Paediatric Patients Affected by Haematological Malignancies and Eligible to Undergo HSCT From an Unrelated Volunteer Clinical Trial
Official title:
Multi-Centre Prospective Randomized Study on the Use of Two Different Doses of Rabbit Anti-Thymocyte Globulin for GVHD Prevention in Paediatric Patients With Haematological Malignancies Given an Unrelated Donor Haematopoietic Stem Cell Transplantation
Paediatric patients affected by haematological malignancies and eligible to undergo HSCT
from an unrelated volunteer will be stratified according to the degree of compatibility with
their donor, the source of haematopoietic stem cells employed (BM vs. PB) and the disease
phase (good vs. poor prognosis). In particular, on the basis of compatibility with their
donor, patients will be allocated to 2 different arms: those transplanted from an unrelated
donor either perfectly matched or with a single allelic disparity at one of the HLA loci
(i.e. A, B, C, and DrB1) vs. those transplanted from an unrelated donor either with 2
allelic disparities or with an antigenic disparity at the HLA loci (i.e. A, B, C, and DrB1).
Patients enrolled in the study will be randomized to receive ATG (Fresenius) at a dosage of
either 30 mg/Kg (10 mg/Kg on days -4, -3 and -2) or 15 mg/Kg (5 mg/Kg on days -4, -3 and
-2).
Good prognosis patients are defined as follows: ALL in 1st CR; ALL in 2nd CR belonging to S2
group; AML in 1st CR, AML in 2nd CR and relapsed more than 6 months after stopping therapy;
NHL in 2nd CR; Ph+ CML in 1st CP; refractory cytopenia.
Poor prognosis patients are defined as follows: ALL in 2nd CR belonging to the S3-S4 group;
ALL in ≥ 3rd CR; AML in 2nd CR and relapsed less than 6 months after stop therapy; secondary
AML; NHL in 3rd CR; Ph+ CML in 2nd CP, as well as in AP; RAEB, RAEB-t, JMML.
Study rationale
Several reports have documented that patients given HSCT from an unrelated volunteer have:
- Increased incidence and severity of acute GVHD;
- Increased incidence and severity of chronic GVHD;
- Increased incidence of graft rejection;
- Increased risk of transplant-related death. The use of anti-thymocyte globulin (ATG)
has been demonstrated to modulate alloreactivity of T-lymphocytes, reducing the risk of
post-transplant immune complications, namely graft rejection and GVHD. However,
concerns about the use of ATG exist, in particular referring to an increased incidence
and severity of infectious complications, increased risk of malignancy recurrence and
increased risk of EBV-related PTLD.
Design of the study Paediatric patients affected by haematological malignancies and eligible
to undergo HSCT from an unrelated volunteer will be stratified according to the degree of
compatibility with their donor, the source of haematopoietic stem cells employed (BM vs. PB)
and the disease phase (good vs. poor prognosis). In particular, on the basis of
compatibility with their donor, patients will be allocated to 2 different arms: those
transplanted from an unrelated donor either perfectly matched or with a single allelic
disparity at one of the HLA loci (i.e. A, B, C, and DrB1) vs. those transplanted from an
unrelated donor either with 2 allelic disparities or with an antigenic disparity at the HLA
loci (i.e. A, B, C, and DrB1).
Patients enrolled in the study will be randomized to receive ATG (Fresenius) at a dosage of
either 30 mg/Kg (10 mg/Kg on days -4, -3 and -2) or 15 mg/Kg (5 mg/Kg on days -4, -3 and
-2).
Good prognosis patients are defined as follows: ALL in 1st CR; ALL in 2nd CR belonging to S2
group; AML in 1st CR, AML in 2nd CR and relapsed more than 6 months after stopping therapy;
NHL in 2nd CR; Ph+ CML in 1st CP; refractory cytopenia.
Poor prognosis patients are defined as follows: ALL in 2nd CR belonging to the S3-S4 group;
ALL in ≥ 3rd CR; AML in 2nd CR and relapsed less than 6 months after stop therapy; secondary
AML; NHL in 3rd CR; Ph+ CML in 2nd CP, as well as in AP; RAEB, RAEB-t, JMML.
Primary end-points
• To evaluate the influence of different ATG dosages on the incidence and severity of acute
GVHD. In particular, we expect an incidence of 50% acute grade II-IV GVHD in the lower
dosage (15 mg/Kg) arm, whereas we expect an incidence of 25% in the higher dosage (30 mg/Kg)
arm.
Secondary end-points
- To compare the incidence of chronic GVHD in the 2 ATG dosage arms.
- To compare relapse rate in the 2 ATG dosage arms.
- To compare TRM in the 2 ATG dosage arms.
- To compare EFS in the 2 ATG dosage arms
- To compare the incidence of EBV reactivation and of EBV-related post-transplant
lymphoproliferative disorders in the 2 ATG dosage arms.
- To compare the incidence of CMV reactivation in the 2 ATG dosage arms.
- To compare the incidence of adenovirus infection in the 2 ATG dosage arms.
- To compare the incidence of fungal infections in the 2 ATG dosage arms.
Study population
Patients enrolled in this study have to be affected by:
- ALL in 1st, 2nd and 3rd CR;
- AML in 1st and 2nd CR;
- NHL in 2nd and 3rd CR;
- Ph+ CML in 1st and 2nd CP, as well as in AP;
- Refractory cytopenia, RAEB, RAEB-t, JMML.
Inclusion criteria
- Unrelated donor selected using high-resolution molecular typing of HLA-A, B, C and DrB1
loci, perfectly matched or with a single allelic disparity at one of the HLA loci or
with 2 allelic disparities and with an antigenic disparity at the HLA loci;
- Age comprised between 0 and 19 years;
- Life-expectancy of at least 2 months;
- Use of G-CSF mobilized PB- or BM-derived haematopoietic stem cells
Exclusion criteria
- Unrelated donor selected using high-resolution molecular typing of HLA-A, B, C and DrB1
loci, with more than one antigenic disparity or more than 2 allelic disparities at the
HLA loci;
- Previous allogeneic HSCT;
- Cord blood as source of haematopoietic stem cells;
- Previous treatment with rabbit ATG in the last 3 months before HSCT;
- History of allergic reactions to rabbit ATG;
- Absence of written informed consent.
Stopping rules
- 30% mortality due to acute GVHD within the first 10 and 20 patients enrolled in the 15
mg/Kg arm;
- 80% incidence of grade II-IV acute GVHD within the first 10 and 20 patients enrolled in
the 15 mg/Kg arm;
- 30% fatal infections (virus and/or fungi) within the first 10 and 20 patients enrolled
in the 30 mg/Kg arm;
- 50% relapse rate within the first 10 and 20 patients enrolled in the 30 mg/Kg arm;
- 80% CMV reactivation within the first 10 and 20 patients enrolled in the 30 mg/Kg arm;
- 50% EBV reactivation within the first 10 and 20 patients enrolled in the 30 mg/Kg arm;
- 30% adenovirus reactivation within the first 10 and 20 patients enrolled in the 30
mg/Kg arm.
GVHD prophylaxis All patients will receive the combination: cyclosporine-A (Cs-A 3 mg/kg/day
intravenously starting from day -2) and short-term methotrexate (MTX, 10 mg/m2 on day +1,
+3, +6, and +11) for GVHD prophylaxis.
Study samples Patient randomization will be performed by the coordinating study centre in
Pavia; Dr. M. Zecca will be the statistician responsible for the study. Patient enrolment
was calculated by a sample size evaluation method based on the log rank test to estimate the
difference in the cumulative incidence of grade II-IV acute GVHD. The minimum number of
patients to be randomized was 80 per arm based on a significance level of 0.05, a study
power of 0.80, and hypothesizing, for children in the lower dosage arm a grade II-IV GVHD
incidence of 50% and for children in the higher dosage arm a grade II-IV GVHD incidence of
25%. Interim analysis will be performed after recruitment of the first 10, 20 and 50
patients.
Duration of the study Patients will be enrolled in approximately 24 months. Each patient
must have a minimum observation time of at least 12 months. Thus, the expected study
duration is 36 months.
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Allocation: Randomized, Endpoint Classification: Efficacy Study, Masking: Open Label, Primary Purpose: Prevention