Neuroblastoma Clinical Trial
Official title:
3RD GENERATION GD2 SPECIFIC CHIMERIC ANTIGEN RECEPTOR AND INDUCIBLE CASPASE 9 SAFETY SWITCH TRANSDUCED AUTOLOGOUS NATURAL KILLER T-CELLS TO TREAT CHILDREN WITH NEUROBLASTOMA (GINAKIT)
This research study is for patients that have a cancer called Neuroblastoma that has either
come back after treatment or did not respond to the standard medicines used to treat it.
This study combines two different ways of fighting cancer: antibodies and Natural Killer T
cells. Antibodies are types of proteins that protect the body from infectious diseases and
possibly cancer. T cells, also called T lymphocytes, are special infection-fighting blood
cells that can kill other cells, including cells infected with viruses and tumor cells. Both
antibodies and T cells have been used to treat patients with cancers. The investigators have
found from previous research that they can put a new gene into T cells that will make them
recognize cancer cells and kill them. In a previous clinical trial, the investigators made a
gene called a chimeric antigen receptor (CAR), from an antibody called 14g2a that recognizes
GD2, a molecule found on almost all neuroblastoma cells (GD2-CAR). They put this gene into
the patients' own T cells and gave them back to patients that had neuroblastoma. Nineteen
patients were treated on that study and there were no long term side-effects seen after the
GD2 T cell infusion. As the investigators have followed the patients over time, they noticed
that for those patients with disease at the time of their infusion, the time to progression
(the amount of time it takes before their neuroblastoma got worse) was longer in those whom
they could find GD2 T cells in the blood for more than 6 weeks after the last T cell
infusion. Because of this, the investigators think that if effector cells are able to last
longer, they may have a better chance of killing neuroblastoma tumor cells.
Natural Killer T cells are a special subset of innate lymphocytes that can effectively go
into tumor tissues of neuroblastoma. Inside the tumor, there are certain white blood cells
which help the cancer cells to grow and recover from injury. Natural Killer T-cells can
specifically kill these cells. In this study, Natural Killer T cells will be genetically
engineered to express GD2-CAR to attack neuroblastoma cells and the white blood cells inside
the tumor tissue.
To prepare the neuroblastoma specific Natural Killer T cells (also called GINAKIT cells),
about 80 mL (up to 6 tablespoons) of blood will be collected from the patient. For children,
the total amount of blood drawn will not be more than 3 ml (less than 1 teaspoon) per 2.2
lbs of body weight.
In case the neuroblastoma specific Natural Killer T cells cannot be expanded from the amount
of blood that can safely be drawn from the patient, the investigators may attempt to collect
white blood cells from the patient by using a special type of blood donation called
leukocyte apheresis. Unlike a regular blood draw or "whole blood" donation in which whole
blood is removed from patient's body, the apheresis process connects the patient to a
machine that removes a particular component of their blood and then returns the rest of the
blood back to them. The white blood cells collected during leukocyte apheresis will be used
to make the GINAKIT cells.
Once collected, the white blood cells will be mixed with a special protein to separate the
Natural Killer T cells from the white blood cells using a special machine called a CliniMACS
Reagent System in the laboratory. This is an investigational device that is not approved by
the FDA. Although this device is not approved for use in this country, it has been in use
for years and is approved in other countries. The investigators will put the new genes into
patient's Natural Killer T cells by mixing them with a retroviral vector (a special virus
that can carry a new gene into cells) containing the new gene called iC9-GD2-CD28-OX40.
After the new gene has been put into the Natural Killer T cells, the cells will be tested to
make sure that they kill GD2-positive neuroblastoma cells and that the cells are killed by
the activation of iC9. The GINAKIT cells may be given back to the patient fresh or frozen.
This is a dose escalation study. This means that at the beginning, patients will be started
on the lowest dose (1 of 4 different levels) of GINAKIT cells. Once that dose schedule
proves safe, the next group of patients will be started at a higher dose. This process will
continue until all 4 dose levels are studied. If the side effects are too severe, the dose
will be lowered or the infusions will be stopped.
Before getting the GINAKIT cells, patients will receive cyclophosphamide and fludarabine
intraveneously for 2 days and then fludarabine alone for one more day. Patients will then
have one day of rest with no chemotherapy before receiving the GINAKIT cells.
The treatment will be given by the Center for Cell and Gene Therapy at Texas Children's
Hospital. Patients will need to stay in Houston for 4 weeks after the infusion so the
investigators can monitor them for side effects. They will have follow-up visits (at weeks
1, 2, 4, 6, and 8; months 3, 6, 9, and 12; twice a year for 4 years and then once a year for
the next 10 years - for a total of 15 years) and scheduled disease evaluations after the
GINAKIT cell infusion (at week 4 and then as clinically needed). Also, to learn more about
the way the GINAKIT cells are working and how long they last in the body, blood will be
obtained before the chemotherapy, on the day of the GINAKIT cell infusion (before and at the
end of the infusion) and at the follow-up visits (time points listed above).
If the patient experiences no significant side effects during or after the first GINAKIT
cell infusion and their cancer remains stable or responds, they may be offered additional
doses of the same cell dose in the future.
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