Scientists come closer to 'mending broken hearts' by using gene therapy to repair muscles damaged in heart attacks

Scientists have come a step closer to being able to repair the damage done by heart attacks, using a cocktail of genes to transform scar tissue into working heart muscles.

Novel techniques to mend broken hearts using gene therapy and stem cells represent a major new frontier in the treatment of heart disease.

In the latest breakthrough, achieved by researchers at the Gladstone Institute of Cardiovascular Disease in California, researchers were able to re-programme scar-forming cells into heart muscle cells, some of which were capable of transmitting the kind of electrical signals that make the heart beat, according to the latest issue of the Stem Cell Reports journal.

The same team demonstrated their technique last year in live mice, transforming scar-forming cells, called fibroblasts, into beating heart muscle cells, but this is the first time that human fibroblasts have been re-programmed in this way.

So far, the work with human fibroblasts has only been done in the lab, but it paves the way for new treatments for heart attack victims. Researchers said that the cocktail of genes used to regenerate cells could one day be replaced with small drug-like molecules that would offer safer and easier delivery.

We've now laid a solid foundation for developing a way to reverse the damage [done by a heart attack] something previously thought impossible and changing the way that doctors may treat heart attacks in the future, said Dr Deepak Srivastava, director of cardiovascular disease at the Gladstone Institutes. Our findings here serve as a proof of concept that human fibroblasts can be re-programmed successfully into beating heart cells.

In 2012, Dr Srivastava and his team reported in the journal Nature that, by injecting three genes into the hearts of live mice that had been damaged by heart attack, fibroblasts could be turned into working heart cells.

The scientists attempted the same technique using human fibroblasts from foetal heart cells, embryonic stem cells and neonatal skin cells, injected with genes in petri dishes in the lab. An increased number of genes was required to transform the human cells, and the efficiency of the transformed cells was low, but the team were encouraged by the results.

While almost all the cells in our study exhibited at least a partial transformation, about 20 per cent of them were capable of transmitting electrical signals a key feature of beating hearts, said Gladstone staff scientist Ji-dong Fu, the studys lead author.

The number of people who survive heart attacks has increased considerably in recent decades. The British Heart Foundation (BHF) said earlier this year that 70 per cent of women and 68 per cent of men were now surviving. However, success in keeping people alive after a heart attack has led to a rise in the number of people suffering from the long-term after-effects, which include debilitating heart failure.

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Scientists come closer to 'mending broken hearts' by using gene therapy to repair muscles damaged in heart attacks