Labmanager Logo

Synthetic Stem Cells Could Offer Therapeutic Benefits, Reduced Risks

Researchers fabricated a cell-mimicking microparticle from poly (lactic-co-glycolic acid) or PLGA, a biodegradable and biocompatible polymer

| 2 min read
Share this Article
Register for free to listen to this article
Listen with Speechify
0:00
2:00

Synthetic Stem Cells Could Offer Therapeutic Benefits, Reduced RisksIllustration courtesy of North Carolina State University

Researchers from North Carolina State University, the University of North Carolina at Chapel Hill, and First Affiliated Hospital of Zhengzhou University have developed a synthetic version of a cardiac stem cell. These synthetic stem cells offer therapeutic benefits comparable to those from natural stem cells and could reduce some of the risks associated with stem cell therapies. Additionally, these cells have better preservation stability and the technology is generalizable to other types of stem cells.

Stem cell therapies work by promoting endogenous repair; that is, they aid damaged tissue in repairing itself by secreting “paracrine factors,” including proteins and genetic materials. While stem cell therapies can be effective, they are also associated with some risks of both tumor growth and immune rejection. Also, the cells themselves are very fragile, requiring careful storage and a multi-step process of typing and characterization before they can be used.

Lab manager academy logo

Get training in Lab Crisis Preparation and earn CEUs.

One of over 25 IACET-accredited courses in the Academy.

Certification logo

Lab Crisis Preparation course

Ke Cheng, associate professor of molecular biomedical sciences at NC State, associate professor in the joint biomedical engineering program at NC State and UNC, and adjunct associate professor at the UNC Eshelman School of Pharmacy, led a team in developing the synthetic version of a cardiac stem cell that could be used in off-the-shelf applications.

Related Article: Roadmap for Advanced Cell Manufacturing Shows Path to Cell-Based Therapeutics

Cheng and his colleagues fabricated a cell-mimicking microparticle (CMMP) from poly (lactic-co-glycolic acid) or PLGA, a biodegradable and biocompatible polymer. The researchers then harvested growth factor proteins from cultured human cardiac stem cells and added them to the PLGA. Finally, they coated the particle with cardiac stem cell membrane.

“We took the cargo and the shell of the stem cell and packaged it into a biodegradable particle,” Cheng says.

When tested in vitro, both the CMMP and cardiac stem cell promoted the growth of cardiac muscle cells. They also tested the CMMP in a mouse model with myocardial infarction, and found that its ability to bind to cardiac tissue and promote growth after a heart attack was comparable to that of cardiac stem cells. Due to its structure, CMMP cannot replicate—reducing the risk of tumor formation.

“The synthetic cells operate much the same way a deactivated vaccine works,” Cheng says. “Their membranes allow them to bypass the immune response, bind to cardiac tissue, release the growth factors and generate repair, but they cannot amplify by themselves. So you get the benefits of stem cell therapy without risks.”

Interested in life sciences?

Subscribe to our free Life Sciences Newsletter.

Is the form not loading? If you use an ad blocker or browser privacy features, try turning them off and refresh the page.

The synthetic stem cells are much more durable than human stem cells, and can tolerate harsh freezing and thawing. They also don’t have to be derived from the patient’s own cells. And the manufacturing process can be used with any type of stem cell.

Related Article: Stem Cells from Diabetic Patients Coaxed to Become Insulin-Secreting Cells

“We are hoping that this may be a first step toward a truly off-the-shelf stem cell product that would enable people to receive beneficial stem cell therapies when they’re needed, without costly delays,” Cheng says.

The research appears in Nature Communications. Cheng is corresponding author. The work was funded in part by the National Institutes of Health, NC State Chancellor’s Innovation Fund, and University of North Carolina General Assembly Research Opportunities Initiative grant. The co-first authors of this paper are. Junnan Tang, Deliang Shen, and Thomas Caranasos. Cheng’s collaborators are Quancheng Kan and Jinying Zhang at The First Affiliated Hospital of Zhengzhou University, Henan, China.

About the Author

  • Tracey Peake, North Carolina State University News Office

Related Topics

Loading Next Article...
Loading Next Article...

CURRENT ISSUE - December 2024

2025 Industry and Equipment Trends

Purchasing trends survey results

Lab Manager December 2024 Cover Image