3D Micro-CT Scanning Shows Fibers That Control Heart Rhythm

Scientists have developed a new computed tomography (CT) imaging method to identify tissue fibers in the heart that ensure the muscle beats in a regular rhythm.

The new three-dimensional (3D) images could provide additional clues into how the body’s heartbeat can be disturbed, which may help clinicians develop ways to reduce the risk of fibrillation--a disorder in which heart muscle contracts haphazardly and cannot pump blood rhythmically around the body.


The heart needs to pump blood in a regular rhythm to maintain a steady circulation of blood to all parts of the body. It does this through the coordinated action of the muscle tissue, that pumps the blood, and the conducting tissue, which is necessary to distribute an electrical wave to trigger every heartbeat. Until now scientists have been unable to produce high resolution 3D images of the conducting tissue to fully identify the network that controls heart rhythm.

The team of investigators, from the University of Liverpool (UK), utilized a micro-CT scanner to image hearts that had been treated with iodine to target the different parts of the tissue. They found that the solution was absorbed less appreciably by the conducting regions of the heart compared to the muscular areas of the organ, allowing scientists to distinctly identify the areas that generate electrical activity on the resulting 3D image.

Dr. Jonathan Jarvis, from the University’s Institute of Aging and Chronic Disease, said, “These new anatomically-detailed images could improve the accuracy of future computer models of the heart and help us understand how normal and abnormal heart rhythms are generated. 3D imaging will give us a more thorough knowledge of the cardiac conduction system, and the way it changes in heart disease. Computer models based on these high-fidelity images will help us to understand why the heart rhythm is vulnerable to changes in heart size, blood supply, or scarring after a heart attack. One of the major concerns for surgeons in repairing malformed hearts, for example, is to avoid damage to the tissue that distributes electrical waves. If they had access to 3D images of the conducting tissues in malformed hearts, however, it could be possible to understand where the conducting tissue is likely to be before they operate.”

The study was conducted in collaboration with Alder Hey Children’s Hospital (Liverpool, UK) and the University of Manchester (UK). The research findings were published April 30, 2012, in the journal PLoS ONE.

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University of Liverpool
Alder Hey Children’s Hospital
University of Manchester