Acute myeloid leukemia pathophysiology: Difference between revisions
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* Presence of Auer rods can be noticed | * Presence of Auer rods can be noticed | ||
[[File:AML-M3 0001.jpg|center|thumb]] | [[File:AML-M3 0001.jpg|center|thumb|'''Images shown below are courtesy of Melih Aktan MD., Istanbul Medical Faculty - Turkey, and Kyoto University - Japan'''. | ||
AML-M3 - polarity of cytoplasmic granulation. In many cells the granules tend to polarize toward one portion of the cytoplasm and the nucleus on the opposite side.]] | |||
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====Acute myeloid leukemia- M5a and M5b classification==== | ====Acute myeloid leukemia- M5a and M5b classification==== | ||
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* M5b: <80% monoblasts in the marrow | * M5b: <80% monoblasts in the marrow | ||
[[File:AML-M5a 0001.jpg|center|thumb|'''Images shown below are courtesy of Melih Aktan MD., Istanbul Medical Faculty - Turkey, and Kyoto University - Japan'''. | |||
M5b: <80% monoblasts in the marrow]] | |||
[[File:AML-M5a 0001.jpg|center|thumb|'''Images shown below are courtesy of Melih Aktan MD., Istanbul Medical Faculty - Turkey, and Kyoto University - Japan'''. | |||
M5a: >80% monoblasts in the marrow]] | |||
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====Acute myeloid leukemia- M7 classification==== | ====Acute myeloid leukemia- M7 classification==== | ||
* Irregular cytoplasmic border is often noted in some of the megakaryoblasts and occasionally projections resembling budding atypical platelets are present | * Irregular cytoplasmic border is often noted in some of the megakaryoblasts and occasionally projections resembling budding atypical platelets are present |
Revision as of 17:24, 29 October 2019
Acute myeloid leukemia Microchapters |
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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: Syed Hassan A. Kazmi BSc, MD [2], Raviteja Guddeti, M.B.B.S. [3], Carlos A Lopez, M.D. [4], Shyam Patel [5]; Grammar Reviewer: Natalie Harpenau, B.S.[6]
Overview
Normal hematopoiesis involves the production of blood cells, and this normal physiologic process is dysregulated in acute myeloid leukemia. The pathophysiology of acute myeloid leukemia involves multiple mechanisms, including altered signal transduction and autonomous proliferation, differentiation blockade, evasion of apoptosis, and self-renewal. The pathophysiology of acute promyelocytic leukemia is most commonly due to a reciprocal translocation between chromosomes 15 and 17. The novel gene production causes a differentiation block in myeloid cells. There are multiple different binding partners for the RARA gene, so multiple translocations can contribute to the pathogenesis of acute promyelocytic leukemia.
Pathophysiology
In order to understand the pathophysiology of acute myeloid leukemia, it is important to understand normal physiology of hematopoiesis or blood cell production.
Normal Hematopoiesis
- Hematopoiesis is defined as the production of blood cells. This process is typically tightly-regulated under physiological conditions via a number of lineage-specific growth factors and lineage-specific growth signaling pathways.
- The differentiation of myeloid stem cells into mature myelocytes is controlled by lineage-specific transcription factors that regulate the expression of lineage-specific genes.
- In normal hematopoiesis, the myeloblast is an immature precursor of myeloid white blood cells. A normal myeloblast will gradually mature into a mature white blood cell.
- Normal hematopoiesis is dependent upon specific growth factor receptors. The two key growth factor receptors involved are as following:
- Growth factor receptors with intrinsic tyrosine kinase activity: These are expressed on CD34+ hematopoietic progenitor cells. Examples include receptors for the platelet-derived growth factors (PDGFs), PDGFR A and B, the receptor for macrophage colony stimulating factor (M-CSF), FMS-like tyrosine kinase receptor (FLT3R), and the receptors for Kit ligand (stem cell factor)[1]
- Growth factor receptors without intrinsic tyrosine kinase activity: These depend upon intracellular kinases of the Src and Janus kinase (JAK) families. Examples include the JAK-STAT pathway.[2]
Pathophysiology of Acute Myeloid Leukemia
- The malignant cell in acute myeloid leukemia is the myeloblast. However, in acute myeloid leukemia a single myeloblast accumulates genetic changes, which "freeze" the cell in its immature state and prevent differentiation.[3] This type of mutation alone does not cause leukemia. However, when such a differentiation arrest is combined with other mutations, which disrupt genes controlling proliferation, the result is the uncontrolled growth of an immature clone of cells, leading to the clinical entity of acute myeloid leukemia.[4]
- Much of the diversity and heterogeneity of acute myeloid leukemia stems from the fact that leukemic transformation can occur at a number of different steps along the differentiation pathway.[5] Human acute myeloid leukemia is organized as a hierarchy, and the cancer stem cell hypothesis best models the pathophysiology of acute myeloid leukemia.
- Modern classification schemes for acute myeloid leukemia recognize that the characteristics and behavior of the leukemic cell (and the leukemia) may depend on the stage at which differentiation was halted.
Role of Altered Signal Transduction and Autonomous Proliferation (Protein Tyrosine Kinase Activation)
- Activation of tyrosine kinase receptors is followed by signal transduction via intracellular signal cascades leading to alteration of transcription within the cell nucleus.[6]
- An important pathway that leads to cellular proliferation is the Ras-MAP Kinase pathway, where Ras is activated by binding of guanosine triphosphate (GTP). Ras-bound GTP in turn triggers a cascade of events that finally lead to activation of serine/threonine kinases. Consequently, there is an activation of MAP kinases, which phosphorylate important transcriptional regulators of cell cycle.[7][8][9][10]
- As a consequence of these, there is autonomous increased proliferation of cells.
Role of Altered Gene Expression and Differentiation Blockade
- Altered gene expression leads to autonomous cellular proliferation with defects in regulatory pathways involved in cellular proliferation.
- Chromosomal translocations and point mutations both play a pivotal role in generating a differentiation blockade on myeloid cells.
- This results in a disruption in transcription factors.
- Transcription factors affected by chromosomal rearrangement (translocations) include:
- Core binding factor complex [t(8;21), ETO-AML1 fusion]
- Core binding factor complex [inv(16), CBFβ-MYH11 fusion]
- Chromosome 3 translocation [t(3;21), RUNX1-EVI1 fusion][11][12][13]
- Retinoic acid receptor (RAR) fusion [t(15;17), PML-RARα fusion][14][15]
- MLL rearrangement [Activator protein of Hox gene promoters; Hox gene promoters in turn promote self-renewal of immature myeloid cells][16]
- Hox proteins[17][18]
- Point mutations in myeloid transcription factors include:
Evasion of Apoptosis (Protein Tyrosine Kinase Activation)
- The increased expression of Bcl-2 pro-survival molecule plays a key role in evasion of programmed cell death in AML.[21]
- PI 3-kinase activates the AKT serine/threonine kinase, and this kinase in turn phosphorylates BAD and releases the BCL-2 anti-apoptotic molecule.[22][23]
- The RUNX1-MTG8 fusion protein of AML represses the expression of p14ARF and promotes destabilization of p53 (a tumor suppressor gene).[24][25][26]
Self-Renewal
- The myeloid cells in acute myeolid leukemia have an ability to self-renew without being committed to a specific cell lineage.[27]
- The self-renewing capacity of myeloid cells in AMLs is thought to be mediated by the following:
- Fusion of ALK tyrosine kinase with nucleophosmin protein (NPM)[28]
- Mutation of FLT3-ITD[29][30]
- RUNX1-MTG8, PML-RARα, and PLZF-RARα fusions can all induce the expression of β-catenin and γ-catenin (plako-globin) proteins[31][32]
- The Wnt signalling pathway has also been shown to be involved in self-renewal of myeloid cells[33]
Pathophysiology of Acute Promyelocytic Leukemia
The pathophysiology of acute promyelocytic leukemia begins with a balanced reciprocal chromosomal translocation in hematopoietic stem cells. The chromosomal translocation involves the juxtaposition of the retinoic acid receptor-alpha gene (RARA) on the long arm of chromosome 17 with another gene (most commonly the promyelocytic leukemia gene (PML) on the long arm of chromosome 15).[34] The translocation is designated as t(15;17)(q22;q12). The PML-RARA fusion product is a transcriptional regulator and binds to retinoic acid response elements in the promoter regions of the genome. The PML-RARA fusion product serves to recruit co-repressors of gene transcription, preventing myeloid differentiation.[35] This is known as a differentiation block, since the cells are unable to differentiate into normal mature cells. The cells remain primitive and stem-like, which is the basis for the malignancy. The result of the chromosomal translocation is ineffective blood cell production and uncontrolled proliferation of malignant promyelocytes.[34] In 95% of cases of acute promyelocytic leukemia, the translocation involved PML and RARA. However, it is important to note that RARA has multiple other binding partners which can lead to the development or acute promyelocytic leukemia, as shown in the table below.
Translocation Partner | Chromosomal Location | Function | Response to Therapy | Other Features |
---|---|---|---|---|
PML |
15q24.1 |
|
|
|
11q23.2 |
|
|
| |
NPM1 |
5q35.1 |
|
|
|
NUMA[36] |
11q13.4 |
|
|
|
STAT5B[37] |
17q21.2 |
|
|
|
Microscopic Pathology
Description of pictures (shown below) according the classification of Acute myeloid leukemia system.
Acute myeloid leukemia- M0 classification
- Acute myeloid leukemia M0 with lack of obvious myeloid differentiation by routine histologic examination and presence of myeloperoxidase in <3% of blasts
- Morphologically, blasts are small to large with no granules or Auer rods
Acute myeloid leukemia- M1 classification
- Presence of more than 90% myeloblasts in blood
- Peroxidase
Acute myeloid leukemia- M2 classification
- Presence of granules can be noted
- Large myeloblasts with prominent nucleoli
Acute myeloid leukemia- M3 classification
- Also known as promyelocytic leukemia
- Hypergranular morphology with most cells containing abundant large granules
- Ruptured cells are releasing their granules free onto the slide
- Presence of Auer rods can be noticed
Acute myeloid leukemia- M5a and M5b classification
- M5a: >80% monoblasts in the marrow
- M5a: large monoblasts with fine nuclear chromatin and prominent nucleoli (note the absence of Auer rods)
- M5b: <80% monoblasts in the marrow
Acute myeloid leukemia- M7 classification
- Irregular cytoplasmic border is often noted in some of the megakaryoblasts and occasionally projections resembling budding atypical platelets are present
- Megakaryoblasts are usually medium-sized to large cells with a high nuclear-cytoplasmic ratio
- Nuclear chromatin is dense and homogeneous
- Variable basophilic cytoplasm which may be vacuolated
- An irregular cytoplasmic border is often noted in some of the megakaryoblasts and occasionally projections resembling budding atypical platelets are present
- Megakaryoblasts lack myeloperoxidase (MPO) activity and stain negatively with Sudan black B
- Clumps or granules in the cytoplasm
- PAS staining varies from negative to focal or granular positivity, to strongly positive staining
- More precise identification is by immunophenotyping or with electron microscopy (EM)
- Immunophenotyping using MoAb to megakaryocytic restricted antigen (CD41 and CD61) may be diagnostic
Images shown below are courtesy of Melih Aktan MD., Istanbul Medical Faculty - Turkey, and Kyoto University - Japan
-
AML-M3 - also called promyelocytic leukemia. Hypergranular morphology with most cells containing abundant large granules.
-
AML-M3 - ruptured cells are releasing their granules free onto the slide. Presence of Auer rods can be noticed.
-
AML-M3 - polarity of cytoplasmic granulation. In many cells the granules tend to polarize toward one portion of the cytoplasm and the nucleus on the opposite side.
-
AML-M3 Auer bodies.
-
AML-M3 Auer bodies.
-
AML-M3 variation.
-
AML-M4 - large monoblasts with abundant cytoplasm and moderately to intensely basophilic. The monoblasts will have lacy nuclear chromatin and one or more predominant nucleoli.
-
AML-M5a - >80% monoblasts in the marrow.
-
AML-M5a - large monoblasts with fine nuclear chromatin and prominent nucleoli. Note the absence of Auer rods.
-
AML-M5a (alpha naphtyle acetat).
-
AML-M5b - <80% monoblasts in the marrow.
-
AML-M5b - moderate amounts of cytoplasm and large nuclei with fine chromatin but without prominent nucleoli. Note presence of nuclear folds and creases, which are a characteristic feature of promonocytes.
-
AML-M7 - irregular cytoplasmic border is often noted in some of the megakaryoblasts and occasionally projections resembling budding atypical platelets are present.
-
AML-M7 - megakaryoblasts are usually medium sized to large cells with a high nuclear-cytoplasmic ratio. Nuclear chromatin is dense and homogeneous.
References
- ↑ Müller-Tidow C, Schwäble J, Steffen B, Tidow N, Brandt B, Becker K, Schulze-Bahr E, Halfter H, Vogt U, Metzger R, Schneider PM, Büchner T, Brandts C, Berdel WE, Serve H (February 2004). "High-throughput analysis of genome-wide receptor tyrosine kinase expression in human cancers identifies potential novel drug targets". Clin. Cancer Res. 10 (4): 1241–9. PMID 14977821.
- ↑ Ihle JN (April 2001). "The Stat family in cytokine signaling". Curr. Opin. Cell Biol. 13 (2): 211–7. PMID 11248555.
- ↑ Fialkow PJ: Clonal origin of human tumors. Biochim Biophys Acta 1976;458:283–321. PMID 1067873
- ↑ Fialkow PJ, Janssen JW, Bartram CR: Clonal remissions in acute nonlymphocytic leukemia: Evidence for a multistep pathogenesis of the malignancy. Blood 1991;77:1415–1517. PMID 2009365
- ↑ Bonnet D, Dick JE: Human acute myeloid leukemia is organized as a hierarchy that originates from a primitive hematopoietic cell. Nat Med 1997;3:730–737. PMID 9212098
- ↑ Schlessinger J (October 2000). "Cell signaling by receptor tyrosine kinases". Cell. 103 (2): 211–25. PMID 11057895.
- ↑ Skolnik EY, Batzer A, Li N, Lee CH, Lowenstein E, Mohammadi M, Margolis B, Schlessinger J (June 1993). "The function of GRB2 in linking the insulin receptor to Ras signaling pathways". Science. 260 (5116): 1953–5. PMID 8316835.
- ↑ Li N, Batzer A, Daly R, Yajnik V, Skolnik E, Chardin P, Bar-Sagi D, Margolis B, Schlessinger J (May 1993). "Guanine-nucleotide-releasing factor hSos1 binds to Grb2 and links receptor tyrosine kinases to Ras signalling". Nature. 363 (6424): 85–8. doi:10.1038/363085a0. PMID 8479541.
- ↑ Rozakis-Adcock M, McGlade J, Mbamalu G, Pelicci G, Daly R, Li W, Batzer A, Thomas S, Brugge J, Pelicci PG, Schlessinger J, Pawson T (December 1992). "Association of the Shc and Grb2/Sem5 SH2-containing proteins is implicated in activation of the Ras pathway by tyrosine kinases". Nature. 360 (6405): 689–92. doi:10.1038/360689a0. PMID 1465135.
- ↑ Carow CE, Levenstein M, Kaufmann SH, Chen J, Amin S, Rockwell P, Witte L, Borowitz MJ, Civin CI, Small D (February 1996). "Expression of the hematopoietic growth factor receptor FLT3 (STK-1/Flk2) in human leukemias". Blood. 87 (3): 1089–96. PMID 8562934.
- ↑ Follows GA, Tagoh H, Lefevre P, Hodge D, Morgan GJ, Bonifer C (June 2003). "Epigenetic consequences of AML1-ETO action at the human c-FMS locus". EMBO J. 22 (11): 2798–809. doi:10.1093/emboj/cdg250. PMC 156747. PMID 12773394.
- ↑ Hiebert SW, Reed-Inderbitzin EF, Amann J, Irvin B, Durst K, Linggi B (2003). "The t(8;21) fusion protein contacts co-repressors and histone deacetylases to repress the transcription of the p14ARF tumor suppressor". Blood Cells Mol. Dis. 30 (2): 177–83. PMID 12732181.
- ↑ 13.0 13.1 Pabst T, Mueller BU, Harakawa N, Schoch C, Haferlach T, Behre G, Hiddemann W, Zhang DE, Tenen DG (April 2001). "AML1-ETO downregulates the granulocytic differentiation factor C/EBPalpha in t(8;21) myeloid leukemia". Nat. Med. 7 (4): 444–51. doi:10.1038/86515. PMID 11283671.
- ↑ Grignani F, De Matteis S, Nervi C, Tomassoni L, Gelmetti V, Cioce M, Fanelli M, Ruthardt M, Ferrara FF, Zamir I, Seiser C, Grignani F, Lazar MA, Minucci S, Pelicci PG (February 1998). "Fusion proteins of the retinoic acid receptor-alpha recruit histone deacetylase in promyelocytic leukaemia". Nature. 391 (6669): 815–8. doi:10.1038/35901. PMID 9486655.
- ↑ He LZ, Guidez F, Tribioli C, Peruzzi D, Ruthardt M, Zelent A, Pandolfi PP (February 1998). "Distinct interactions of PML-RARalpha and PLZF-RARalpha with co-repressors determine differential responses to RA in APL". Nat. Genet. 18 (2): 126–35. doi:10.1038/ng0298-126. PMID 9462740.
- ↑ Milne TA, Briggs SD, Brock HW, Martin ME, Gibbs D, Allis CD, Hess JL (November 2002). "MLL targets SET domain methyltransferase activity to Hox gene promoters". Mol. Cell. 10 (5): 1107–17. PMID 12453418.
- ↑ Thorsteinsdottir U, Sauvageau G, Humphries RK (December 1997). "Hox homeobox genes as regulators of normal and leukemic hematopoiesis". Hematol. Oncol. Clin. North Am. 11 (6): 1221–37. PMID 9443054.
- ↑ Nakamura T, Largaespada DA, Shaughnessy JD, Jenkins NA, Copeland NG (February 1996). "Cooperative activation of Hoxa and Pbx1-related genes in murine myeloid leukaemias". Nat. Genet. 12 (2): 149–53. doi:10.1038/ng0296-149. PMID 8563752.
- ↑ Tiesmeier J, Czwalinna A, Müller-Tidow C, Krauter J, Serve H, Heil G, Ganser A, Verbeek W (November 2003). "Evidence for allelic evolution of C/EBPalpha mutations in acute myeloid leukaemia". Br. J. Haematol. 123 (3): 413–9. PMID 14616999.
- ↑ Mueller BU, Pabst T, Osato M, Asou N, Johansen LM, Minden MD, Behre G, Hiddemann W, Ito Y, Tenen DG (August 2002). "Heterozygous PU.1 mutations are associated with acute myeloid leukemia". Blood. 100 (3): 998–1007. PMID 12130514.
- ↑ Lisovsky M, Estrov Z, Zhang X, Consoli U, Sanchez-Williams G, Snell V, Munker R, Goodacre A, Savchenko V, Andreeff M (November 1996). "Flt3 ligand stimulates proliferation and inhibits apoptosis of acute myeloid leukemia cells: regulation of Bcl-2 and Bax". Blood. 88 (10): 3987–97. PMID 8916965.
- ↑ Franke TF, Hornik CP, Segev L, Shostak GA, Sugimoto C (December 2003). "PI3K/Akt and apoptosis: size matters". Oncogene. 22 (56): 8983–98. doi:10.1038/sj.onc.1207115. PMID 14663477.
- ↑ Nosaka T, Kawashima T, Misawa K, Ikuta K, Mui AL, Kitamura T (September 1999). "STAT5 as a molecular regulator of proliferation, differentiation and apoptosis in hematopoietic cells". EMBO J. 18 (17): 4754–65. doi:10.1093/emboj/18.17.4754. PMC 1171548. PMID 10469654.
- ↑ Lin AW, Barradas M, Stone JC, van Aelst L, Serrano M, Lowe SW (October 1998). "Premature senescence involving p53 and p16 is activated in response to constitutive MEK/MAPK mitogenic signaling". Genes Dev. 12 (19): 3008–19. PMC 317198. PMID 9765203.
- ↑ Pomerantz J, Schreiber-Agus N, Liégeois NJ, Silverman A, Alland L, Chin L, Potes J, Chen K, Orlow I, Lee HW, Cordon-Cardo C, DePinho RA (March 1998). "The Ink4a tumor suppressor gene product, p19Arf, interacts with MDM2 and neutralizes MDM2's inhibition of p53". Cell. 92 (6): 713–23. PMID 9529248.
- ↑ Zhang Y, Xiong Y, Yarbrough WG (March 1998). "ARF promotes MDM2 degradation and stabilizes p53: ARF-INK4a locus deletion impairs both the Rb and p53 tumor suppression pathways". Cell. 92 (6): 725–34. PMID 9529249.
- ↑ Buchholz F, Refaeli Y, Trumpp A, Bishop JM (August 2000). "Inducible chromosomal translocation of AML1 and ETO genes through Cre/loxP-mediated recombination in the mouse". EMBO Rep. 1 (2): 133–9. doi:10.1038/sj.embor.embor610. PMC 1084259. PMID 11265752.
- ↑ Redner RL, Rush EA, Faas S, Rudert WA, Corey SJ (February 1996). "The t(5;17) variant of acute promyelocytic leukemia expresses a nucleophosmin-retinoic acid receptor fusion". Blood. 87 (3): 882–6. PMID 8562957.
- ↑ Kiyoi H, Towatari M, Yokota S, Hamaguchi M, Ohno R, Saito H, Naoe T (September 1998). "Internal tandem duplication of the FLT3 gene is a novel modality of elongation mutation which causes constitutive activation of the product". Leukemia. 12 (9): 1333–7. PMID 9737679.
- ↑ Kelly LM, Kutok JL, Williams IR, Boulton CL, Amaral SM, Curley DP, Ley TJ, Gilliland DG (June 2002). "PML/RARalpha and FLT3-ITD induce an APL-like disease in a mouse model". Proc. Natl. Acad. Sci. U.S.A. 99 (12): 8283–8. doi:10.1073/pnas.122233699. PMC 123059. PMID 12060771.
- ↑ Muller-Tidow, C.; Steffen, B.; Cauvet, T.; Tickenbrock, L.; Ji, P.; Diederichs, S.; Sargin, B.; Kohler, G.; Stelljes, M.; Puccetti, E.; Ruthardt, M.; deVos, S.; Hiebert, S. W.; Koeffler, H. P.; Berdel, W. E.; Serve, H. (2004). "Translocation Products in Acute Myeloid Leukemia Activate the Wnt Signaling Pathway in Hematopoietic Cells". Molecular and Cellular Biology. 24 (7): 2890–2904. doi:10.1128/MCB.24.7.2890-2904.2004. ISSN 0270-7306.
- ↑ . doi:10.1101/gad.14.11.1319. Missing or empty
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(help) - ↑ Austin TW, Solar GP, Ziegler FC, Liem L, Matthews W (May 1997). "A role for the Wnt gene family in hematopoiesis: expansion of multilineage progenitor cells". Blood. 89 (10): 3624–35. PMID 9160667.
- ↑ 34.0 34.1 34.2 Langabeer SE, Preston L, Kelly J, Goodyer M, Elhassadi E, Hayat A (2017). "Molecular Profiling: A Case of ZBTB16-RARA Acute Promyelocytic Leukemia". Case Rep Hematol. 2017: 7657393. doi:10.1155/2017/7657393. PMC 5424191. PMID 28529810.
- ↑ Falchi L, Verstovsek S, Ravandi-Kashani F, Kantarjian HM (2016). "The evolution of arsenic in the treatment of acute promyelocytic leukemia and other myeloid neoplasms: Moving toward an effective oral, outpatient therapy". Cancer. 122 (8): 1160–8. doi:10.1002/cncr.29852. PMC 5042140. PMID 26716387.
- ↑ 36.0 36.1 36.2 36.3 36.4 36.5 Park J, Jurcic JG, Rosenblat T, Tallman MS (2011). "Emerging new approaches for the treatment of acute promyelocytic leukemia". Ther Adv Hematol. 2 (5): 335–52. doi:10.1177/2040620711410773. PMC 3573416. PMID 23556100.
- ↑ 37.0 37.1 37.2 Chen C, Huang X, Wang K, Chen K, Gao D, Qian S (2018). "Early mortality in acute promyelocytic leukemia: Potential predictors". Oncol Lett. 15 (4): 4061–4069. doi:10.3892/ol.2018.7854. PMC 5835847. PMID 29541170.