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New computer model sheds light on biological events leading to sudden cardiac death

Date:
November 28, 2017
Source:
Johns Hopkins University
Summary:
A powerful new computer model replicates the biological activity within the heart that precedes sudden cardiac death.
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Some heart disease patients face a higher risk of sudden cardiac death, which can happen when an arrhythmia -- an irregular heartbeat -- disrupts the normal electrical activity in the heart and causes the organ to stop pumping. Arrhythmias linked to sudden cardiac death are very rare, however, making it difficult to study how they occur -- and how they might be prevented.

To make it much easier to discover what triggers this deadly disorder, a team led by Johns Hopkins researchers constructed a powerful new computer model that replicates the biological activity within the heart that precedes sudden cardiac death.

In a study published recently in PLOS Computational Biology, the team reported that the digital model has yielded important clues that could provide treatment targets for drug makers.

"For the first time, we have come up with a method for relating how distressed molecular mechanisms in heart disease determine the probability of arrhythmias in cardiac tissue," said Raimond L. Winslow, the Raj and Neera Singh Professor of Biomedical Engineering at Johns Hopkins and senior author of the study.

"The importance of this," said Winslow, who also is director of the university's Institute for Computational Medicine, "is that we can now quantify precisely how these dysfunctions drive and influence the likelihood of arrhythmias. That is to say, we now have a way of identifying the most important controlling molecular factors associated with these arrhythmias."

With this knowledge, Winslow said, researchers will be better able to develop treatments to keep some deadly heart rhythms from forming. "It could lead to better drugs that target the right mechanisms," Winslow said. "If you can find a molecule that blocks this particular action, then doing so will significantly reduce the probability of an arrhythmia, whereas other manipulations will have comparatively negligible effects."

The lead author of the study was Mark A. Walker, who worked on the problem while earning his Johns Hopkins doctoral degree under Winslow's supervision. Walker said he and his colleagues used computer models to determine what activity was linked to arrhythmia at three biological levels: in the heart tissue as a whole, within individual heart cells, and within the molecules that make up the cells, including small proteins called ion channels that control the movement of calcium in the heart.

"Calcium is an important player in the functioning of a heart cell," said Walker, who now works as a computational biologist at the Broad Institute, a research center affiliated with Harvard University and the Massachusetts Institute of Technology. "There are a lot of interesting questions about how the handling of calcium in heart cells can sort-of go haywire."

Walker and his colleagues chose to focus on one intriguing question about this process: when heart cells possess too much calcium, which can happen in heart disease patients, how does this overload of calcium trigger an arrhythmia?

The team discovered that heart cells respond by expelling excess calcium, and in doing so, they generate an electrical signal. If by chance, a large enough number of these signals are generated at the same time, it can trigger an arrhythmia.

"Imagine if you have a bunch of people in a room, and you want to test the strength of the floor they are all standing on," Walker said. "It's not a very strong floor, so if there's enough force on it, it will break. You tell everyone that on the count of three, jump in the air. They all land on the floor, and you try to figure out what's the probability that the floor will break, given that everyone is going to jump at a slightly different time, people will weigh different amounts, and they might jump to different heights. These are all random variables."

Similarly, Walker said, random variables also exist in trying to determine the probability that enough calcium-related electrical signals will simultaneously discharge in the heart to set off a lethal arrhythmia. Because the circumstances that cause sudden cardiac death are so rare, it makes them very tough to predict.

"You're trying to figure out what the probability is," Walker said. "The difficulty of doing that is if the probability is one in a million, then you have to do tens of millions of trials to estimate that probability. One of the advances that we made in this work was that we were able to figure out how to do this with really just a handful of trials."

Walker and Winslow both cautioned that, at present, the new computer model cannot predict which heart patients face a higher risk of sudden cardiac death. But they said the model should speed up the pace of heart research and the development of related medicines or treatments such as gene therapy. They said the model will be shared as free open-source software.


Story Source:

Materials provided by Johns Hopkins University. Note: Content may be edited for style and length.


Journal Reference:

  1. Mark A. Walker, Viatcheslav Gurev, John J. Rice, Joseph L. Greenstein, Raimond L. Winslow. Estimating the probabilities of rare arrhythmic events in multiscale computational models of cardiac cells and tissue. PLOS Computational Biology, 2017; 13 (11): e1005783 DOI: 10.1371/journal.pcbi.1005783

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Johns Hopkins University. "New computer model sheds light on biological events leading to sudden cardiac death." ScienceDaily. ScienceDaily, 28 November 2017. <www.sciencedaily.com/releases/2017/11/171128160448.htm>.
Johns Hopkins University. (2017, November 28). New computer model sheds light on biological events leading to sudden cardiac death. ScienceDaily. Retrieved November 20, 2024 from www.sciencedaily.com/releases/2017/11/171128160448.htm
Johns Hopkins University. "New computer model sheds light on biological events leading to sudden cardiac death." ScienceDaily. www.sciencedaily.com/releases/2017/11/171128160448.htm (accessed November 20, 2024).

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