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Introduction

Myelodysplastic neoplasms (previous terminology, myelodysplastic syndromes; MDS) are characterized by ineffective hemopoiesis, bone marrow dysplasia, cytopenia and an increased risk of leukemic transformation (1). Gene myeloid mutations play a role in the pathogenesis of MDS; thus, these mutations become a contributing factor to the diagnosis, classification and prognosis of patients with the disease (2-5). The minimal diagnostic criteria proposed by the World Health Organization (WHO; from 2001 to 2008) included gene mutations [e.g., splicing factor 3b subunit 1 (SF3B1)] in the co-criteria (6). The WHO 2016 classification had used the SF3B1 mutation as a criterion in the classification of MDS (7). Subsequently, in the WHO 2022 classification, the SF3B1 and TP53 mutations were used to classify MDS (8). Therefore, gene mutations play an increasingly critical role in the diagnosis and classification of MDS. Furthermore, previous studies have demonstrated that gene mutations can be considered a key prognostic factor for MDS (9-11). The Molecular International Prognostic Scoring System (IPSS-M), which combines the International Prognostic Scoring System-Revised (IPSS-R) with molecular data including 31 gene mutations, appears to be superior to previous prognostic systems (12-14). However, its disadvantage is its high cost; thus, it is difficult for this new system to be applied in developing countries.

Of note, these gene mutations can also directly influence hematopoiesis due to their involvement in pathogenesis. The SF3B1 mutation is related to sideroblastic anemia; thus, the WHO 2022 classification determined that the detection of 15% ring sideroblasts may substitute for the SF3B1 mutation (15). It would be of interest to determine whether it is possible to use blood or bone marrow cell indices to predict the presence of gene mutations, thus providing reasonable and economical indications. Thus, the aim of the present study was to assess the association between gene mutations and certain cell indices in patients diagnosed with MDS.

Patients and methods

Patients

A retrospective cross-sectional study was conducted at the National Institute of Hematology and Blood Transfusion, Hanoi, Vietnam. Patients newly diagnosed with MDS who had been examined for myeloid genes mutations from January, 2018 to June, 2021 were consecutively recruited in the present study. The study protocol was approved by the Institutional Review Board of the National Institute of Hematology and Blood Transfusion (no. 939/QĐ-HHTM). Patient consent was waived by the committee, since this study was a retrospective observational study. All details of the patients were deidentified.

Next-generation sequencing (NGS)

NGS was performed with 51 myeloid gene mutations. The panel included gene groups for DNA methylation, chromatin modification, RNA splicing, cohesin complex, transcription, cytokine receptor/tyrosine kinase, RAS signaling, checkpoint/cell cycle and others (Table I). SF3B1, TET2, ASXL1 and DMNT3A were analyzed using the MiSeq Reagent kit (Illumina, Inc.). Other gene mutations were analyzed using the Hema 50 Panel (Dxome Co., Ltd., Korea).

Table I Panel of sequencing genes.

Table I

Panel of sequencing genes.

No	Gene	Location	No	Gene	Location
1	ANKRD26	10p12.1	26	IDH2	15q26.1
2	ASXL1	20q11.21	27	IKZF1	7p12.2
3	ATM	11q22.3	28	JAK2	9p24.1
4	BCOR	Xp11.4	29	KIT	4q12
5	BIRC3	11q22.2	30	KRAS	12p12.1
6	BLM	15q26.1	31	MPL	1p34.2
7	BRAF	7q34	32	MYD88	3p22.2
8	CALR	19p13.13	33	NF1	17q11.2
9	CBL	11q23.3	34	NOTCH1	9q34.3
10	CDKN2A	9p21.3	35	NOTCH2	1p12
11	CDKN2B	9p21.3	36	NPM1	5q35.1
12	CEBPA	19q13.11	37	NRAS	1p13.2
13	CREBBP	16p13.3	38	PAX5	9p13.2
14	CRLF2	Xp22.33	39	PRF1	10q22.1
15	CSF3R	1p34.3	40	PTPN11	12q24.13
16	DDX41	5q35.3	41	RB1	13q14.2
17	DNMT3A	2p23.3	42	RUNX1	21q22.12
18	ELANE	19p13.3	43	SETBP1	18q12.3
19	ETV6	12p13.2	44	SF3B1	2q33.1
20	EZH2	7q36.1	45	SRSF2	17q25.1
21	FANCA	16q24.3	46	TET2	4q24
22	FLT3	13q12.2	47	TP53	17p13.1
23	GATA1	Xp11.23	48	U2AF1	21q22.3
24	GATA2	3q21.3	49	UNC13D	17q25.1
25	IDH1	2q34	50	WAS	Xp11.23
			51	WT1	11p13

[i] ANKRD26, ankyrin repeat domain containing 26; ASXL1, ASXL transcriptional regulator 1; ATM, ATM serine/threonine kinase; BCOR, BCL6 corepressor; BIRC3, baculoviral IAP repeat containing 3; BLM, BLM RecQ like helicase; BRAF, B-Raf proto-oncogene, serine/threonine kinase; CALR, calreticulin; CBL, Cbl proto-oncogene; CDKN2A, cyclin dependent kinase inhibitor 2A; CDKN2B cyclin dependent kinase inhibitor 2B; CEBPA, CCAAT enhancer binding protein alpha; CREBBP, CREB binding protein; CRLF2, cytokine receptor like factor 2; CSF3R, colony stimulating factor 3 receptor; DDX41, DEAD-box helicase 41; DNMT3A, DNA methyltransferase 3 alpha; ELANE, elastase, neutrophil expressed; ETV6, ETS variant transcription factor 6; EZH2, enhancer of zeste 2 polycomb repressive complex 2 subunit; FANCA, FA complementation group A; FLT3, Fms related receptor tyrosine kinase 3; GATA1, GATA binding protein 1; GATA2, GATA binding protein 2; IDH1, isocitrate dehydrogenase [NADP(+)] 1; IDH2, isocitrate dehydrogenase [NADP(+)] 2; IKZF1, IKAROS family zinc finger 1; JAK2, Janus kinase 2; KIT, KIT proto-oncogene; KRAS, KRAS proto-oncogene; MPL, MPL proto-oncogene; MYD88, MYD88 innate immune signal transduction adaptor; NF1, neurofibromin 1; NOTCH1, Notch receptor 1; NOTCH2, Notch receptor 2; NPM1, nucleophosmin 1; NRAS, NRAS proto-oncogene; PAX5, paired box 5; PRF1, perforin 1; PTPN11, protein tyrosine phosphatase non-receptor type 11; RB1, RB transcriptional corepressor 1; RUNX1, RUNX family transcription factor 1; SETBP1, SET binding protein 1; SF3B1, splicing factor 3b subunit 1; SRSF2, serine and arginine rich splicing factor 2; TET2, Tet methylcytosine dioxygenase 2; TP53, tumor protein 53; U2AF1, U2 small nuclear RNA auxiliary factor 1; UNC13D, Unc-13 homolog D; WAS, WASP actin nucleation promoting factor; WT1, WT1 transcription factor.

Data collection

Data from patients, including clinical characteristics, peripheral blood and bone marrow cell indices, as well as cytogenetics report, recorded before starting treatment, were collected from medical record of the patients.

Diagnosis and classification of MDS

The determination of the diagnosis of MDS was based on the proposal of the minimal diagnostic criteria of MDS (5). Patients with MDS were classified according to the WHO 2022 criteria (15). The risk was calculated according to IPSS-M (9,16).

Statistical analysis

Qualitative variables (clinical characteristic, karyotype, cytogenetic risk, type of MDS and IPSS-M) and quantitative variables (hemoglobin, neutrophil count, platelet count, percentage of peripheral blood blast, bone marrow cell count and the percentage of bone marrow blasts) were analyzed according to sex and classification of age (50 years). Comparisons of qualitative variables were performed using the χ2 test or Fisher's exact test. Comparisons of quantitative variables were performed using an independent samples t-test or the Mann-Whitney U test according to normal or non-normal distribution. The presence of gene mutations was expressed as frequency and percentage. The differences between quantitative variables (hemoglobin, neutrophil count, platelet count, the percentage of peripheral blood blast, bone marrow cell count and the percentage of bone marrow blasts) were compared between two groups according to the presence of each mutation using an independent samples t-test or the Mann-Whitney U test according to normal or non-normal distribution. In variables for which a statistically significant difference was found, receiver operating characteristic (ROC) curve analysis was performed to separate the significant variables to determine a cut-off value. An area under the curve (AUC) value >0.8 was considered good for separation. The cut-off value was determined based on the coordinates of the curve. The cut cut-off value, the sensitivity (Se) and the specificity (Sp) were selected according to the Youden index (J) as follows: [J=max (Se + Sp -1)] with the highest value. Fisher's exact test was used to examine the association between the presence of the gene mutations and the cut-off value found. Statistical analysis was performed using SPSS 25 software (IBM Corp.). P<0.05 was considered to indicate a statistically significant difference. The bias was controlled as no data were lost. The study reporting conforms to the STROBE guidelines (17).

Results

Patient characteristics

The present study included 34 patients, with 21 males (61.8%) and 13 females (38.2%). The median age of the patients was 66 years (range, 28-81 years). All patients were Vietnamese, of Kinh ethnicity. The peripheral blood and bone marrow cell indices of the patients are presented in Table II. The clinical characteristics of the patients, as well as the classification results (WHO 2022 classification, karyotype, risk of cytogenetics and risk stratification according to the criteria of IPSS-M) are presented in Table III. The common clinical symptom was anemia (97.1%), followed by hemorrhage and infection. There were 3 to 4 patients with hepatomegaly, splenomegaly or lymphadenopathy, which were not massive. A total of 12 patients (35.3%) had comorbidities that included chronic obstructive pulmonary disease, hypertension, diabetes and dyslipidemia. In addition, 10 patients (29.4%) had an abnormal karyotype at the time of diagnosis, of which 2 patients had a complex karyotype (≥3 chromosomal abnormalities), 2 patients had isolated del(5q) and 6 patients had other abnormalities [such as del(20q), -7/del(7q), translocation]. A total of 11 patients were diagnosed with MDS with a low blast count, which accounted for the highest rate (32.4%) and 1 patient was diagnosed with MDS-biTP53, accounting for the lowest rate (2.9%); others types included MDS 5q-, MDS-SF3B1, MDS-IB1 and MDS-IB2. According to IPSS-M, 9 patients were classified as moderate-high risk, with the highest proportion (26.5%) and no patients were classified as very low risk. No statistically significance differences were found between the males and females, and between patients aged <50 and ≥50 years when these characteristics were compared (P>0.05).

Table II Cell indices of the patients according to sex and age.

Table II

Cell indices of the patients according to sex and age.

		Sex			Age, years
Index	All patients (n=34)	Male (n=21)	Female (n=13)	P-value	<50 (n=5)	≥50 (n=29)	P-value
Hemoglobin (g/l), mean ± SD	81.97±15.05	84±13.35	78.64±17.52	>0.05	86.40±10.76	81.21±15.6 9	>0.05
Platelet count (G/l), median	75.5	83	60	>0.05	78	75	>0.05
Neutrophil count (G/l), median	1.3	1.12	1.41	>0.05	1.41	1.19	>0.05
Peripheral blasts (%), median	1.0	2.0	0.0	>0.05	2.0	0.0	>0.05
Bone marrow cell count (G/l), median	29.46	31.3	20	>0.05	36.8	29.1	>0.05
Bone marrow blast (%), mean ± SD	5.91±5.14	5.95±5.04	5.85±5.52	>0.05	7.2±8.83	5.69±4.91	>0.05

[i] SD, standard deviation.

Table III Patients characteristics according to sex and age.

Table III

Patients characteristics according to sex and age.

		Sex			Age, years
Characteristic	All patients (n=34), n (%)	Male (n=21)	Female (n=13)	P-value	<50 (n=5)	≥50 (n=29)	P-value
Clinical factors
Anemia	33 (97.1)	20	13	>0.05	5	28	>0.05
Hemorrhage	8 (23.5)	4	4	>0.05	1	7	>0.05
Infection	7 (20.6)	3	4	>0.05	2	5	>0.05
Hepatomegaly	4 (11.8)	3	1	>0.05	0	4	>0.05
Splenomegaly	4 (11.8)	4	0	>0.05	0	4	>0.05
Lymphadenopathy	3 (8.8)	2	1	>0.05	0	3	>0.05
Comorbidities	12 (35.3)	7	5	>0.05	2	10	>0.05
Type of MDS
MDS 5q-	2 (5.9)	1	1		1	1
MDS SF3B1	2 (5.9)	2	0		0	2
MDS-biTP53	1 (2.9)	1	0		0	1
MDS low blast	11 (32.4)	6	5	>0.05	1	10	>0.05
MDS-IB1	10 (29.4)	5	5		1	9
MDS-IB2	8 (23.5)	6	2		2	6
Karyotype
Normal	24 (70.6)	14	10		3	21
Del (5q) isolated	2 (5.9)	1	1	>0.05	1	1	>0.05
Complex karyotype	2 (5.9)	1	1		0	2
Abnormal (other)	6 (17.6)	5	1		1	5
Cytogenetic risk
Very good	1 (2.9)	1	0	>0.05	0	1	>0.05
Good	27 (79.4)	16	11		4	23
Intermediate	0 (0)	0	0		0	0
Poor	4 (11.8)	3	1		1	3
Very poor	2 (5.9)	1	1		0	2
IPSS-M
Very low	0 (0)	0	0		0	0
Low	8 (23.5)	7	1		1	7
Moderately low	6 (17.6)	2	4	>0.05	2	4	>0.05
Moderately high	9 (26.5)	4	5		1	8
High	6 (17.6)	4	2		1	5
Very high	5 (14.7)	4	1		0	5

[i] MDS, myelodysplastic neoplasms (myelodysplastic syndromes); IB, increased blasts; IPSS-Molecular International Prognostic Scoring System.

Gene mutation data

NGS was performed to evaluate 51 myeloid gene mutations. A total of 20 patients (58.8%) had mutations. The remaining 14 patients did not have mutations. There were 18 mutations to be detected (Table IV). The ASXL transcriptional regulator 1 (ASXL1) mutation (17.6%) was the most commonly encountered, followed by the Runt-related transcription factor 1 (RUNX1), Tet methylcytosine dioxygenase 2 (TET2) (14.7%), and SF3B1 and TP53 mutations (11.8%) (Table IV). The number of gene mutations ranged between 1 to 7 per patient with a mean value of 1.35 (Table V).

Table IV Frequency of gene mutations.

Table IV

Frequency of gene mutations.

Pathways	Gene mutations	Frequency	%
Chromatin modification	ASXL1	6	17.6
Cohesin complex	STAG2	2	5.9
Transcription	RUNX1	5	14.7
	BCOR	2	5.9
RNA splicing	SF3B1	4	11.8
	SRSF2	3	8.8
	U2AF1	3	8.8
DNA methylation	TET2	5	14.7
	IDH1	1	2.9
	IDH2	2	5.9
	DNMT3A	3	8.8
Cytokine receptor/tyrosine	CSF3R	1	2.9
kinase	JAK2	1	2.9
	MPL	1	2.9
	KIT	1	2.9
RAS signaling	NRAS	2	5.9
Checkpoint/cell cycle	TP53	4	11.8
Others	SETBP1	1	2.9

[i] ASXL1, ASXL transcriptional regulator 1; STAG2, STAG2 cohesin complex component; RUNX1, RUNX family transcription factor 1; BCOR, BCL6 corepressor; SF3B1, splicing factor 3b subunit 1; SRSF2, serine and arginine rich splicing factor 2; U2AF1, U2 small nuclear RNA auxiliary factor 1; TET2, Tet methylcytosine dioxygenase 2; IDH1, isocitrate dehydrogenase [NADP(+)] 1; IDH2, isocitrate dehydrogenase [NADP(+)] 2; DNMT3A, DNA methyltransferase 3 alpha; CSF3R, colony stimulating factor 3 receptor; JAK2, Janus kinase 2; MPL, MPL proto-oncogene; KIT, KIT proto-oncogene; NRAS, NRAS proto-oncogene; TP53, tumor protein 53; SETBP1, SET binding protein 1.

Table V Distribution of gene mutations in the patients.

Table V

Distribution of gene mutations in the patients.

Number of gene mutations per patient	No. of patients with this number of mutations	%
0	14	41.2
1	10	29.4
2	1	2.9
3	6	17.6
4	1	2.9
5	1	2.9
6	0	0
7	1	2.9

Association between mutations and cell indices

As shown in Table VI, patients with the U2 small nuclear RNA auxiliary factor 1 (U2AF1) or TET2 mutation had a lower hemoglobin level than patients without this mutation. In addition, patients with the BCL6 corepressor (BCOR) or the serine and arginine rich splicing factor 2 (SRSF2) mutation had a higher percentage of peripheral blood blasts than patients without this mutation. Furthermore, patients with the BCOR mutation had a higher percentage of bone marrow blasts than those without it. On the other hand, patients with the SF3B1 mutation had a higher platelet count compared to the patients without it. These differences were statistically significant (P<0.05).

Table VI Cell indices according to the presence of some gene mutations.

Table VI

Cell indices according to the presence of some gene mutations.

Index	Gene mutations	Yes	No	P-value
Hemoglobin (g/l), mean ± SD	U2AF1	59.33±21.82	84.16±12.69	0.005
	TET2	68.80±20.68	84.24±13.02	0.032
Platelet count (G/l), median	SF3B1	335	67	0.004
Peripheral blood blast (%), median	BCOR	13	0	0.016
	SRSF2	8	0	0.007
Bone marrow blasts (%), mean ± SD	BCOR	13.50±4.95	5.44±4.84	0.029

[i] U2AF1, U2 small nuclear RNA auxiliary factor 1; TET2, Tet methylcytosine dioxygenase 2; SF3B1, splicing factor 3b subunit 1; BCOR, BCL6 corepressor; SRSF2, serine and arginine rich splicing factor 2.

ROC analysis determined that the significant separation only appeared in variables, such as the hemoglobin level, platelet count and peripheral blood blasts, with an AUC value >0.8 and P<0.05 (Table VII). Based on the coordinates of the curve with the results of calculating the J index, the optimal cut-off values for the hemoglobin level, platelet count and the percentage of peripheral blood blasts were determined with the possible highest values of sensitivity (Se) and specificity (Sp). The cut-off value, the Se and the Sp are presented in Table VII. The optimal cut-off value for the hemoglobin level to separate the presence of the U2AF1 mutation was 56.5. The optimal cut-off value for the percentage of peripheral blood blasts to separate the presence of the BCOR and SRSF2 mutation was 7.5 and 5.5, respectively. The optimal cut-off value for the platelet count to separate the presence of the SF3B1 mutation was 228.5. Otherwise, ROC did not determine the separation of the hemoglobin level or the percentage of bone marrow blasts according to the presence of the TET2 and BCOR mutation.

Table VII ROC analysis of the separation of cell indices according to the presence of some gene mutations.

Table VII

ROC analysis of the separation of cell indices according to the presence of some gene mutations.

Gene mutations	Cell indices	AUC	P-value	Cut-off value	Sensitivity (%)	Specificity (%)
U2AF1	Hemoglobin (g/l)	0.87	0.036	56.5	96.8	98.67
SF3B1	Platelet count (G/l)	0.95	0.004	228.5	100	96.67
BCOR	Peripheral blood blasts	0.98	0.026	7.5	100	99.37
SRSF2	(%)	0.94	0.013	5.5	100	98.39

[i] AUC, area under the ROC curve; U2AF1, U2 small nuclear RNA auxiliary factor 1; SF3B1, splicing factor 3b subunit 1; BCOR, BCL6 corepressor; SRSF2, serine and arginine rich splicing factor 2.

The results of Fisher's exact test indicated that a hemoglobin level <56.5 g/l, a platelet count >228.5 G/l, a percentage of peripheral blood blasts >7.5% and a percentage of peripheral blood blasts >5.5% was associated with the U2AF1, SF3B1, BCOR and SRSF2 mutations, respectively (Table VIII).

Table VIII Association between cell indices and the presence of some gene mutations.

Table VIII

Association between cell indices and the presence of some gene mutations.

Gene mutations	Cell indices	P-value
U2AF1	Hemoglobin (g/l) <56.5	0.016
SF3B1	Platelet count (G/l) >228.5	0.002
BCOR	Peripheral blood blasts (%) >7.5	0.011
SRSF2	Peripheral blood blasts (%) >5.5	0.009

[i] U2AF1, U2 small nuclear RNA auxiliary factor 1; SF3B1, splicing factor 3b subunit 1; BCOR, BCL6 corepressor; SRSF2, serine and arginine rich splicing factor 2.

Discussion

The development of MDS may be associated with cumulative genetic changes involving hematopoietic stem cells; thus, gene mutations are often detected in patients with MDS (18). Some studies have demonstrated that the majority of patients with MDS (50-90%) have at least one mutation (19-22). In the present study, gene mutations were observed in 58.8% of the patients. In fact, this rate also depended on the panel of NGS, as well as the sample size. The present study demonstrated that the most frequent genetic mutation was the ASXL1 mutation, followed by RUNX1, TET2, SF3B1 and TP53. Liu et al (23) also indicated that the ASXL1, RUNX1 and TP53 mutations were common. The TET2, SF3B1, ASXL1, SRSF2, DNA methyltransferase 3 alpha (DNMT3A) and RUNX1 mutations were the most commonly observed mutations in the study by Haferlach et al (20). In their study, Zhao et al (21) suggested that the most prevalent mutations were the U2AF1, SF3B1, ASXL1, TET2, BCOR, TP53 and DNMT3A mutations. In general, it has been indicated that genetic mutations, such as ASXL1, RUNX1, BCOR, TET2, DNMT3A, SF3B1, SRSF2, U2AF1 and TP53 are the most common mutations. These mutations also belong to the most known gene groups according to pathways/functions including chromatin modification (ASXL1), transcription factors (RUNX1), transcriptional regulator (BCOR), DNA methylation (TET2 and DNMT3A), RNA splicing (SF3B1, SRSF2 and U2AF1) and tumor suppressor (TP53) (24,25).

The accumulation of gene mutations alters hematopoiesis in MDS; thus, features such as cytopenia and bone marrow dysplasia may be associated with the activation of these mutations. Some studies, although a limited number, have indicated this association. Bejar et al (19) considered that the RUNX1, TP53 and NRAS mutations were strongly related to severe thrombocytopenia. The SF3B1 mutation was the most notable one. Martín et al (10) claimed that the majority of patients with MDS with ring sideroblasts carried the SF3B1 mutation. The SF3B1 mutation is involved in iron transport and causes abnormal iron deposition around the mitochondria to form ring sideroblasts (24). Polprasert et al (26) demonstrated that patients with the SF3B1 mutation had lower hemoglobin levels than those with the wild-type variant, but had normal platelet counts. Stockton et al (27) conducted a meticulous study that included numerous mutations and also indicated that patients with the SF3B1 mutation had anemia and a higher platelet count. In the present study, patients with this mutation also had a higher platelet count. A platelet count >228.5 G/l was associated with the presence of the SF3B1 mutation. The U2AF1 mutation, although valuable for consideration, had an ununified effect. Polprasert et al (26) hypothesized that it was associated with more severe leukopenia; however, Stockton et al (27) indicated that it was related to thrombocytopenia. In the present study, the U2AF1 mutation was associated with severe anemia. Patients with hemoglobin levels <56.5 g/l had the U2AF1 mutation. The present study also indicated that a percentage of peripheral blood blasts >7.5 and >5.5% was associated with the presence of the BCOR and SRFS2 mutations, respectively. Otherwise, Stockton et al (27) assumed that the SRFS2 mutation was related to higher hemoglobin levels. There were differences between the results of the studies. However, with the exception of the role of the SF3B1 mutation in increasing the number of sideroblasts, the mechanisms of gene mutations as regards the genesis of each cell clone are still being investigated.

The present study had certain limitations which should be mentioned: The most notable one was the is small sample size. Although the number of genes for the analysis was 51 genes, it still did not cover all myeloid genetic changes. The present study was only a cross-sectional study; thus, patients were not followed-up to determine their progress or any changes of the cell clone over time. The present study was conducted in Vietnam, a developing country. Due to the difficulty in accessing novel drugs, as well as the high cost of treatments such as stem cell transplantation, treatment outcome and survival time were difficult to evaluate, so the prognostic role of gene mutations has not been mentioned. In addition, the association between gene mutations and hematopoiesis is very complex, requiring additional valuable tests such as reticulin staining, Prussian blue staining (to detect ring sideroblasts), iron metabolism, etc. for more detailed analyses. These are also limitations of the study.

In conclusion, the present study demonstrates that there is an association between gene mutations and blood cell indices in patients diagnosed with MDS. The U2AF1 mutation may be related to severe anemia, while the BCOR and SRSF2 mutations may be related to MDS with an increased number of blasts. The SF3B1 mutation may be related to a good platelet count. Based on the levels of these blood cell indices, the appropriate gene mutations may be considered for examination. However, further research is required in order to determine the association between genetic changes, and changes in blood and bone marrow cells so that a model based on cell indices can be constructed to predict genes. This may promote reasonable genetic testing in patients with MDS. We also hope to carry out studies with large sample sizes and long follow-up periods to be able to determine the time when gene mutations appear based on changes in cell indices.

Acknowledgements

Not applicable.

Funding

Funding: No funding was received.

Availability of data and materials

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

Authors' contributions

MPV and QHN conceived and designed the study. QHN, TAT, QCD and DBV participated in data collection and processing. MPV, QHN, TAT, QCD, DBV, HTN and QKB participated in data analysis and interpretation, as well as in the literature search, and wrote the manuscript. All authors have read and approved the final manuscript. QHN and TAT confirm the authenticity of the raw data.

Ethics approval and consent to participate

The study protocol was approved by the Institutional Review Board of the National Institute of Hematology and Blood Transfusion (no. 939/QĐ-HHTM). Patient consent was waived by the committee since the present study was a retrospective observational study.

Patient consent for publication

Not applicable.

Competing interests

The authors declare that have no competing interests.

References