Aussies pioneer new approach to mend broken hearts

In the Media
A printer that builds beating 3D hearts in a laboratory could soon be saving the lives of heart attack patients if a pioneering Australian trial proves successful.

The Heart Research Institute has bought a 3D bio-printer to engineer human heart tissue that can be stuck directly to a damaged organ following an attack.

The Australia-first experiment could dramatically alter the cardiac treatment landscape, giving patients whose hearts are wounded by an attack a chance to fully recover and return to normal life.

“If we can make it work we’ll be changing the lives of thousands of Australians and flipping the world of heart attack treatment on its head.” 
Dr Carmine Gentile, HRI research fellow and world leader in 3D tissue culture.

More than 350,000 Australians will have a heart attack in their lifetime, and while there have been improvements in recovery rates, the event still claims the lives of 24 Australians every day.

The two common treatments, coronary angioplasty and reperfusion therapy, offer excellent results for patients who receive them very soon after an attack, but those who miss out often suffer irreversible heart damage.

With an urgent need for new treatments, the HRI investigated the benefits of a bio-printer to print out unique 3D human mini hearts developed by Dr Gentile. These mini hearts, called cardiac spheroids, were built from stem cells to be used as "bio-ink" to print cardiac patches.

The HRI was awarded a $44,000 grant by the Ian Potter Foundation to purchase the bio-printer, which will first be used to print patches for testing on animal models in the laboratory prior to their use in humans.

“The idea is these patches will be grafted on to the heart after a heart attack, promoting muscle regeneration and returning cardiac function to normal,” Dr Gentile says.

The printer works by spreading “bio-ink” made from human cells layer-by-layer onto biocompatible sheet, called hydrogel, to generate living 3D bio-printed heart tissues. These bio-printed heart tissues can be used in the lab to safely test new heart drugs and to discover new molecular targets for future therapies.

Ultimately though, the technology will be used to replace the damaged parts of human hearts following heart failure and heart attack. As Dr Gentile explains, the printed patches would be customized to each patient to ensure the best outcome.

“Each patient’s heart is scanned first to map the damage to make sure the patch is the right size and shape,” he says. “We’ll also isolate stem cells from the patient’s own skin to make personalized bio-ink to build compatible heart tissue.”

The patch moulds to the heart, mimicking the role of the original damaged tissue for the rest of the individual’s life.

While plenty of past studies have highlighted the feasibility of 3D printing to improve heart disease outcomes in humans, nobody has yet proved it. If successful, the HRI trial would be the first.

Professor Gemma Figtree at the Kolling Institute who is a collaborating partner on the research, is optimistic about the outcome.

“Dr Gentile’s cardiac spheroids have already shown very promising results in the laboratory,” she says. “They have been successful in overcoming hurdles faced by approaches that use only single cells. The future looks very exciting indeed.”

The researchers expect the therapy could be available for patients in the next five years, and every effort will be made to get the treatment into hospitals as soon as possible. The process will be costly however, as it is expensive to collect biological material like cells to 3D bio-print a human cardiac patch.

Listen: Dr Gentile speaks with ABC's The Conversation Hour
"Aussies Pioneer New Approach to Mend Broken Hearts"

Previous
Next

Related news

Dr Anna Waterhouse joins HRI as Group Leader

The HRI is pleased to welcome Dr Anna Waterhouse as Group Leader of the Cardiovascular Medical Devices Group and Senior Lecturer at the University of Sydney. Dr Waterhouse’s research focuses on how medical devices – such as artificial hearts, stents and bypass machines – interact with the body. Her aim is to understand the interactions of medical devices with patients’ blood, proteins and cells to develop more sophisticated and compatible materials. 

Read more

A new generation of blood vessels?

The HRI’s Applied Materials Group is working to develop the next generation of bioactive materials – materials that can bond to living tissues.
Read more

Glowing Stem Cells Mend Broken Hearts

HRI researcher is heralding hope for broken hearts with a cutting-edge tool that helps scientists fast-track exciting new therapies to mend damaged organs.

Richard Tan from the Heart Research Institute in Sydney has developed a glowing stem cell tracker model that could change the way the science community develops life-saving tissue therapies.

Read more