Research identifies therapy for improving survival rates for heart attack victims
MUMBAI: In pre-clinical trials, New Zealand’s University of Otago researchers have discovered a promising new therapy that has the potential to be used clinically for improving survival rates for people who suffer a heart attack.
The researchers from Heart Otago - a group of cardiovascular researchers and clinicians located at the University and Dunedin Hospital - the Brain Health Research Centre and Centre for Neuroendocrinology, found blocking specific oxytocin cells within the brain after a heart attack dramatically improved survival outcome. Their research was recently published in biological sciences journal Communications Biology. “Our results strongly advocate blockade of oxytocin cells as a promising emerging therapy for the acute management of an acute heart attack,” Associate Professor Daryl Schwenke says.
An acute heart attack, or myocardial infection, is one of the most common causes of death in industrialised societies. Often death can occur within the first few hours following a heart attack due to a dangerous overstimulation of nerves that control heart function.
Associate professor Schwenke explains that when a person has a heart attack the brain thinks the heart is damaged, so it “speaks a lot louder to the heart”.
The reason why the nerves that control heart function become over-activated has remained unclear. However, Associate Professor Schwenke and his colleagues Dr Ranjan Roy, Dr Rachael Augustine and Professor Colin Brown, have recently identified a distinct region within the brain containing oxytocin cells that become “switched on” immediately after an acute heart attack.
Although oxytocin is traditionally associated with uterine contractions during labour and breastfeeding, some of these cells also modulate the nerves that control the heart.
“When we experimentally blocked these oxytocin cells after a heart attack, we found that the heart nerves did not become activated and, remarkably, survival and outcome were dramatically improved,” Associate Professor Schwenke says.
This breakthrough is still currently in the experimental stages.