Cardiac cells that beat in space offer hope for better heart treatment on Earth

Emory researchers join forces with NASA to turn stem cells into beating heart muscle cells

A rocket lifts off at night with big clouds of smoke

A SpaceX Falcon 9 rocket lifts off from Cape Canaveral Air Force Station in Florida on March 6, 2020, taking scientific experiments and other cargo to the International Space Station.

A SpaceX Falcon 9 rocket lifts off from Cape Canaveral Air Force Station in Florida on March 6, 2020, taking scientific experiments and other cargo to the International Space Station.

Chunhui Xu wears an Emory shirt as she speaks with a microphone at the Kennedy space center

Emory professor Chunhui Xu, principal investigator for the Generation of Cardiomyocytes from Induced Pluripotent Stem Cells experiment, addresses NASA Social participants during a What’s on Board science briefing at the Kennedy Space Center on March 5, 2020.

Emory professor Chunhui Xu, principal investigator for the Generation of Cardiomyocytes from Induced Pluripotent Stem Cells experiment, addresses NASA Social participants during a What’s on Board science briefing at the Kennedy Space Center on March 5, 2020.

In just three weeks, stem cells became beating cardiac cells while aboard NASA’s SpaceX-20 mission. 

The experiment was conducted in March 2020 by NASA astronauts aboard the mission and researchers at Emory University School of Medicine and Children’s Healthcare of Atlanta. 

Before trying the real thing on the International Space Station (ISS), Chunhui Xu, PhD, Kevin Maher, MD and colleagues had been using space-simulation machines to enhance the ability of pluripotent, or immature, stem cells to turn into cardiac muscle cells. The goal was to determine the effects of zero gravity conditions on stem cells and to optimize the generation of clinically relevant cardiac muscle cells on Earth.

Stem cell-derived cardiac muscle cells have been used to treat heart failure in animal models. They've also been used to study inherited cardiac diseases separately from the heart of the source patient.

“These cells have the potential to treat heart disease in kids and adults, but repairing a damaged heart requires a large number of heart cells,” says Xu, associate professor in the Department of Pediatrics at Emory School of Medicine. “We were hoping to identify a more effective way to generate these cells by exploring the use of microgravity.”

Emory professor Chunhui Xu, principal investigator for the Generation of Cardiomyocytes from Induced Pluripotent Stem Cells experiment, addresses NASA Social participants during a What’s on Board science briefing at the Kennedy Space Center on March 5, 2020.

After the cells that were onboard the space station returned to Earth and arrived at Emory, Xu and Maher spent the last year diving into the study outcomes.

Results showed that these stem cells grow faster in the zero gravity conditions of space.

They shared their findings — alongside NASA astronaut Jessica U. Meir, PhD — with patients of the Children’s Healthcare of Atlanta Heart Center during a recent event, moderated by Lucky Jain, MD, chair of the Department of Pediatrics at Emory School of Medicine and chief academic officer for Children’s.

Hear NASA astronaut Jessica Meir speak about helping the research of Emory professors Chunhui Xu and Kevin Maher “come to life” in the unique environment of the International Space Station. 

“We think about the future of taking care of patients with heart problems,” says Maher, professor in the Department of Pediatrics at Emory School of Medicine and director of the Cardiac Intensive Care Unit at Children’s. “Being able to learn how to make stem cells grow faster has the potential to increase the chance for a better treatment for patients. There’s a lot of work being done to see how we can use these types of stem cells to make the heart stronger in the future.” 

The ISS National Laboratory called the spaceflight experiment a significant step for next-generation space research, as freezing cell technology offers many advantages for space research as well as research on Earth.

The potential clinical implications of this research mean that kids and teens with damaged heart valves may instead receive a replacement valve grown from their own cells. Additionally, cells from a child with heart arrythmia could be taken by biopsy and grown to test medications and treatments, potentially opening a new door to personalized medicine.


Media contact: Jill Wu

404-727-3870 (office) or 386-383-6061 (cell)
jill.s.wu@emory.edu 

Story published July 6, 2021. Photos courtesy of NASA.

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