Study predicts heart cells' response to dwindling oxygen

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Time is of the essence when treating a patient undergoing a heart attack. Cardiac surgeons attempt to quickly stabilize the heart by applying reperfusion, a technique that restores oxygen to the heart by opening up blocked vessels with balloons and stents. While reperfusion can restore cardiac function, such sudden infusions of oxygen can also further injure severely depleted regions of the heart.

“It’s a double-edged sword,” says Anthony McDougal, a graduate student in MIT’s Department of Mechanical Engineering. “The rapid return of oxygen is necessary for the heart to survive, but it could also overwhelm the heart.”

Time is of the essence when treating a patient undergoing a heart attack. Cardiac surgeons attempt to quickly stabilize the heart by applying reperfusion, a technique that restores oxygen to the heart by opening up blocked vessels with balloons and stents. While reperfusion can restore cardiac function, such sudden infusions of oxygen can also further injure severely depleted regions of the heart.

“It’s a double-edged sword,” says Anthony McDougal, a graduate student in MIT’s Department of Mechanical Engineering. “The rapid return of oxygen is necessary for the heart to survive, but it could also overwhelm the heart.”

Now McDougal has developed a model that predicts a single heart cell’s response to dwindling supplies of oxygen. Specifically, it evaluates a cell’s ability to keep producing ATP — a cell’s primary fuel source — and stay alive, even as it is increasingly deprived of oxygen.

The model is a first step in predicting whether reperfusion techniques will aid or further harm a depleted heart. It may also help to determine the optimal amount of oxygen to apply, given the degree of a heart’s deterioration.

Read more at Massachusetts Institute of Technology (MIT)

Image: Graduate student Anthony McDougal has developed a model that predicts a single heart cell’s response to dwindling supplies of oxygen. Credit: MIT News