Search
Menu
PI Physik Instrumente - Fast Steering LB LW 11/24

Light to the Heart to Restore Healthy Beats

Facebook X LinkedIn Email
BALTIMORE, Aug. 29, 2013 — When a person’s heart slows or stops, the current practice is to jump-start it with a blast of electricity from a pacemaker or defibrillator. But a multi-university team aims to put an optogenetic twist on the procedure by replacing the violent jolt of electricity with gently applied light.

“Applying electricity to the heart has its drawbacks," said team leader professor Natalia Trayanova of Johns Hopkins. "When we use a defibrillator, it's like blasting open a door because we don't have the key. It applies too much force and too little finesse. We want to control this treatment in a more intelligent way. We think it's possible to use light to reshape the behavior of the heart without blasting it." 

Light-sensitive cells are already being used to control certain brain activities. Trayanova and other bioengineers at Stony Brook and Johns Hopkins plan to give this technique a cardiac twist so that in the near future doctors can use low-energy light to solve serious heart problems such as arrhythmia. Her team plans to accomplish their less painful method by using biological lab data and intricate computer modeling. 

Natalia TrayanovaTo achieve this, Trayanova's team is diving into the field of optogenetics — the insertion of light-responsive proteins called opsins into cells. When exposed to light, these proteins become tiny portals within the target cells, allowing a stream of ions (an electric charge) to pass through. Early researchers have begun using this tactic to control the bioelectric behavior of certain brain cells, forming a first step toward treating psychiatric disorders with light.

Trayanova has spent many years developing highly detailed computer models of the heart, simulating whole cardiac behavior as well as molecular and cellular behavior. The researchers reported that they had successfully tested the light-based tactic on the computer-modeled heart.

Trayanova's team will use this model to conduct virtual experiments, trying to determine how to position and control the light-sensitive cells to help the heart maintain healthy rhythm and pumping activity. They will also try to gauge how much light is needed to activate the healing process.

Excelitas PCO GmbH - PCO.Edge 11-24 BIO MR

The Stony Brook collaborators are working on techniques to make heart tissue light-sensitive by inserting opsins into cells. They also will test how these cells respond when illuminated. The overall goal is to use the computer model to push the research closer to the day when doctors can begin treating their heart patients with gentle light beams. The researchers say it could happen within a decade.

In this illustration, the 'optrode' at left delivers blue light to the heart via a fiber optic tip. In the enlargement at right, a heart cell (large red oval) contains an implanted light-sensitive 'opsin' protein (blue oval) that works alongside the heart's own proteins (yellow ovals).
In this illustration, the "optrode" at left delivers blue light to the heart via a fiber optic tip. In the enlargement at right, a heart cell (large red oval) contains an implanted light-sensitive "opsin" protein (blue oval) that works alongside the heart's own proteins (yellow ovals). This teamwork allows the cell to convert light energy into an electric kick that triggers a healthy heartbeat. Courtesy of Patrick M. Boyle. 

"The most promising thing about having a digital framework that is so accurate and reliable is that we can anticipate which experiments are really worth doing to move this technology along more quickly," said postdoctorate fellow Patrick M. Boyle. "One of the great things about using light is that it can be directed at very specific areas. It also involves very little energy. In many cases, it's less harmful and more efficient than electricity."

After the technology is honed through the computer modeling tests, it could be incorporated into light-based pacemakers and defibrillators.

The research was published Aug. 28 in the online journal Nature Communications.

For more information, visit: www.jhu.edu  

Published: August 2013
Glossary
bioelectricity
Bioelectricity refers to the electrical potentials and currents generated by biological processes within living organisms. These electrical phenomena arise from the movement of ions across cell membranes and the activity of specialized cells and tissues that generate and conduct electrical signals. Bioelectricity plays a crucial role in various physiological functions and behaviors. Cellular basis: Bioelectric signals originate primarily from the movement of ions such as sodium (Na+),...
optogenetics
A discipline that combines optics and genetics to enable the use of light to stimulate and control cells in living tissue, typically neurons, which have been genetically modified to respond to light. Only the cells that have been modified to include light-sensitive proteins will be under control of the light. The ability to selectively target cells gives researchers precise control. Using light to control the excitation, inhibition and signaling pathways of specific cells or groups of...
AmericasbioelectricityBiophotonicscardiac researchCommunicationsdefibrillatorElectronics & Signal AnalysisJohns Hopkinslight based cardiac treatmentLight SourcesNatalia TrayanovaoptogeneticspacemakerPatrick BoyleResearch & TechnologySoftwareStony Brook

We use cookies to improve user experience and analyze our website traffic as stated in our Privacy Policy. By using this website, you agree to the use of cookies unless you have disabled them.