Clinical Trial Details
— Status: Active, not recruiting
Administrative data
NCT number |
NCT03282656 |
Other study ID # |
P00026188 |
Secondary ID |
|
Status |
Active, not recruiting |
Phase |
Phase 1
|
First received |
|
Last updated |
|
Start date |
February 13, 2018 |
Est. completion date |
November 13, 2024 |
Study information
Verified date |
June 2024 |
Source |
Boston Children's Hospital |
Contact |
n/a |
Is FDA regulated |
No |
Health authority |
|
Study type |
Interventional
|
Clinical Trial Summary
A promising approach for the treatment of genetic diseases is called gene therapy. Gene
therapy is a relatively new field of medicine that uses genetic material (mostly DNA) from
the patient to treat his or her own disease. In gene therapy, the investigators introduce new
genetic material in order to fix or replace the patient's disease gene, with the goal of
curing the disease. The procedure is similar to a bone marrow transplant, in that the
patient's malfunctioning blood stem cells are reduced or eliminated using chemotherapy, but
it is different because instead of using a different person's (donor) blood stem cells for
the transplant, the patient's own blood stem cells are given back after the new genetic
material has been introduced into those cells. This approach has the advantage of eliminating
any risk of GVHD, reducing the risk of graft rejection, and may also allow less chemotherapy
to be utilized for the conditioning portion of the transplant procedure. The method used to
introduce the gene into the patient's own blood stem cells is to engineer and use a modified
version of a virus (called a 'vector') that efficiently inserts the "correcting" genetic
material into the cells. The vector is a specialized biological medicine that has been
formulated for use in human beings.
The investigators have recently discovered a gene that is very important in the control of
fetal hemoglobin expression. Increasing the expression of this gene in sickle cell patients
could increase the amount of fetal hemoglobin while simultaneously reducing the amount of
sickle hemoglobin in their blood, and therefore potentially cure the condition. In summary,
the advantages of a gene therapy approach include: 1) it can be used even if the patient does
not have a matched donor available; 2) it may allow a reduction in the amount of chemotherapy
required to prepare the patient for the transplant; and 3) it will avoid the strong medicines
often required to prevent and treat GVHD and rejection. The goal is to test whether this
approach is safe, and whether using gene therapy to change the expression of this particular
gene will lead to increased fetal hemoglobin production in people with sickle cell disease.
Description:
This is an open-label, non-randomized, single center, pilot and feasibility, single arm
cohort study involving a single infusion of autologous bone marrow derived CD34+ HSC cells
transduced with the lentiviral vector containing a short-hairpin RNA targeting BCL11a.
Accrual will be a maximum of 7 evaluable patients with SCD. The study will have three strata:
1. Stratum 1: ages ≥18-40
2. Stratum 2: ages ≥12-<18
3. Stratum 3: ages ≥3-<12
To determine the feasibility and safety of administering a lentiviral gene transfer vector
encoding a small hairpin (sh) RNA targeting the γ-globin gene repressor, BCL11A, in patients
with severe SCD.
Patients will undergo standard work-up for autologous bone marrow transplantation according
to institutional guidelines and then undergo two bone marrow harvests at a minimum of 4 weeks
apart that will be used for a back-up marrow (minimum of 2 x 106 CD34+ cells/kg) and for a
harvest of autologous bone marrow for gene transfer.
Patients will receive blood transfusions for a period of 3 months prior to the planned date
of product infusion, with a goal of achieving a HbS level ≤ 30% by the time of gene transfer.
If the subject is already on a chronic transfusion regimen as part of baseline disease
management, the regimen may be continued. The timing of transfusions will be coordinated to
occur within 7 days prior to any procedures requiring anesthesia such as bone marrow harvest.
Hematopoietic cells will be collected from the patient in advance of the treatment, to serve
as a salvage procedure ("back-up graft"), should there be no hematopoietic recovery observed
following the injection of genetically-manipulated cells, or should manipulated cells fail to
meet release criteria. Bone marrow (up to 20 mL/kg) will be harvested from the patient under
general anesthesia from the posterior iliac crests on both sides by multiple punctures at a
minimum of 4 weeks prior to gene therapy. A portion of the bone marrow containing at least 2
x 106 CD34+ cells/kg will be frozen and stored unmanipulated according to standard clinical
procedures for autologous bone marrow collection to constitute the back-up graft. If the
number of CD34+ cells that exceeds 2 x 106 cells/kg is greater than or equal to 1 x 106
cells/kg, these excess cells would be processed for transduction, transduced, and then
frozen. Transduction will be carried out on the selected CD34+ cells and transduced cells
will be cryopreserved. If cells from the first harvest were transduced and frozen, these
gene-modified cells will be thawed and prepared for infusion in parallel with the product
from the subsequent harvest(s). In this case two separate products would be infused. All cell
manipulation procedures and release testing will be performed in the transduction facility in
accordance with Good Manufacturing Practice (GMP) following process specific standard
operating procedures. Final Drug Product will be accompanied by a Certificate of Analysis,
documenting that all release testing is complete and within specification. Subjects will
receive myeloablative conditioning with Busulfan administered on days -5 to -2, prior to
infusion of transduced cells. Cells will be infused intravenously over 30-45 minutes after
standard prehydration and premedication according to Boston Children's Hospital Hematopoietic
Stem Cell Transplantation Unit standard guidelines. This standard requires that the patient
be on continuous cardiac, respiratory and oxygen saturation monitor throughout the infusion
and for 30 minutes afterwards. Vital signs will be measured and recorded pre-transfusion, 15
minutes into transfusion, every hour for duration of infusion, and end of transfusion. The RN
will stay with the patient for the first 5 minutes of the transfusion. If two transduction
products are administered, the second transduced product will be administered without delay
after the first.