Treatment with alkylating agents or radiophosphorous (32P) has been shown to carry a certain leukemogenic risk in myeloproliferative disorders (MPDs), including essential thrombocytemia (ET). The leukemogenic risk associated to treatment with hydroxyurea in ET, on the other hand, is generally considered to be relatively low. Between 1970 and 1991, we diagnosed ET in 357 patients, who were monitored until 1996. One or several therapeutic agents had been admistered to 326 patients, including hydroxyurea (HU) in 251 (as only treatment in 201), pipobroman in 43, busulfan in 41, and32P in 40. With a median follow-up duration of 98 months, 17 patients (4.5%) had progressed to acute myeloid leukemia (AML; six cases) or myelodysplastic syndrome (MDS; 11 cases). Fourteen of these patients had received HU, as sole treatment in seven cases, and preceded or followed by other treatment in seven cases, mainly pipobroman (five cases). The remaining three leukemic progressions occurred in patients treated with 32P (two cases) and busulfan (one case). The incidence of AML and MDS after treatment, using 32P alone and 32P with other agents, busulfan alone and with other agents, HU alone and with others agents, and pipobroman alone and with other agents was 7% and 9%, 3% and 17%, 3.5% and 14%, and 0% and 16%, respectively. Thirteen of 17 patients who progressed to AML or MDS had successful cytogenetic analysis. Seven of them had rearrangements of chromosome 17 (unbalanced translocation, partial or complete deletion, isochromosome 17q) that resulted in 17p deletion. They also had a typical form of dysgranulopoiesis combining pseudo Pelger Hüet hypolobulation and vacuoles in neutrophils, and p53 mutation, as previously described in AML and MDS with 17p deletion. Those seven patients had all received HU, as the only therapeutic agent in three, and followed by pipobroman in three. The three patients who had received no HU and progressed to AML or MDS had no 17p deletion. A review of the literature found cytogenetic analysis in 35 cases of AML and MDS occurring after ET, 11 of whom had been treated with HU alone. Five of 35 patients had rearrangements that resulted in 17p deletion. Four of them had been treated with HU alone. These results show that treatment with HU alone is associated with a leukemic risk of approximately 3.5%. A high proportion of AML and MDS occurring in ET treated with HU (alone or possibly followed by pipobroman) have morphologic, cytogenetic, and molecular characteristics of the 17p syndrome. These findings suggest that widespread and prolonged use of HU in ET may have to be reconsidered in some situations, such as asymptomatic ET.

ESSENTIAL THROMBOCYTHEMIA (ET) is a clonal myeloproliferative disorder (MPD)1 characterized by a persistent increase in platelet counts. Progression of ET to acute myeloid leukemia (AML), preceded or not by myelodysplastic syndrome (MDS), has been observed in 3% to 4% of cases, and, until recently, mostly in patients who had received treatment with radiophophorous (32P) or alkylating agents, especially busulfan.2-15 Hydroxyurea (HU), which is considered to have relatively low leukemogenic potential, has therefore been widely used in ET in recent years. No characteristic morphologic or cytogenetic features of AML and MDS occurring during the course of ET have been described, by comparison to other therapy-related cases of AML or MDS.2-15 

Recently, we and others reported, in AML and MDS, a strong correlation between 17p deletion, resulting from unbalanced translocations between 17p and another chromosome or less often from monosomy 17 or i(17q), typical dysgranulopoiesis combining pseudo Pelger Hüet hypolobulation and small vacuoles in neutrophils, and p53 mutation.16,17 This correlation suggested that a new morphologic-cytogenetic-molecular entity or syndrome could be described in MDS and AML. Approximately 30% of patients with these characteristics had received chemotherapy for a prior neoplasm.16 

We reviewed cases of AML and MDS occurring in 357 ET patients diagnosed from 1970 to 1991 in two hematologic centers and monitored until August 1996. Seventeen cases of AML and MDS were observed, generally in patients treated exclusively or predominantly with HU. Seven of them had 17p deletions and other characteristics of the 17psyndrome.

Patients.

Between 1970 and January 1991, the diagnosis of ET was made at two institutions (Centre Hospitalier Universitaire [CHU], Lille, and Hopital St Philibert, Lomme, France) in 357 patients, according to the following criteria: (1) platelet count greater than 700 × 109/L on two different counts separated by a 1-month interval; (2) no known cause for reactive thrombocytosis, ie, no iron deficiency based on normal serum iron level and transferrin-binding capacity, presence of stainable iron in marrow, and, in recent patients, normal serum ferritin; absence of inflammatory disease based on normal values of erythrocyte sedimentation rate, protein electrophoresis, and serum fibrinogen level; absence of splenectomy or of an underlying neoplasm; and (3) exclusion of thrombocytosis of other myeloproliferative disorders, ie, normal total erythrocyte volume considered when, in the absence of iron deficiency, the hematocrit was greater than 47% in women and 50% in men; absence of myelofibrosis when a leukoerythroblastic reaction or morphologic abnormalities of erythrocytes was present; absence of Philadelphia chromosome when hematologic data were compatible with chronic myelogenous leukemia (CMI) with thrombocythemic onset; and absence of MDS, such as acquired idiopathic sideroblastic anemia or the 5q-syndrome, both of which can be associated with thrombocytosis.

The Lille center started to diagnose ET patients in 1970, and the Lomme center in 1982. Characteristics of the 147 patients diagnosed in Lille before July 1987, and their follow-up data to July 1988, have been previously reported.5 Follow-up data of patients from the two centers were analyzed on the reference date of August 31, 1996.

Treatment.

Cytoreductive therapy was generally started when patients met one of the following criteria: platelet count greater than 1 × 1012/L; age older than 65 years; symptomatic disease; and presence of another major risk factor for vascular disease (diabetes mellitus, severe hypertension, hypercholesterolemia, or heavy smoking), or of previous symptomatic artery disease (involving the coronary, cerebral or legs arteries).

Until 1980, first-line therapy generally consisted of busulfan (6 mg/d) or 32P (0.1 mCi/kg). After 1980, first-line therapy was generally with HU (at the starting dose of 1.5 g/d), except in some elderly patients who still received 32P. In patients in whom HU did not allow permanent control of platelet counts at less than 0.5 × 109/L, HU was generally replaced by pipobroman (Vercyte; Abbott, Rungis, France) at the starting dose of 1 mg/kg/day. Indeed, after several of our ET patients had experienced thrombotic episodes at platelet counts of 0.5 to 0.6 × 109/L, we had aimed, in patients in whom treatment indicated, to maintain platelet counts at less than 0.5 × 109/L.5 

Overall, 326 of 357 patients had received at least one cytoreductive agent, including 32P in 40 patients, busulfan in 41, HU in 251, pipobroman in 43, and other drugs in five.

Methods.

Cytogenetic analysis was performed with conventional banding techniques, and abnormalities were classified according to the International system for cytogenetic nomenclature.18 

MDS and AML were classified according to French-American-British (FAB) criteria.19 Bone marrow smears obtained at diagnosis of MDS and AML were reviewed, with particular emphasis on analysis of myelodysplastic features.

Analysis of p53 mutations was made by single-strand conformation polymorphism (SSCP) analysis of exons 4 to 10 of the p53 gene and/or by immunocytochemical analysis of p53 protein using monoclonal antibodies, as previously described.20 

Statistical analysis were performed with the chi-square test or Fisher's exact test.

Clinical and hematologic features of cases of AML and MDS occurring after ET.

With a median follow-up duration of 98 months (range, 22 to 265), 17 (4.5%) patients had progressed to AML (six cases) or MDS (11 cases). Fourteen cases were diagnosed among 334 patients monitored in Lille, and three among 23 patients monitored in Lomme. The characteristics and outcome of those patients are listed in Table1. Fourteen patients had received HU, during a median period of 53 months (range, 3 to 96); seven of them had received HU alone, and seven had also received other treatments, including pipobroman in five (during a median period of 48 months; range, 4 to 76), 32P in one, melphalan in one, and busulfan in one (one patient had received three successive treatment regimens). The remaining three patients had received no HU, but had received32P alone in two cases and busulfan alone in one case.

The median age of the 17 patients at diagnosis of ET was 62 years (range, 30 to 75), and there were 11 men and six women. The median interval between diagnosis of ET and diagnosis of AML or MDS was 84 months (range, 55 to 147). Six patients had AML not preceded by a phase of MDS, including five with M2 and one with M4 AML. Eleven patients had MDS, including refractory anemia (RA) in two cases, refractory anemia with excess of blasts (RAEB) in one, RAEB in transformation (RAEB-T) in six, and chronic myelomonocytic leukemia (CMML) in two. After the diagnosis of AML or MDS was made, two patients received intensive chemotherapy and one received low-dose cytarabine, with no response. Two patients were allografted as first-line therapy: one relapsed after 3 months and died, and one remained in complete remission after 72 months. The remaining patients were treated symptomatically. All patients except the allografted patient who was still in complete remission had died 1 to 36 months (median, 6) after the diagnosis of MDS or AML.

Cytogenetic and molecular features of AML and MDS occurring after ET.

Thirteen of 17 patients had successful cytogenetic analysis at the time of progression to AML or MDS. Seven of them (41% of the 17 patients, and 54% of the karyotyped cases) had 17p deletions, resulting from unbalanced translocation between 17p and another chromosome in three cases (chromosome 5 in two and undetermined chromosome in one), del 17p in one, i(17q) in one, and monosomy 17 in the two remaining patients. Six of seven patients with a 17p deletion had additional cytogenetic abnormalities, involving in particular chromosome 5 and/or 7 (Table 1). Typical dysgranulopoiesis, including pseudo Pelger Hüet hypolobulation and small vacuoles in greater than 5% neutrophils, as previously described,16,17 was seen in all of them. p53 mutation by SSCP analysis and/or p53 overexpression by immunocytochemistry (which in our experience in MDS and AML is always associated with the presence of a p53 missense mutation)20 was demonstrated in the six assessable cases.

The remaining patients had normal cytogenetics (two cases), complex cytogenetic findings without 17p involvement, where chromosome 5 but not 7 was involved (three cases), isolated acquired trisomy 21 (one case), or were not karyotyped (four cases). None of the 10 patients without 17p deletion had dysgranulopoı̈esis typical of 17p deletion cases and, among them, none of the four who were tested had a p53 mutation and/or overexpression.

Nine of 17 patients who progressed to AML or MDS had been karyotyped at diagnosis of ET, and cytogenetic findings were normal in all nine. They included five patients who had 17p deletions at the time of progression.

Incidence and features of AML and MDS according to cytoreductive treatment.

The incidence of progression to AML and MDS according to cytoreductive treatment is shown in Table 2. It was 7.5% after 32P (7% after 32P alone), 5% after busulfan (3% after busulfan alone), 5.5% after HU (3.5% after HU alone), and 12% after pipobroman (zero of 12 patients treated with pipobroman alone). Differences were not significant among the four agents when used alone. However, progression was significantly more frequent after HU combined with other agents (seven of 50) than after HU alone (seven of 201, P = .01) and after one of the three other agents used alone (three of 76, P = .04)

The seven patients who progressed to AML and MDS with a 17p deletion had all received HU, as the sole cytoreductive agent in three of them, preceded or followed by pipobroman in three, and by busulfan and32P in one case each. The median duration of treatment with HU in those seven patients had been 57 months. The three cases of AML or MDS that occurred in patients who had not received HU showed no 17p rearrangement. Thus, four cases of AML and MDS with 17p deletion occurred among 50 patients treated with HU and other drugs, as compared with three cases among 201 patients treated with HU alone (P = .03) and none among 106 patients who received no HU (P = .02).

The incidence of AML and MDS during the course of ET observed in this study where prolonged follow-up data were available in most patients (4.5%), was similar to that previously reported in other series of ET. Indeed, by combining the 14 published series (to our knowledge) of ET that included more than 30 patients,2-15 an incidence of progression to MDS or AML of 3.5% was found.

Most of the patients who developed MDS or AML in our study had received HU, generally for prolonged periods, and HU was the only cytoreductive agent used in seven of them. The incidence of MDS and AML in patients who had received HU alone was not significantly different than that of patients who had received busulfan alone or 32P alone, two treatments that are known to be leukemogenic. Most of our ET patients diagnosed before 1980 had received busulfan or 32P. After 1980, to avoid the leukemogenic effects of busulfan and32P, patients were generally treated with HU. However, in Lille, we observed only one progression to AML among the first 147 patients monitored until 1988,5 whereas 13 new cases were diagnosed between 1988 and 1996.

These findings confirm that HU has some leukemogenic potential in ET. HU is a nonalkylating myelosuppressive agent that inhibits DNA synthesis by inhibition of ribonucleoside diphosphate reductase, but also inhibits DNA repair.21 The leukemogenic potential of HU has been mainly studied in polycythemia vera (PV). In PV treated with HU alone, the incidence of progression to AML had initially been reported to be only 1% to 3% in two cohorts of approximately 100 cases followed over a median of 5 years.22,23 This was less than the 6% to 10% and 12% to 13% reported after 32P and chlorambucil, respectively, by the PV Study Group (PVSG) and other groups.24,25 On the other hand, the incidence of progression to AML in PV treated with HU alone was 8% at 12 years and 5.9% at 8.5 years in two recently published large series with prolonged follow-up evaluation26,27 as compared with 1.5% after phlebotomy alone.27 To our knowledge, after excluding cases with Philadelphia chromosome at diagnosis, 103 cases of acute leukemia and MDS occurring during the course of ET have been reported.2-15,30-60 Seven of them were acute lymphocytic leukemia and the remaining cases were AML or MDS. At least 34 of them had been treated with HU, and 19 with HU alone (Table3). By combining published series of ET in which treatment and evolution were available,2-15 we found that 10 of 293 patients (3.4%) treated with HU alone had progressed to acute leukemia, a figure similar to our results.

In PV, long-term results of a large study that randomized patients to receive, after a first course of 32P, maintenance with HU versus no maintenance (and additional 32P if required) showed a significantly higher incidence of AML in the group maintained with HU, although the other group had received higher cumulative doses of 32P.28 In another study, leukemias in ET treated with HU occurred mainly in patients who, because of incomplete response to this drug, were switched to alkylating agents.29 Thus, HU also appears to increase the leukemic risk of other cytoreductive treatments administered in PV and ET. Our findings of a significantly higher incidence of evolution to AML and MDS in patients treated with HU and other agents as compared with HU alone or with other agents alone are in agreement with those reports.

Five of 17 patients reported here had, in addition to HU, received pipobroman, a bromide derivative of piperazine, which, although its formula is close to that of the alkylating agents, mainly appears to act as a metabolic competitor of pyrimidine bases.61Pipobroman, in our experience and that of some other groups, often allows better control of platelet counts than HU.5,62 Three of the five MDS and AML cases occurring in patients who had received pipobroman had 17p deletions. The incidence of AML and MDS in patients who had received pipobroman was relatively high (12%), but AML and MDS occurred in patients who had also received other drugs, and none of the 12 patients treated with pipobroman alone had leukemic evolution. This suggests that the leukemic risk of pipobroman is found mainly in patients who also received other drugs, principally HU in our experience. Pipobroman has not been widely used in ET, and the risk of leukemia with this drug has not been previously well defined. In two series of 21 and 24 ET patients treated with pipobroman, no progression to AML had occurred, but the follow-up duration was relatively short.63,64 In PV, the risk of leukemia after pipobroman was considered to be 6% and 9% after 5 and 7 years of treatment, respectively, in one series,65 and 4.5% in another.66 Recently, in a randomized prospective study, it was evaluated at 8% after 12 years, similar to that observed with HU.26 

Our study also found that approximately 40% of the AML and MDS cases occurring in ET treated predominantly with HU had 17p deletions and other characteristics of what we and others described as the 17p syndrome, ie, typical dysgranulopoiesis and p53 mutation.16,17 The seven ET patients who progressed to AML or MDS with a 17p deletion presented here had all received HU, which, in three of them, was the only antineoplastic agent used, whereas three other cases had also received pipobroman. Of the 103 cases of transformed ET reported until now, to our knowledge, 35 had cytogenetic analysis, and 17p deletion was found in five patients.4,13,42,51 Three of these five patients had monosomy 17 and additional complex cytogenetic findings, one had i(17q) (Table 4), and the last patient had deletion of chromosome 17.51 Four of these five patients had received HU as the sole antineoplastic agent, during 17, 24, 64, and 92 months, respectively (Table 4), and the last patient51 had received busulfan and low-dose cytarabine. At transformation, they were classified as M2 AML, acute undifferentiated leukemia, Mo AML, and RAEB-T, respectively, in four cases (Table 4), and not classified in the last case.51 No mention of dysgranulopoiesis was made in the five case reports. Patients with 17p deletions after treatment with HU alone constituted four of the 11 reported cases of ET that progressed to MDS or AML after HU alone and where karyotype was available (Table 3).

Morphologic, cytogenetic, and molecular features of the 17p syndrome have not only been reported in AML and MDS, but also in CML in blast crisis. Indeed, in blast crisis CML, Sessarego et al67 found a strong correlation between pseudo Pelger Hüet hypolobulation and 17p deletion, often resulting from i(17q). Furthermore, in blast crisis CML, a correlation between p53 mutation and 17p deletion has been reported.68 Because blast crisis is the “natural” evolution of CML, one could suggest that blast crisis of other myeloproliferative disorders with features of the 17p syndrome could also result from their natural evolution. However, in untreated ET, leukemic evolution appears to be rare: only two of 46 evolutions of ET to acute leukemia recorded in large series of patients (Table 3) occurred in untreated patients.

The relatively high incidence of chromosome 17 involvement in MDS and AML following ET treated by HU in the literature and our findings suggests that prolonged use of HU in ET may lead to or at least increase the risk of MDS and AML with loss of 17p chromosomal material and p53 mutation. The incidence was particularly high (four of 50 cases) in patients treated with HU and other drugs. In particular, three cases occurred in patients who had received HU and pipobroman. Thus, a role for pipobroman in the pathogenesis of MDS and AML with 17p deletion, which could be additive to that of HU, is also possible in ET. Recently, Gaidano et al69 also found p53 mutations in four of 10 cases of AML following ET, in a study so far published only in abstract form. No data on treatment received by those patients was available, but they came from centers in which HU is generally used as first-line therapy in ET. Data on dysgranulopoiesis and karyotype at the time of progression to AML were not available. However, because of the high correlation between 17p deletion and p53 mutations observed in myeloid malignancies,15,16,67 70 it is probable that several of those patients had 17p deletions.

Overall, our findings in a large series of patients, with prolonged follow-up evaluation, confirm a certain leukemogenic potential for HU in ET. The use of HU probably also increases the leukemic risk of other cytoreductive treatments given in ET. We also found that MDS and AML occurring after treatment with HU (and possibly pipobroman) often had a 17p deletion, confirming a few previously published case reports. However, our findings need to be confirmed. We therefore encourage the publication of all cases of AML and MDS occurring during the course of ET treated with HU, with special emphasis on their morphologic and cytogenetic characteristics. Description of larger numbers of MDS and AML with 17p deletions after HU could lead to reconsideration of the widespread use of this drug and to more limited use, for instance, in asymptomatic ET. It would also possibly encourage larger use of drugs that are probably nonleukemogenic, such as interferon and anagrelide,62 when treatment is required in ET. From a more fundamental viewpoint, description of other cases of MDS and AML with 17p deletion after HU would also point to a possible relationship between HU and genes located in chromosome 17 (including the p53 gene), whose disruption could participate in the leukemogenic process.

Address reprint requests to Pierre Fenaux, MD, Service des Maladies du Sang, CHU, 1 place de Verdun, 59037 Lille, France.

The publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked “advertisement” in accordance with 18 U.S.C. section 1734 solely to indicate this fact.

1
Fialkow
PJ
Faguet
GR
Jacobson
RJ
Vaidya
K
Murphy
S
Evidence that essential thrombocythemia is a clonal disorder within a multipotent stem cell.
Blood
58
1981
916
2
Cervantes
F
Tassies
D
Salgado
C
Rovira
M
Pereira
A
Rozman
C
Acute transformation in nonleukemic chronic myeloproliferative disorders: Actuarial probability and main characteristics in a series of 218 patients.
Acta Haematol
85
1991
124
3
Chistolini
A
Mazzucconi
MG
Ferrari
A
La Verde
G
Ferrazza
G
Dragoni
F
Vitale
A
Arcieri
R
Mandelli
F
Essential thrombocythemia: A retrospective study on the clinical course of 100 patients.
Haematologica
75
1990
537
4
Löfvenberg
E
Nordenson
I
Wahlin
A
Cytogenetic abnormalities and leukemic transformation in hydroxyurea treated patients with Philadelphia chromosome negative chronic myeloproliferative disease.
Cancer Genet Cytogenet
49
1990
57
5
Fenaux
P
Simon
M
Caulier
MT
Laı̈
JL
Goudemand
J
Bauters
F
Clinical course of essential thrombocythemia in 147 cases.
Cancer
66
1990
549
6
Kwong
YL
Liang
RHS
Chui
EKW
Lie
AKW
Chan
LC
Todd
D
Chan
TK
Essential thrombocythemia: A retrospective analysis of 39 cases.
Am J Hematol
49
1995
39
7
Bellucci
S
Janvier
M
Tobelem
G
Flandrin
G
Charpak
Y
Berger
R
Boiron
M
Essential thrombocythemias: Clinical evolutionary and biological data.
Cancer
58
1986
2440
8
Hehlmann
R
Jahn
M
Baumann
B
Köpcke
W
Essential thrombocythemia: Clinical characteristics and course of 61 cases.
Cancer
61
1988
2487
9
Sessarego
M
Defferrari
R
Dejana
AM
Rebuttato
AM
Fugazza
G
Salvidio
E
Ajmar
F
Cytogenetic analysis in essential thrombocythemia at diagnosis and at transformation. A 12 years study.
Cancer Genet Cytogenet
43
1989
57
10
Cortelazzo
S
Finazzi
G
Ruggeri
M
Vestri
O
Galli
M
Rodeghiero
F
Barbui
T
Hydroxyurea for patients with essential thrombocythemia and high risk of thrombosis.
N Engl J Med
332
1995
1132
11
Hattori
A
Nagayama
R
Kishi
K
Fuse
I
Hanano
M
Takizawa
SI
Takeshiga
T
Shibata
A
Primary thrombocythemia in Japan: A survey of 225 patients.
Leuk Lymphoma
4
1991
177
12
(suppl 1, abstr)
Turlure
P
Le Prise
PY
Letortorec
S
Linassier
C
Ifrah
N
Desablens
B
Tourani
JM
Lejeune
F
Sensebe
L
Briere
JB
Essential thrombocythemia. Clinical course and results of a multicenter prospective study.
Blood
82
1993
197a
13
Colombi
M
Radaelli
F
Zocchi
L
Maiolo
AT
Thrombotic and hemorragic complications in essential thrombocythemia. A retrospective study of 103 patients.
Cancer
67
1991
2926
14
Liozon
E
Brigaudeau
C
Trimoreau
F
Desangles
F
Fermeaux
V
Praloran
V
Bordessoule
D
Is treatment with hydroxyurea leukemogenic in patients with essential thrombocythemia? An analysis of three new cases of leukaemic transformation and review of the literature.
Hematol Cell Ther
39
1997
11
15
Peterson P, Murphy S, Iland HJ, Geller SA, Ellis JT: Occurrence of acute leukemia in treated essential thrombocythemia. Lab Invest 70:118-A, 1994
16
Lai
JL
Preudhomme
M
Zandecki
M
Flactif
M
Vanrumbeke
M
Wattel
E
Fenaux
P
Myelodysplastic syndromes and acute myeloid leukemia with 17p deletion. An entity characterized by specific dysgranulopoiesis and a high incidence of p53 mutations.
Leukemia
8
1995
1342
17
Jary
L
Mossafa
H
Fourcade
C
Genet
P
Pulik
M
Flandrin
G
The 17p-syndrome: A distinct myelodysplastic syndrome entity?
Leuk Lymphoma
25
1997
163
18
International System for Cytogenetic Nomenclature: Guidelines for cancer cytogenetics. Supplement to Mitelman T (ed): An International System for Human Cytogenetic Nomenclature. Basel, Switzerland, Karger, 1991
19
Bennett
JM
Catovsky
D
Daniel
MT
Flandrin
G
Galton
D
Gralnick
H
Sultan
C
Proposals for the classification of the myelodysplastic syndromes.
Br J Haematol
51
1982
189
20
Lepelley
P
Preudhomme
C
Vanrumbeke
M
Quesnel
B
Cosson
A
Fenaux
P
Detection of p53 mutations in hematological malignancies: Comparison between immunocytochemistry and DNA analysis.
Leukemia
8
1994
1342
21
(suppl 9)
Yarbro
JW
Mechanism of action of hydroxyurea.
Semin Oncol
19
1992
1
22
Donovan
PB
Kaplan
ME
Golberg
JD
Treatment of polycythemia vera with hydroxyurea.
Am J Hematol
17
1984
329
23
West
WO
Hydroxyurea in the treatment of polycythemia vera: A prospective study of 100 patients over a 20 year period.
South Med J
80
1987
323
24
Landaw
SA
Acute leukemia in polycythemia vera.
Semin Hematol
23
1986
156
25
Najean
Y
Deschamps
A
Dresch
C
Faille
C
Rain
JD
Acute leukemia and myelodysplasia in polycythemia vera. A clinical study with long-term follow-up.
Cancer
61
1988
89
26
Najean
Y
Rain
JD
Treatment of polycythemia vera: The use of hydroxyurea and pipobroman in 242 patients under the age of 65 years.
Blood
90
1997
3370
27
Berk PD, Wasserman LR, Fruchtman SM, Golberg JD: Treatment of Polycythemia Vera. A Summary of Clinical Trials Conducted by the PVSG. Philadelphia, PA, Saunders, 1995, p 166
28
Najean
Y
Rain
JD
Treatment of polycythemia vera. Use of 32P alone or in combination with maintenance therapy using hydroxyurea in 434 patients over the age of 65 years.
Blood
89
1997
2319
29
(abstr)
Murphy
S
Peterson
P
Iland
HJ
Fruchtman
S
Hydroxyurea and other myelosuppressive agents in the treatment of essential thrombocytemia: Analysis of leukemogenic potential.
Thromb Haemost
69
1993
564a
30
Furgerson
JL
Vukelja
SJ
Baker
WJ
O'Rourke
TJ
Acute myeloid leukemia evolving from essential thrombocythemia in two patients treated with hydroxyurea.
Am J Hematol
51
1996
137
31
Van Den Anker-Lugtenburg
PJ
Sizoo
W
Myelodysplastic syndrome and secondary acute leukemia after treatment of essential thrombocythemia with hydroxyurea.
Am J Hematol
33
1990
152
32
Murphy
PT
Sivakumaran
M
Van Rhee
F
Watmoret
AE
Mitchell
VE
Acute lymphoblastic transformation of essential thrombocythaemia.
Br J Haematol
89
1995
921
33
Ferrari
D
Ticozzelli
G
De Vizzi
M
Corigliano
P
De Vizzi
G
Essential thrombocythemia and acute leukemia.
Haematologica
78
1993
401
34
Weinfeld
A
Swolin
B
Westin
J
Acute leukaemia after hydroxyurea therapy in polycythaemia vera and allied disorders: Prospective study of efficacy and leukaemogenicity with therapeutic implications.
Eur J Haematol
52
1994
134
35
Higuchi
T
Okada
S
Mori
H
Niikura
H
Omine
M
Terada
H
Leukemic transformation of polycythemia vera and essential thrombocythemia possibly associated with an alkylating agent.
Cancer
75
1995
471
36
Shibata
K
Shimamoto
Y
Suga
K
Sano
M
Matsuzaki
M
Yamaguchi
M
Essential thrombocythemia terminating in acute leukemia with minimal myeloid differentiation—A brief review of recent literature.
Acta Haematol
91
1994
84
37
Sedlacek
SM
Curtis
JL
Weintraub
J
Levin
J
Essential thrombocythemia and leukemic transformation.
Medicine
65
1986
353
38
(suppl 3)
Lopes
E
Ribeiro
MM
Silva
MJ
Gandra
M
Principe
F
Granato
C
Essential thrombocythemia. Clinical features, therapy and follow-up of 12 cases.
Leukemia
6
1992
138s
39
Boros
L
Markhan
RE
Brernan
JK
Primary thrombocythemia and acute leukemia.
JAMA
253
1985
1721
40
O'Hea
AM
Erber
W
O'Connor
NTJ
Bunch
C
Acute transformation of essential thrombocythaemia: Report of two cases.
J Clin Pathol
39
1986
1296
41
Kimura
A
Fujimoto
T
Inada
T
Imamura
N
Oguma
N
Kajihara
H
Mbasiwa
DN
Kahoh
O
Fujimura
K
Kuramoto
A
Blastic transformation in essential thrombocythemia In vitro differentiation of blast cells into granulocytic, erythroid, and megakaryocytic lineages.
Cancer
65
1990
1538
42
Groupe Français de Cytogénétique Hématologique: Cytogenetic of acutely transformed chronic myeloproliferative syndromes without a philadelphia chromosome: A multicenter study of 55 patients. Cancer Genet Cytogenet 32:157, 1998 (abstr)
43
Higuchi
T
Okada
S
Mori
H
Niikura
H
Omine
M
Terada
H
Leukemic transformation of polycythemia vera and essential thrombocythemia possibly associated with an alkylating agent.
Cancer
75
1995
471
44
Okuda
M
Shishido
T
Sato
A
Najai
T
Sujaware
T
Kameoba
J
Karreda
K
Mejuro
K
Fujuhera
O
Sukurai
T
Essential thrombocythemia transformed to acute myeloid leukemia.
Jpn J Clin Hematol
31
1990
1689
45
Honna
K
Blastic transformation of essential thrombocythemia. A case report.
Acta Pathol Jpn
39
1989
670
46
Woronzoff-Dashoff
K
Litz
GE
Acute lymphoblastic leukemia in a case of essential thrombocythemia.
Am J Clin Pathol
106
1996
206
47
Patino-Sarcinelli
F
Knecht
H
Pechet
L
Pihan
G
Savas
L
Snyder
M
Leukemia with megakaryocytic differentiation following essential thrombocythemia and myelofibrosis.
Acta Hematol
95
1996
122
48
Rios
R
Soli
F
Pérez
M
Gascon
F
Garcia
F
Gonzalez
PM
t(2;3) in a case of blastic transformation of essential thrombocythemia.
Br J Haematol
92
1996
769
49
Chen
YH
Mishoulam
H
Mir
JA
Choiy
S
Schadi
ST
Blastic transformation in a case of essential thrombocythemia.
South Med J
80
1987
1040
50
Emilia
G
Sacchi
S
Temperani
P
Longo
R
Vecchi
A
Progression of essential thrombocythemia to blastic crisis via idiopathic myelofibrosis.
Leuk Lymphoma
9
1993
423
51
Frei-Lahr
D
Barton
JC
Hoffman
R
Burkett
LL
Prchal
JT
Blastic transformation of essential thrombocythemia. Dual expression of myelomonoblastic/megakaryoblastic phenotypes.
Blood
63
1984
866
52
(suppl 1, abstr)
Nand
S
Stock
W
Godwin
J
Fisher
S
Leukemogenic risk of hydroxyurea therapy in polycythemia vera, essential thrombocythemia and myeloid metaplasia with myelofibrosis.
Blood
86
1995
798a
53
Geller
SA
Shapiro
E
Acute leukemia as a natural sequel to primary thrombocythemia.
Am J Clin Pathol
77
1982
353
54
Gris
JC
Schved
JF
Arnaud
A
Chawet
C
Myelodysplastic syndrome and secondary acute leukemia after treatment of essential thrombocythemia with melphalan.
Am J Hematol
30
1989
47
55
Raman
SBK
Mahmood
A
Van Slyck
EJ
Essential thrombocythemia with transition into acute leukemia.
Ann NY Acad Sci
370
1981
145
56
Vinti
H
Taillan
B
Pesce
A
Dujandin
P
Megakaryoblastic transformation of essential thrombocythemia, hypercalcemia and lytic bone lesions.
Acta Haematol
83
1990
53
57
Yonekura
S
Nagao
T
Arimori
S
Essential thrombocythemia developing into refractory anemia and complicated by acute leukemia.
Intern Med
31
1992
1224
58
Asano
Y
Naritomi
Y
Kimura
H
Maeda
Y
Kusata
T
Yoshizawa
S
Shiraishi
G
Low dose aclarubicin in blastic transformation of essential thrombocythemia.
Ann Hematol
62
1991
194
59
Toh
BT
Gregory
SA
Knospe
WH
Acute leukemia following treatment of polycythemia vera and essential thrombocythemia with uracil mustard.
Am J Hematol
28
1988
58
60
Berkhan
LC
Nelson
J
Ockelford
PA
Browett
PJ
Transformation of essential thrombocythaemia to acute lymphoblastic leukaemia.
Leuk Lymphoma
20
1996
347
61
Boivin
P
Indications, procedure and results for the treatment of polycythaemia vera by bleeding, pipobroman and hydroxyurea.
Nouv Rev Fr Hematol
35
1993
491
62
(suppl)
Barbui
T
Finazzi
G
Dupuy
E
Kiladjian
JJ
Brière
J
Treatment strategies in essential thrombocythemia. A critical appraisal of various experiences in different centers.
Leuk Lymphoma
22
1996
149
63
Mazzucconi
MG
Francesconi
M
Chistolini
A
Falcione
E
Ferrari
A
Tirindelli
MC
Mandelli
F
Pipobroman therapy of essential thrombocythemia.
Scand J Haematol
37
1986
306
64
Brusamolino
E
Canevari
A
Salvaneschi
L
Merante
S
Bernasconi
C
Efficacy trial of pipobroman in essential thrombocythemia. A study of 24 patients.
Cancer Treat Rep
68
1984
1339
65
Brusamolino
E
Salvaneschi
L
Canevari
A
Bernasconi
C
Efficacy trial of pipobroman in polycythemia vera and incidence of acute leukemia.
J Clin Oncol
2
1984
558
66
Najman
A
Stachowiak
J
Parlier
Y
Gorin
NC
Duhamel
G
Pipobroman therapy of polycythemia vera.
Blood
59
1982
890
67
Sessarego
M
Ajmar
F
Correlation between acquired pseudo-Pelger-Huët anomaly and involvement of chromosome 17 in chronic myeloid leukemia.
Cancer Genet Cytogenet
25
1987
265
68
Ahuja
H
Bar Eli
E
Arlin
Z
The spectrum of molecular alterations in the evolution of chronic myeloid leukemia.
J Clin Invest
87
1991
2042
69
(suppl 1, abstr)
Gaidano
G
Pastore
C
Santini
A
Gamberi
B
Resegotti
L
Mazza
U
Rossi Ferrini
P
Lo Coco
F
Saglio
G
Blastic transformation of polycythemia vera and essential thrombocythemia frequently associates with mutations of p53.
Blood
88
1996
98a
70
Fenaux
P
Jonveaux
P
Quiquandon
I
Lai
JL
Pignon
JM
Loucheux-Lefebvre
MH
Bauters
F
Berger
R
Kerckaert
JP
P53 gene mutations in acute myeloid leukemia with 17p monosomy.
Blood
78
1991
1652
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