Clinical Trial Details
— Status: Completed
Administrative data
NCT number |
NCT06267898 |
Other study ID # |
EBMT- 842205547 |
Secondary ID |
|
Status |
Completed |
Phase |
|
First received |
|
Last updated |
|
Start date |
November 1, 2009 |
Est. completion date |
May 21, 2015 |
Study information
Verified date |
February 2024 |
Source |
European Society for Blood and Marrow Transplantation |
Contact |
n/a |
Is FDA regulated |
No |
Health authority |
|
Study type |
Observational [Patient Registry]
|
Clinical Trial Summary
Stem cell transplantation and blood product transfusions are standard of care for
Myelodysplastic Syndromes (MDS). Several studies have shown changes in serum ferritin and
non-transferrin-bound iron (NTBI) in patients undergoing stem cell transplantation. A large
proportion of MDS patients are at risk for organ damage from tissue siderosis, due to the
development of iron overload.
Toxic effects of iron may play an important role in the complications associated with HSCT.
Iron chelation therapy may reduce the acute and chronic treatment-related toxicity by
removing excess of iron, iron radicals and reactive oxygen species (ROS).
There is little information about the efficacy and safety of iron chelation in MDS patients.
This audit wants to evaluate the effect of iron toxicity on treatment-related mortality in
untreated, adult MDS or CMML patients during and after treatment with myeloablative
conditioning (MAC) and reduced intensity conditioning (RIC) allo-HSCT, by prospectively
collecting data from 200 MDS or CMML patients from 2009 onwards.
Description:
PRIMARY OBJECTIVE:
To evaluate in adult MDS or CMML patients the correlation between iron toxicity and
treatment-related mortality in the context of the treatment of such toxicity with iron
chelation during and after treatment with allo-HSCT
DETAILED DESCRIPTION:
Myelodysplastic syndromes (MDS) form a complex and heterogeneous group of bone marrow failure
disorders. These are characterized by ineffective hematopoiesis leading to peripheral
cytopenias and morphologic dysplasia. The incidence of MDS is about 5 per 100,000 persons a
year in the general population. After 60 years of age the incidence increases tot 20-50 per
100,000 persons a year.
Care for MDS includes amelioration of hematological deficits with blood product transfusions,
and stem cell transplantation after a standard myeloablative regimen. At the moment stem cell
transplantation is the only known curative treatment for MDS patients . Allogeneic Stem cell
transplantation can lead to considerable treatment-related morbidity and mortality among
patients. Insight in factors contributing to treatment related mortality, could lead to a
better treatment regimen in patients who are treated with allo-HSCT and subsequently lead to
overall lower treatment related mortality.
Red blood cell transfusion therapy is used to prevent anemia-related morbidity, and to
improve quality of life. However, non-transfusion dependent patients have a significantly
better prognosis than transfusion dependent patients.
The increased mortality of transfused patients can partly be attributed to iron overload.
Iron overload is a common acute and long-term event associated with autologous and allogeneic
hematopoietic stem cell transplantation (HSCT). The main cause of iron overload is chronic
transfusion therapy. Frequent blood transfusions lead to an increase in ferritin levels,
transferrin saturation and in the appearance of non-transferrin-bound iron (NTBI). Iron
overload is also observed in non-transfused patients with MDS. This may be due to the release
of toxic iron radicals by the intensive treatment itself and its associated ineffective
hematopoiesis, and some other less well defined processes. Ineffective hematopoiesis for
example, either a feature of the underlying disease or a consequence of the intensive
treatment, leads to growth and differentiation factor (GDF-15) over-expression which inhibits
the production of hepcidin in the liver. This leads to increased iron absorption and
increased iron toxicity.
When the acute storage capacity for body iron is exceeded, organs, such as liver, heart and
endocrine glands, are loaded with free iron. This leads to free radical generation, tissue
damage, and subsequently organ dysfunction.
Individuals with IPSS lower-risk disease or high-risk patients who respond favorably to
intensive antileukemic therapy, may survive long enough to develop clinical consequences of
iron overload. An increased iron load leads to toxic and infectious events even during the
first 3 months after transplantation.
Several different investigations are useful to determine iron overload. These include imaging
of liver and heart, tissue histology, and serum ferritin, transferrin saturation and
non-transferrin-bound iron (NTBI). Accuracy of imaging studies and feasibility of standard
tissue histology has been questioned. Serum ferritin and NTBI levels are widely used to
quantify iron overload, but are also limited in their use. Ferritin is elevated in various
inflammatory situations, as well as in hepatic damage. Therefore one should always be careful
in interpreting serum ferritin variations. When combined with liver enzymes and inflammation
markers, such as fibrinogen and C-reactive protein (CRP), ferritin, transferrin saturation
and NTBI levels can be used as a simple (and non-invasive) diagnostic step to determine iron
overload.
Although chronic red blood cell transfusions leading to iron overload are common among
patients with MDS, the clinical implications and the value of iron chelation therapy in MDS
remain unclear. Iron chelation therapy could improve the survival in transfusion-dependent
MDS patients, by removing excess iron, iron radicals and reactive oxygen species (ROS). This
may lead to a reduction in acute and chronic treatment-related toxicity and a reduction in
treatment-related mortality.
Results with iron chelation are mostly gained in studies which have been performed in other
transfusion dependent diseases, like thalassemia. It is often stated that the survival rate
in MDS is too low, due to coexisting morbidity and that the MDS patients are too old to
benefit from chelation therapy. However, patients with MDS could be more vulnerable to the
toxic effects of iron overload and therefore benefit more from iron chelation therapy in a
shorter period.
The recent development of oral iron chelators, like deferasirox and deferiprone, might lead
to a breakthrough in chelation therapy for MDS patients. Although most information stems from
trials performed on non-MDS patients, oral chelators promise to be effective and convenient
alternatives for subcutaneously administered iron chelators, like desferoxamine. The biggest
benefit of these drugs is their oral use. Continuous subcutaneous infusions are inconvenient
and may be associated with local side effects. On the other hand, both deferiprone and
deferasirox can also produce relevant side effects.
There is very little literature available to guide recommendations for management and
treatment of iron overload in patients with low-risk MDS. Most information about iron
overload and chelation stems from non-MDS patients. More studies are needed to quantify
effects of iron overload in MDS patients and to determine efficacy and safety of oral
chelators over other therapies. This international observational audit will provide insight
in correlation between iron overload and outcome of disease in MDS or CMML patients.
An ongoing retrospective analysis by the MDS subcommittee of the EBMT-CLWP showed that the
number of transfusions administered prior to the allogeneic SCT had a significant impact on
survival by a reduced non relapse mortality in patients who received less than 20 units prior
to the transplantation. Pre-transplantation ferritin levels were only reported in a minority
of the patients, but also ferritin levels appear to influence the non relapse mortality in
this group of patients (personal communication). Therefore, the proposed international
observational audit will provide insight in correlation between iron overload and outcome of
disease in MDS or CMML patients.
RESEARCH DESIGN:
Centers will be asked to register prospectively patients in this observational,
non-interventional audit. Patients will be treated according to local protocols. Both
Myelo-ablative conditioning (MAC) and Reduced Intensity Conditioning (RIC) are allowed.
It is advised to treat iron overload from 2 months after allogeneic HSCT onwards if serum
ferritin levels are over 1,000 g/l. Both phlebotomies and iron chelation therapy are assumed
to be a policy of the center applicable to all patients treated by that center; each center
is required to accurately state its "intention-to-treat" policy, i.e. under what conditions a
decision for phlebotomy and/or iron chelation therapy is normally reached (although centers
are allowed to deviate from this general policy if deemed necessary),based on individual
patient or physician preference. This "Intention-to-treat-policy" should be given before
inclusion of the first patient in this observational audit. Details of the chelation and the
phlebotomy therapy can be found on the Website of the EBMT (details:
http://www.ebmt.org/ClinicalTrials/observational audits/ not available yet).
Data will be collected by forms or files based on existing MED-B forms and an additional
questionnaire.
Follow-up data will be collected at 3 months, 6 months and every 6 months thereafter
STUDY POPULATION:
200 adult patients with cytologically proven untreated MDS or CMML, according to the FAB or
the WHO classification, transplanted with myeloablative or reduced intensity conditioning
allo-HSCT from May 2009 onwards.
RESEARCH VARIABLES
- Patients' features
- Centres' features
- Initial diagnosis
- Interval between diagnosis and HSCT
- Subclassification and status of disease at HSCT
- Complications: liver (transaminases, bilirubin, incidence VOD), kidney impairment,
infections
- Additional therapies
- Relapse or progression
- Last disease and patient status
- Donor
- Transplantation
- Graft manipulation
- Engraftment
- Comorbid conditions
- Preparative treatment
- Graft versus Host disease
- RBC transfusions before and after transplantation
- Ferritin levels, CRP, transferrin saturation, NTBI
- Chelation therapy: start therapy and average daily dosage per month
- Phlebotomy therapy: start therapy and average number of phlebotomies per month
- Follow up
ANALYSIS The primary outcome of this audit is non-relapse mortality (treatment related
mortality).
Secondary outcomes are treatment-related toxic effects, relapse rate, event-free survival and
overall survival.
Variables to be analyzed for their predictive ability on the above mentioned outcome
variables, are:
- Transfusion dependency, number of transfusions, hemoglobin levels
- ferritin levels, transferrin saturation, C-reactive protein (CRP)
- iron chelation therapy (prior and postSCT)
- phlebotomy therapy
- disease classification at SCT
- age patient,
- donor type
- female-donor/male recipient vs other combinations
- SCT conditioning type
- interval diagnosis and SCT, cytogenetics
- T-cell depletion
- acute and chronic GVHD
- length of survival
- primary causes of death
- relapse and complications
METHOD OF ANALYSIS:
For the primary objective(s), non-relapse mortality and relapse incidence will be analyzed
together in a competing risk framework, based on cause-specific hazard estimates stemming
from the appropriate Cox models.
The center will be introduced as a random effect. Since this is an observational and not a
randomized study, comparison of treatment policies with respect to outcome is difficult due
to the interplay of treatment policy and the actual occurrence of toxicity and a possible
center effect. Hence the prudent way to proceed is a thorough analysis within the subgroups
based on the center policy (the actual application of a specific treatment is depending on
center policy rather than the individual characteristics of the patient, so the covariate
"iron toxicity therapy" will be used as a intention-to-treat stratification factor rather
than a covariate).
The influence of iron toxicity in its broadest sense on the primary outcome variables is
studied by taking iron toxicity parameters as an additional covariate in a full Cox model for
non-relapse mortality as well as relapse incidence using known predictors for these outcomes
among MDS or CMML patients.
The entire analysis will be a careful evaluation of the above mentioned parameters in an
observational context and therefore a detailed statistical plan listing all possible
hypotheses to be tested, is not provided a priori since the observational nature of this
audit will most likely induce hypothesis generating statements rather than hypothesis testing
ones.
The methodology applied can however be stated in advance. Apart from Cox regression models
and a competing risk framework, the data will be analyzed according to the repeated
measurements structure induced by the repeated observations. In particular the predictive
ability of toxicity measures on any variables occurring later in time (whether events or
other continuous measures) will be studied in the context of mixed models, accounting for
center effects. These analyses focus on prediction of parameters at 3 months after SCT, 1
year after SCT, and 2 years after SCT. An interim analysis will be performed at the time
point when the first 100 patients have a follow-up of one year after SCT.