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INFORMATION FOR

    Treating Cancer with CAR-T Cell Therapy

    July 07, 2026

    Transcript

    • 00:04CAR T cell therapy
    • 00:06is a treatment using your
    • 00:08own T cells
    • 00:10that have been modified
    • 00:11outside your body and put
    • 00:13back into you to attack
    • 00:14cancer. In order to make
    • 00:16any sense of that, I
    • 00:17have to talk a little
    • 00:17bit about what the immune
    • 00:18system is. So
    • 00:20the immune system is this
    • 00:22large organ
    • 00:23in your body made up
    • 00:24of a huge number of
    • 00:25cells
    • 00:26that is used to detect
    • 00:27foreign agents.
    • 00:29T cells are a subset
    • 00:31of our lymphocytes,
    • 00:33and lymphocytes are important immune
    • 00:35cells. They play an important
    • 00:37role in, defending us from
    • 00:39viral infections
    • 00:40and helping other parts of
    • 00:42the immune system to fight
    • 00:43infection.
    • 00:44One of the things that
    • 00:45t cells do is to
    • 00:47literally recognize
    • 00:49when one of our own
    • 00:51cells is infected by something,
    • 00:53by what are called receptors
    • 00:54on the surface of those
    • 00:55t cells, and then attack
    • 00:56those cells and actually destroy
    • 00:58them.
    • 00:59Our cancer cells aren't always
    • 01:01that much different from our
    • 01:02normal cells.
    • 01:04Our immune system is just
    • 01:06not recognizing
    • 01:07these cancer cells as far
    • 01:08enough
    • 01:09to attack them.
    • 01:11But we often know that
    • 01:13cancer cells
    • 01:14make certain
    • 01:16proteins,
    • 01:17which are little molecules,
    • 01:19that are on their surfaces.
    • 01:21So we can take t
    • 01:22cells out of the body
    • 01:23and we can engineer them
    • 01:25to recognize
    • 01:26the specific molecules on a
    • 01:27particular cancer.
    • 01:29And once a t cell
    • 01:30recognizes something,
    • 01:32it can destroy it.
    • 01:37So how do we do
    • 01:37it? As I said, we
    • 01:39take the t cells out
    • 01:40en masse. We do it
    • 01:41by something called phoresis.
    • 01:43A process that's
    • 01:44a little bit more complicated
    • 01:46than a a general blood
    • 01:47donation, but outpatient procedure where
    • 01:49the lymphocytes are filtered from
    • 01:51a bloodstream for a few
    • 01:52hours.
    • 01:53Those cells are sent to
    • 01:54a laboratory
    • 01:56where
    • 01:57We put a piece of
    • 01:58DNA into that cell, and
    • 01:59that DNA is a blueprint.
    • 02:01It encodes
    • 02:02what's called a receptor or
    • 02:04a protein, and it's made
    • 02:05up of two
    • 02:06distinct
    • 02:07parts.
    • 02:08It's got one part that
    • 02:10sticks out of the t
    • 02:10cell that recognizes
    • 02:12the molecule on the cancer
    • 02:14and it's connected
    • 02:15to a part that sticks
    • 02:17into the cell that signals
    • 02:19to the T cell to
    • 02:20tell it to kill.
    • 02:21And we call it a
    • 02:22CAR because that stands for
    • 02:24chimeric
    • 02:25antigen
    • 02:26receptor.
    • 02:27And then they're expanded in
    • 02:29a laboratory, so we have
    • 02:30a lot of these cells
    • 02:31that we can infuse to
    • 02:32a patient.
    • 02:34These CAR T cells, when
    • 02:35they work well, will not
    • 02:37only go into the body,
    • 02:39but they will divide there
    • 02:40and they will stick
    • 02:41around. And we've
    • 02:43seen that many of these
    • 02:44patients have actually been cured.
    • 02:46It takes many, many providers
    • 02:49and professionals,
    • 02:50both clinically and in the
    • 02:52laboratory,
    • 02:52in our cell processing lab,
    • 02:54in our epheresis unit to
    • 02:57collaboratively
    • 02:58orchestrate
    • 02:59the treatment,
    • 03:00that's this complicated.
    • 03:02It's a pretty big undertaking
    • 03:04and,
    • 03:05it requires a program, not
    • 03:06just
    • 03:07a physician,
    • 03:09to administer these treatments.
    • 03:18The FDA approvals for these
    • 03:19cells are for
    • 03:21diseases really of the blood
    • 03:23system, so hematologic
    • 03:25neoplasms.
    • 03:26There is a lot of
    • 03:27research trying to harness the
    • 03:29same technology
    • 03:30to fight solid tumors.
    • 03:33Solid tumors
    • 03:34in general are more advanced
    • 03:36than blood tumors,
    • 03:38So they're much more mutant.
    • 03:40They're much more heterogeneous.
    • 03:42And so Yale has a
    • 03:44number of scientists who are
    • 03:45working on finding the right
    • 03:47target in a cancer cell.
    • 03:49The targets are proteins usually
    • 03:51on the surface of those
    • 03:52cancer cells.
    • 03:53However,
    • 03:54the cancer cells can often
    • 03:55lose those targets, making them
    • 03:58not susceptible.
    • 03:59So
    • 04:00people are looking for targets
    • 04:02that it's very hard for
    • 04:03the cancer cell to lose.
    • 04:05We have a very active
    • 04:07clinical trial portfolio
    • 04:09for solid tumors,
    • 04:11for a lot of different
    • 04:12kinds of cancers and different
    • 04:14types of CAR T cells
    • 04:15or other T cell redirection
    • 04:18type
    • 04:18therapies.
    • 04:20It's a whole range of
    • 04:21research from
    • 04:22developing
    • 04:23in a laboratory
    • 04:25what is going to work
    • 04:26and then eventually putting it
    • 04:27into people. And that whole
    • 04:29range of research is super
    • 04:30important if we're gonna get
    • 04:32more therapies like this
    • 04:33that could really change the
    • 04:35face of how we treat
    • 04:36cancer.