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Mayo Clinic researcher
harnesses uniqueness of
space to advance medicine on
Earth
(DUBAI)
-
Mayo Clinic physician
and researcher Dr.
Abba Zubair’s work
combines two passions —
medicine and space — for the
benefit of astronauts and
people on Earth. His space
research is yielding
discoveries in cancer,
stroke, bone loss, and more.
In this expert alert, Dr.
Zubair answers five
questions about his studies
in microgravity.
What are you hoping
to accomplish through your
research?
"The goal is to harness the
uniqueness of the space
environment for the
betterment of humanity, be
it on Earth or in space,"
Dr. Zubair says. "We wanted
to take advantage of the
environment at the
International Space Station
to study how it affects
human physiology."
The absence of gravity and
the impacts of radiation and
vacuum are three fundamental
aspects of the uniqueness of
space, adds Dr. Zubair, who
has sent three research
projects to the
International Space Station
(ISS) since 2017, with more
to come.
As a
regenerative biotherapeutics
specialist, Dr. Zubair's
work focuses in part on
adult stem cells — known as
mesenchymal stem cells —and
their use in future
treatments for stroke. He
noted that he uses stem
cells in regenerative
medicine and in supporting
Mayo's bone marrow
transplant program.
"I also know how challenging
it is to grow them in the
lab. One of the first
fundamentals is to see how
the absence of gravity
influences how stem cells
divide and the growth rate,"
Dr. Zubair explains. "We
wanted to see whether cells
grown in space are any
better or grow faster than
cells grown in the lab. When
we did our first space
flight, we had a really
interesting finding, because
we realized that the absence
of gravity affects stem
cells, but it depends on the
type of stem cells."
That led Dr. Zubair to
another project on the ISS:
studying how mesenchymal
stem cells, the precursor
for bone-forming cells, play
a role in bone formation or
osteoporosis, bone loss. He
notes that astronauts tend
to lose bone density despite
rigorous exercise.
How might your
research benefit people with
cancer?
Dr.
Zubair is also studying how
leukemia stem cells, the
cells that form the seed of
this blood cancer, respond
to the space environment.
"We are also working to
understand the impact of
space radiation, from the
angle of how we can mitigate
the effect of radiation and
prevent cancer," Dr. Zubair
says. "In the long run, we
really want to protect
astronauts, especially
during long-term space
travel, such as to Mars,
where they would be deep in
space and away from any
magnetic field protection
that we get from Earth."
The research also may
benefit people on Earth by
revealing how to protect
stem cells or cells in
general when there is
radiation exposure, such as
nuclear accidents, he adds.
In addition, Dr.
Zubair's space research
could have implications for
CAR-T treatment, bone marrow
transplants, or other
therapies for cancer
patients.
"If we can
understand how stem cells in
space, especially
hematopoietic stem cells
(cells that live in the bone
marrow and produce cells
that function in the blood),
expand and differentiate to
make immune cells like T
cells, macrophages, we will
learn how to make them more
efficiently," Dr. Zubair
says.
You've
remarked that you can
envision a time when people
might go into space to
receive certain medical
treatments. How would that
work, and might it be
possible to simulate
microgravity for those
treatments on Earth?
If cells proliferate
more in space, for example,
if cancer cells go into what
is called the cell cycle and
multiply abnormally when
they proliferate, then
chemotherapy will be more
effective, Dr. Zubair says.
"If that is the case,
the absence of gravity can
induce leukemia cells or
other cancer cells to go
into the cell cycle, which
makes them susceptible to
chemotherapy," he explains.
"So instead of giving the
chemo on Earth, you might go
into space where the absence
of gravity makes the cancer
cells more vulnerable to
chemotherapy. That would be
one more reason to go to
space. That is definitely
something that I would love
to explore."
It would
be difficult to create a
comparable microgravity
environment on Earth, but
technically, it could be
done, Dr. Zubair adds.
"Microgravity on Earth
is basically like going into
a swimming pool, a state of
buoyancy where you are kind
of in suspension; the
gravity is canceled out by
the effect of the water," he
says. "Now, obviously, it
wouldn't be pleasant to be
in water for quite some
time. In the lab, we use a
microgravity simulator where
cells are suspended. It
would be interesting if you
could do the same for a
human being."
What attracted you
to space research?
Dr. Zubair grew up in
Kano, Nigeria, and remembers
gazing at the night sky as a
child.
"As far back
as I can remember, I was
always fascinated by what is
out there in space. Looking
at the moon and all the
stars, and really that
ignites my passion for space
and space exploration," Dr.
Zubair says.
Dr.
Zubair's first dream was to
become an astronaut, but an
adviser in high school
counseled him to find a more
practical career, and he
pursued medicine.
What's next?
One of Dr. Zubair's next
two payloads to the
International Space Station,
not yet scheduled for
launch, will examine whether
umbilical cord blood cells,
rich in stem cells and
potential therapeutic value,
can be expanded. Another
study will explore different
cell types that participate
in bone formation and
whether the problem of bone
loss in space can be
alleviated through the use
of a special compound.
"If it works, then
definitely we will see how
we can treat patients with
osteoporosis, particularly
women, cancer patients, or
people who are bedridden for
a long time and are not
weight-bearing, which
affects their bones," Dr.
Zubair says.
Dr.
Zubair notes that all of his
space experiments are done
in parallel on Earth with
identical cells to compare
the two results and validate
the findings from space.
"I really think there is
a lot out there that is just
waiting for us to explore
and use," he says. "And
that's why I do what I do."
Dr. Zubair has been
honored by NASA with the
Exceptional Scientific
Achievement Medal for
demonstrating that
human-derived mesenchymal
stem cells grown aboard the
International Space Station
could be used for potential
clinical applications.
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