³Ô¹ÏÍøÕ¾

Tiny hearts breakthrough a giant leap in fight against heart disease

QIMR Berghofer

An Australian research team led by QIMR Berghofer has succeeded in introducing a vascular system into tiny living and beating model human heart muscles, an achievement which it’s hoped will accelerate progress towards the ultimate goal of repairing damage from heart disease.

The findings, published in the prestigious journal , have also for the first time revealed the central role the vascular system plays in causing inflammation-driven injury of the heart muscle, which is important for several diseases that can cause heart injury including COVID-19.

The new vascularised tiny heart muscles, or organoids, more closely mimic the human heart and will allow much more accurate testing of new drugs to treat disease and inflammation, and take scientists a step closer to the holy grail of repairing heart tissue.

Lead researcher , who heads , said vascularising the tiny hearts is a game changer for their work.

Professor James Hudson, Group Leader of the Cardiac Bioengineering Research Group at QIMR Berghofer

“We only know a fraction about the biology underpinning the heart so we’re constantly trying to improve our cardiac organoids to simulate the heart’s complex cellular interactions and tissue composition.

“Each organoid is only about the size of a chia seed, measuring just 1.5 millimetres across, but inside are 50,000 cells representing the different cell types that make up the heart,” Professor Hudson said.

Organoids are grown from human pluripotent stem cells which can be generated using “reprogramming” of skin or blood cells. Until now, the model hearts included a range of cell types including the cells that hold the tissue together and the cells that make them beat, but researchers had not been able to add the critical vascular cells.

“Incorporating the vascular cells for the first time in our mini heart muscles is very significant because we found they had a key role in the biology of the tissues. Vascular cells made the organoids function better and beat strongly. This has really opened up our ability to better understand the heart and accurately model disease,” Professor Hudson said.

The team is focused on finding therapeutics to repair different types of heart damage. One of those is inflammation, which is the body’s reaction to insults such as metabolic disease or COVID-19, causing the heart to stiffen so it fails to fully relax and fill with enough blood.

Vascularised human cardiac organoid showing vascular cells in green.

“When we simulated inflammation in our mini heart muscles, we found the vascular cells played a central role. We only saw the stiffening in the tissues that had the vascular cells. The cells sensed what was happening and changed their behaviour, and we identified that the cells release a factor called endothelin that mediates the stiffening. We can now target this mechanism to see if we can control it with new therapeutics,” Professor Hudson said.

Cardiovascular disease is the claiming the lives of around . It is a major burden on the health system costing around . The trend is predicted to worsen due to an ageing population and lifestyle factors.

“Heart disease is devastating for the patient and their loved ones. And it is a huge burden on the economy. Finding new treatments is crucial to addressing this.

“For one type of heart failure that we work on, preserved ejection fraction (HFpEF), there is only one therapeutic available, so we urgently need to identify new drugs to improve patient outcomes and reduce the burden of heart disease.

“That’s where our new system of producing vascularised cardiac organoids will really give us an advantage because we’ll be able to progress the search for new treatments much more quickly,” Professor Hudson said.

Publication of the research will assist researchers around the world to replicate the vascularised organoids and boost the global effort to tackle heart disease. The method also has broader implications that could help researchers in other fields creating organoids such as kidneys and brains.

The QIMR Berghofer-led research involved collaboration with , based at , including and . Leading Australian institutions that contributed include The University of Queensland, The Royal Children’s Hospital Melbourne, The University of Melbourne, , Monash University, Victor Chang Cardiac Research Institute, UNSW, Westmead Hospital, SA Pathology and University of South Australia.

The researchers work closely with the to produce specially designed moulds used to help grow and support the organoids.

Professor Hudson is supported by a and this work was supported by multiple grants including .

/Public Release. View in full .