, M. Prenatal Manifestation of Transient Abnormal Myelopoiesis: Case Report and Review of the Literature. J. Clin. Med. 2024, 13, 4584. https://doi.org/10.3390/jcm13164584

AMA Style

Walasik I, Litwińska-Korcz E, Szpotańska M, Stanirowski P, Księżopolska A, Ludwin A, Litwińska M. Prenatal Manifestation of Transient Abnormal Myelopoiesis: Case Report and Review of the Literature. Journal of Clinical Medicine. 2024; 13(16):4584. https://doi.org/10.3390/jcm13164584

Chicago/Turabian Style

Walasik, Izabela, Ewelina Litwińska-Korcz, Monika Szpotańska, Paweł Stanirowski, Aleksandra Księżopolska, Artur Ludwin, and Magdalena Litwińska. 2024. "Prenatal Manifestation of Transient Abnormal Myelopoiesis: Case Report and Review of the Literature" Journal of Clinical Medicine 13, no. 16: 4584. https://doi.org/10.3390/jcm13164584

APA Style

Walasik, I., Litwińska-Korcz, E., Szpotańska, M., Stanirowski, P., Księżopolska, A., Ludwin, A., & Litwińska, M. (2024). Prenatal Manifestation of Transient Abnormal Myelopoiesis: Case Report and Review of the Literature. Journal of Clinical Medicine, 13(16), 4584. https://doi.org/10.3390/jcm13164584

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