Nanomaterials help regenerate cardiac cells
20 Sep 2012
Scientists have capitalised on the electrical properties of a nanomaterial to aid the regeneration of cardiac cells.
The advance has been led by a team of scientists at the Regenerative Medicine Institute (REMEDI) at the National University of Ireland Galway in conjunction with Trinity College Dublin.
Heart disease is the leading cause of death throughout the world. Once damaged by heart attack, cardiac muscle has very little capacity for self-repair and at present there are no clinical treatments available to repair damaged cardiac muscle tissue.
Over the last 10 years, there has been huge interest in developing a cell-based therapy to address the problem. Since the use of a patient’s own heart cells is not a viable clinical option, many researchers are working to try to find an alternative source of cells that could be used for cardiac tissue repair.
REMEDI researchers Dr Valerie Barron and Dr Mary Murphy have brought together a multi-disciplinary team of Irish materials scientists, physicists and biologists from REMEDI at National University of Ireland Galway and Trinity College Dublin to address this problem.
The researchers recognised that carbon nanotubes, a widely used nanoparticle, is reactive to electrical stimulation. They then used these nanomaterials to create cells with the characteristics of cardiac progenitors, a special type of cell found in the heart, from adult stem cells.
“The electrical properties of the nanomaterial triggered a response in the mesenchymal (adult) stem cells, which we sourced from human bone marrow. In effect, they became electrified, which made them morph into more cardiac-like cells”, explains Valerie Barron of REMEDI at National University of Ireland Galway.
“This is a totally new approach and provides a ready-source of tailored cells, which have the potential to be used as a new clinical therapy. Excitingly, this symbiotic strategy lays the foundation stone for other electroactive tissue repair applications, and can be readily exploited for other clinically challenging areas such as in the brain and the spinal cord.”
This work has recently been published in two leading scientific journals, Biomaterials and Macromolecular Bioscience, and was carried out in collaboration with Professor Werner Blau, Investigator in CRANN and the School of Physics, Trinity College Dublin (TCD).