Electrifying results shed light on graphene foam as a potential material for lab grown cartilage

(Press-News.org) Boise State University researchers have developed a new technique and platform to communicate with cells and help drive them towards cartilage formation. Their work leverages a 3-dimensional biocompatible form of carbon known as graphene foam and is featured on a cover for the American Chemical Society’s Applied Materials and Interfaces - - an interdisciplinary journal for chemists, engineers, physicists and biologists to report on how newly discovered materials and interfacial processes can be leveraged for a wide range of applications. 

In this work, the researchers aim to develop new techniques and materials that can hopefully lead to new treatments for osteoarthritis through tissue engineering. Osteoarthritis is driven by the irreversible degradation of hyaline cartilage in the joints which eventually leads to pain and disability with complete joint replacement being the standard clinical treatment. Using custom designed and 3D printed bioreactors with electrical feedthroughs, they were able to deliver brief daily electrical impulses to cells being cultured on 3D graphene foam. 

The researchers discovered that applying direct electrical stimulation to ATDC5 cells adhered to the 3D graphene foam bioscaffolds significantly strengthens their mechanical properties and improves cell growth - key metrics for achieving lab grown cartilage. ATDC5 cells are a murine chondrogenic progenitor cell line well studied as a model for cartilage tissue engineering. Additionally, their specialized setup allowed full submersion of the 3D graphene foam scaffold, enhancing cell attachment and integration within its porous structure - highlighting a promising approach for improving engineered tissues using electrical stimulus through conductive biomaterials.

 “One of the biggest challenges in applying direct electrical stimulation to stem cells is achieving repeatable delivery while monitoring the electrical environment and mapping that back to specific cellular responses,” said Mone’t Sawyer, lead author of the study. “Our system introduces a modular and scalable platform that enables high-throughput, scaffold-coupled electrical stimulation with precise control—opening new possibilities for understanding how electrical cues influence tissue formation.” 

Osteoarthritis ranks as a world-leading cause of pain and disability, currently affecting over 595 million individuals—more than double the 256 million afflicted individuals recorded in 1990. The economic burden is large, with global costs exceeding $460 billion annually, including healthcare expenses, lost productivity, and disability-related costs. In the U.S. alone, OA accounts for $65 billion in direct and indirect costs, with over 1 million joint replacements performed each year to manage severe cases. 

"Mone’t’s work is providing new fundamental insights into the role of materials and electrical stimuli in communicating with stem cells," said Prof. David Estrada of the Micron School of Materials Science and Engineering. "I believe this work is setting the stage for greater understanding of the human electrobiome, that is, the role of electric charge and transport across different length scales and ultimately in cell fate to tissue function."

This works was supported by the National Science Foundation through CAREER award #1848516 and the LSAMP Bridge to Doctorate Program under award #1906160. The researchers now plan to test their experimental setup with human stem cells in order to move one step closer to clinical applications.

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