Go to main site

News

Why a blow to the chest can kill or save you

© iStock

© iStock

It is still a mystery why a blow to the chest can kill some people yet save others. We may be one step closer to an answer, however, thanks to a device developed by researchers at EPFL and the University of Bern that can replicate the experience in the laboratory.

A blow to the chest can have highly contrasting effects. For instance, some baseball players have died after being hit in the chest by a baseball, while patients undergoing fatal cardiac tachyarrhythmias have been saved by an appropriately timed thump to the chest. Scientists know that such blows create rapid strains on heart tissue, but they still don’t fully understand how the blows affect cardiac functioning. Researchers at EPFL’s Soft Transducers Laboratory and at the Department of Physiology of the University of Bern (Group Rohr) have developed an experimental device that lets scientists subject bioengineered heart tissue to highly dynamic strain cycles and measure its electrophysiological response. Their work has been published in Nature Communications.

The normal heartbeat is the result of an electro-mechanical coupling process. More specifically, electrical impulses invade the entire heart and “order” the heart muscle to contract. With each contraction, blood is ejected from the heart thereby ensuring stable circulation. “This coupling is essential, because that’s what makes our hearts beat at a regular pace,” says Matthias Imboden, a co-author of the study and EPFL post-doc, who performed part of his research at the Department of Physiology. 

Until recently, scientists believed that the potentially fatal effects of a blow to the chest, or on the contrary, the rescue of patients in cardiac arrest by an appropriately timed thump to the chest, were the result of the strains that interfere with the transmission of electrical impulses, thereby causing disruption of the heartbeat. But no laboratory systems previously existed to test that hypothesis. “We did have methods for reproducing cellular strain, but they created the strain too slowly to truly replicate what happens during a blow,” says Stephan Rohr, a co-author of the study and University of Bern professor. 

Replicating blow effects in the laboratory

The researchers’ experimental device can subject cardiac tissue to strain patterns that closely mimic realistic chest impacts. It consists of stretchable, extremely thin gold and carbon electrodes deposited on a silicone membrane. “The carbon electrodes create the strain in the cardiac tissue and the gold ones measure the cellular electrophysiological response,” says Herbert Shea, head of the Soft Transducers Laboratory, a co-author of the study and a professor at the EPFL's School of Engineering. The researchers tested their system on bioengineered strands of rat cardiac cells, which were placed on top of the electrodes and subjected to different strains patterns. 

Much faster strains

The device can generate cellular strains in the order of 10–12%, which is consistent with what occurs during a normal heartbeat. However, it generates that strain up to 100 times faster than what the heart encounters during normal function – just like what happens during a blow to the chest. The researchers’ device is motorless and is the only one to closely replicate the dynamics of blows to the chest, while simultaneously permitting the measurement of strain effects on the electrophysiology of the cardiac tissue.

Findings that lead in new directions 

The researchers found that contrary to what other studies had concluded, even very rapid strains do not affect the propagation of electrical impulses. “That means we need to look into other possible explanations of what exactly happens during a deadly blow to the chest,” says Rohr. “The strain sensitive element in the heart may actually not be the contracting heart cell itself but adjacent connective tissue cells.” Their device also paves the way to further research, such the effect of specific drugs or gene therapies having beneficial effects on mechano-electrical coupling in the heart.

Contacts

EPFL - Prof. Herbert Shea

021 693 6663

University of Bern - Prof. Stephan Rohr

031 631 8746

Funding

This research has received funding from the Marie Skłodowska-Curie Action H2020-MSCA-IF-2015 #701614 (to M.I.) and the Swiss National Science Foundation under grants CR32I3_166326, 20020_165993 (to H.S.) and 310030_169234 (to S.R.).

References

The research was carried out jointly by EPFL’s Soft Transducers Laboratory and the University of Bern’s Group Rohr in the Department of Physiology.

“High-speed mechano-active multielectrode array for investigating rapid stretch effects on cardiac tissue,” Nature Communications(2019), 10:834. Matthias Imboden, Etienne de Coulon, Alexandre Poulin, Christian Dellenbach, Samuel Rosset, Herbert Shea and Stephan Rohr

DOI: https://doi.org/10.1038/s41467-019-08757-2


Author: Clara Marc
Source: Mediacom
Login