Detection of Early Precursors of t(12;21) Positive Pediatric Acute Lymphoblastic Leukemia During Follow-Up

被引：3

作者：

Laszlo, Renata

Alpar, Donat

Kajtar, Bela

Lacza, Agnes

Ottoffy, Gabor ^{[2
]}

Kiss, Csongor ^{[3
]}

Bartyik, Katalin ^{[4
]}

Nagy, Kalman ^{[5
]}

Pajor, Laszlo ^{[1
]}

机构：

[1] Univ Pecs, Dept Pathol, Fac Med, Med Ctr, H-7624 Pecs, Hungary

[2] Univ Pecs, Med Ctr, Dept Pediat Oncol, H-7624 Pecs, Hungary

[3] Univ Debrecen, Med Ctr, Dept Pediat Oncol, H-4012 Debrecen, Hungary

[4] Univ Szeged, Med Ctr, Dept Pediat Oncol, Szeged, Hungary

[5] Borsod Cty Teaching Hosp, Child Welf Ctr, Dept Hematol, Miskolc, Hungary

来源：

PEDIATRIC BLOOD & CANCER | 2010年 / 54卷 / 01期

关键词：

minimal residual disease; pediatric acute lymphoblastic leukemia; real-time quantitative PCR; scanning fluorescence microscopy; t(12; 21) rearrangement; MINIMAL-RESIDUAL-DISEASE; IN-SITU HYBRIDIZATION; GENE REARRANGEMENTS; PCR ANALYSIS; FUSION GENE; TARGETS; IMMUNOGLOBULIN; CELLS;

D O I：

10.1002/pbc.22300

中图分类号：

R73 [肿瘤学];

学科分类号：

100214 ;

摘要：

DNA-, RNA-, and cell-based methods provide different biologic information for determining the presence of minimal residual disease (MRD). We monitored the responses of patients with pediatric acute lymphoblastic leukemia (PALL) using DNA markers, TEL/AML1 expression, and scanning fluorescence microscopy (SFM). Using SFM, 36% of patients exhibited 1.5-3.1 log and 2.9-4.2 log higher MRD levels compared with those based on DNA and RNA markers, respectively. CD10+ ancestor cells with germline antigen receptors, but silent TEL/AML1 expression, may reside in the lymphoid stem cell compartment of treated t(12;21)-positive patients and might act as a potential source of cells for late relapses. Pediatr Blood Cancer 2010;54:158-160. (C) 2009 Wiley-Liss, Inc.

引用

页码：158 / 160

页数：3

共 44 条

[21] Involvement of der(12)t(12;21)(p13;q22) and as well as additional rearrangements of chromosome 12 homolog in ETV6/RUNX1-positive acute lymphoblastic leukemia
Stanchescu, Racheli
Betts, David R.
Rechavi, Gideon
Amariglio, Ninette
Trakhtenbrot, Luba
CANCER GENETICS AND CYTOGENETICS, 2009, 190 (01) : 26 - 32
[22] CD371-positive pediatric B-cell acute lymphoblastic leukemia: propensity to lineage switch and slow early response to treatment
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Varotto, Elena
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Gaipa, Giuseppe
Schumich, Angela
Brueggemann, Monika
Mejstrikova, Ester
Cazzaniga, Giovanni
Hrusak, Ondrej
Szczepanowski, Monika
Scarparo, Pamela
Zimmermann, Martin
Strehl, Sabine
Schinnerl, Dagmar
Zaliova, Marketa
Karawajew, Leonid
Bourquin, Jean-Pierre
Feuerstein, Tamar
Cario, Gunnar
Alten, Julia
Moericke, Anja
Biffi, Alessandra
Parasole, Rosanna
Fagioli, Franca
Valsecchi, Maria Grazia
Biondi, Andrea
Locatelli, Franco
Attarbaschi, Andishe
Schrappe, Martin
Conter, Valentino
Basso, Giuseppe
Dworzak, Michael N.
BLOOD, 2024, 143 (17) : 1738 - 1751
[23] Long-Term Follow-up of Allogeneic Hematopoietic Stem Cell Transplantation for Patients with Philadelphia Chromosome-Positive Acute Lymphoblastic Leukemia: Impact of Tyrosine Kinase Inhibitors on Treatment Outcomes
Kebriaei, Partow
Saliba, Rima
Rondon, Gabriela
Chiattone, Alexandre
Luthra, Rajyalakshmi
Anderlini, Paolo
Andersson, Borje
Shpall, Elizabeth
Popat, Uday
Jones, Roy
Worth, Laura
Ravandi, Farhad
Thomas, Deborah
O'Brien, Susan
Kantarjian, Hagop
de Lima, Marcos
Giralt, Sergio
Champlin, Richard
BIOLOGY OF BLOOD AND MARROW TRANSPLANTATION, 2012, 18 (04) : 584 - 592
[24] Nilotinib combined with multi-agent chemotherapy in newly diagnosed Philadelphia chromosome-positive acute lymphoblastic leukemia: a single-center prospective study with long-term follow-up
Liu, Bingcheng
Wang, Ying
Zhou, Chunlin
Wei, Hui
Lin, Dong
Li, Wei
Liu, Kaiqi
Zhang, Guangji
Wei, Shuning
Li, Yan
Gong, Benfa
Liu, Yuntao
Gong, Xiaoyuan
Mi, Yingchang
Wang, Jianxiang
ANNALS OF HEMATOLOGY, 2019, 98 (03) : 633 - 645
[25] Extremely low-frequency magnetic fields and survival from childhood acute lymphoblastic leukemia: an international follow-up study
Schuz, J.
Grell, K.
Kinsey, S.
Linet, M. S.
Link, M. P.
Mezei, G.
Pollock, B. H.
Roman, E.
Zhang, Y.
McBride, M. L.
Johansen, C.
Spix, C.
Hagihara, J.
Saito, A. M.
Simpson, J.
Robison, L. L.
Dockerty, J. D.
Feychting, M.
Kheifets, L.
Frederiksen, K.
BLOOD CANCER JOURNAL, 2012, 2 : e98 - e98
[26] STAT3 mediates oncogenic addiction to TEL-AML1 in t(12;21) acute lymphoblastic leukemia
Mangolini, Maurizio
de Boer, Jasper
Walf-Vorderwuelbecke, Vanessa
Pieters, Rob
den Boer, Monique L.
Williams, Owen
BLOOD, 2013, 122 (04) : 542 - 549
[27] Evaluation of complete disease remission in acute myeloid leukemia - A prospective study based on cytomorphology, interphase fluorescence in situ hybridization, and immunophenotyping during follow-up in patients with acute myeloid leukemia
Bacher, U
Kern, W
Schoch, C
Schnittger, S
Hiddemann, W
Haferlach, T
CANCER, 2006, 106 (04) : 839 - 847
[28] BIOMED-1 Concerted Action report:: Flow cytometric characterization of CD7+ cell subsets in normal bone marrow as a basis for the diagnosis and follow-up of T cell acute lymphoblastic leukemia (T-ALL)
Porwit-MacDonald, A
Björklund, E
Lucio, P
van Lochem, EG
Mazur, J
Parreira, A
van den Beemd, MWM
van Wering, ER
Baars, E
Gaipa, G
Biondi, A
Ciudad, J
van Dongen, JJM
San Miguel, JF
Orfao, A
LEUKEMIA, 2000, 14 (05) : 816 - 825
[29] BIOMED-1 Concerted Action report: Flow cytometric characterization of CD7+ cell subsets in normal bone marrow as a basis for the diagnosis and follow-up of T cell acute lymphoblastic leukemia (T-ALL)
A Porwit-MacDonald
E Björklund
P Lucio
EG van Lochem
J Mazur
A Parreira
MWM van den Beemd
ER van Wering
E Baars
G Gaipa
A Biondi
J Ciudad
JJM van Dongen
JF San Miguel
A Orfao
Leukemia, 2000, 14 : 816 - 825
[30] Treatment of higher risk acute lymphoblastic leukemia in young people (CCG-1961), long-term follow-up: a report from the Children's Oncology Group
Steinherz, Peter G.
Seibel, Nita L.
Sather, Harland
Ji, Lingyun
Xu, Xinxin
Devidas, Meenakshi
Gaynon, Paul S.
LEUKEMIA, 2019, 33 (09) : 2144 - 2154

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