Snipping key nerves may help life threatening heart rhythms

December 19, 2011

What do sweaty palms and abnormal heart rhythms have in common? Both can be initiated by the nervous system during adrenaline-driven "flight or fight" stress reaction when the body senses danger.

Governed by the sympathetic nervous system, an abnormal "flight or fight" stress response which causes excessive sweaty palms (called hyperhidrosis) may also contribute to problems like dangerous irregular heart rhythms from the lower chambers of the heart, called ventricular arrhythmias.

UCLA cardiologists have found that surgery to snip nerves related to the sympathetic nervous system on both the left and right sides of the chest, may be helpful in stopping dangerous incessant ventricular arrhythmias -- called an electrical storm -- when other treatment methods have failed. This same type of surgery has been used for years to alleviate hyperhidrosis.

The UCLA team's findings are reported in the Dec. 27/Jan. 3 issue of the Journal of the American College of Cardiology. This is one of the first studies to assess the impact of performing the surgery on both sides of the heart to control arrhythmias, called a bilateral cardiac sympathetic denervation (BCSD). This builds on previous work at UCLA where this procedure was just done on the left side, but to obtain relief, some patients may need the procedure performed bilaterally.

Many people suffer from ventricular arrhythmias, which is the leading cause of death in the U.S. (400,000 deaths/year). These arrhythmias can usually be controlled by medications, an implantable cardioverter defibrillator (ICD) that automatically shocks the heart to help bring it back into normal rhythm or a procedure called catheter ablation, which stops the arrhythmia by providing a targeted burn to the tiny area of the heart causing the irregular heart beat.

"When these treatment options fail, especially for a patient experiencing a life-threatening electrical storm, the situation becomes critical. We are always seeking additional options to help patients," said senior study author Dr. Kalyanam Shivkumar, director, UCLA Cardiac Arrhythmia Center and co-director of the Oppenheimer Family Center for Neurobiology of Stress at UCLA.

The UCLA findings add to a growing field of research into the sympathetic nervous system's impact on stress and possible role in disease. Shivkumar notes that this may provide a unique opportunity. If snipping the cardiac sympathetic nerve proves to effectively alleviate irregular heart rhythms, perhaps this could be a treatment initiated early, before the disease manifests.

"In the future, we may be able to correct what is wrong with the heart early, like fixing what's broken in an airplane engine before we need a parachute like an implantable defibrillator," said Shivkumar, professor of medicine and radiological sciences at the David Geffen School of Medicine at UCLA.

Specifically, surgeons cut the stellate ganglia, part of the sympathetic nervous system that delivers information to the body about stress and initiates the "flight or fight" response. These ganglia contain thousands of nerve cell bodies, and run on either side of the spinal cord in long chains. From these ganglia, nerves then travel to the heart.

To help control arrhythmias, surgeons snip the stellate ganglion, as well as the following three ganglia below it to completely remove these nerves that are destined for the heart. The procedure can be done on the left, right, or both sides of the thorax, which is the area of the body located between the neck and the abdomen containing organs such as the heart and lungs

For the study, researchers reviewed records from patients at UCLA and a collaborating center in France. The patients presented with electrical storm. The average age was 60 and all were poor candidates for a heart transplant. After other treatments had failed such as medications, catheter ablation and an implantable defibrillator, patients received surgeries to snip the cardiac sympathetic nerves destined for both sides of the heart.

Researchers found that after the surgery, four out of the six study patients completely responded with no more arrhythmias. One patient had a partial response and one had no response at all.

With their heart rhythms stabilized, three of the responding patients received no more shocks from their ICDs, which would previously occur when the devices tried to normalize irregular rhythms. One of these patients had been experiencing 11 shocks a day. The patient who partially responded to treatment had a shock reduction of more than 50 percent.

All five responding patients survived until hospital discharge. Two of the responding patients passed away after discharge due to health issues not related to arrhythmias. No major operative complications occurred in the patients studied. Typical side effects related to this procedure such as alterations in sweating or temperature regulation were not significant. Researchers note that these side effects are usually acceptable to the seriously ill patients who are experiencing an electrical storm, considering that the alternative includes continued arrhythmias, ICD shocks or death.

According to researchers, cutting the cardiac sympathetic nerve may interrupt pro-arrhythmic signaling within the heart tissue or stellate ganglion, thus stopping the irregular heart rhythms.

"We are encouraged by this small study's results, and plan to further examine the role of this procedure in suppressing arrhythmias in a larger patient population," said Dr. Olujimi Ajijola, a UCLA cardiology fellow and lead author of the study.

"This type of innovative therapy is only possible because of close scientific and clinical collaborations between multiple teams of specialists caring for very sick patients" said co-author Dr. Aman Mahajan, chief of cardiac anesthesia and vice chairman of the Department of Anesthesia at UCLA.
The research by this group in this area was supported by the National Heart, Lung and Blood Institute, part of the National Institutes of Health.

Other authors include: Dr. Nicholas Lellouche from Henri Mondor Hospital, Creteil, France, Dr. Tara Bourke, Dr. Roderick Tung, all from the UCLA Cardiac Arrhythmia Center and Dr. Samuel Ahn, Department of Surgery.

University of California - Los Angeles Health Sciences

Related Stress Articles from Brightsurf:

Stress-free gel
Researchers at The University of Tokyo studied a new mechanism of gelation using colloidal particles.

Early life stress is associated with youth-onset depression for some types of stress but not others
Examining the association between eight different types of early life stress (ELS) and youth-onset depression, a study in JAACAP, published by Elsevier, reports that individuals exposed to ELS were more likely to develop a major depressive disorder (MDD) in childhood or adolescence than individuals who had not been exposed to ELS.

Red light for stress
Researchers from the Institute of Industrial Science at The University of Tokyo have created a biphasic luminescent material that changes color when exposed to mechanical stress.

How do our cells respond to stress?
Molecular biologists reverse-engineer a complex cellular structure that is associated with neurodegenerative diseases such as ALS

How stress remodels the brain
Stress restructures the brain by halting the production of crucial ion channel proteins, according to research in mice recently published in JNeurosci.

Why stress doesn't always cause depression
Rats susceptible to anhedonia, a core symptom of depression, possess more serotonin neurons after being exposed to chronic stress, but the effect can be reversed through amygdala activation, according to new research in JNeurosci.

How plants handle stress
Plants get stressed too. Drought or too much salt disrupt their physiology.

Stress in the powerhouse of the cell
University of Freiburg researchers discover a new principle -- how cells protect themselves from mitochondrial defects.

Measuring stress around cells
Tissues and organs in the human body are shaped through forces generated by cells, that push and pull, to ''sculpt'' biological structures.

Cellular stress at the movies
For the first time, biological imaging experts have used a custom fluorescence microscope and a novel antibody tagging tool to watch living cells undergoing stress.

Read More: Stress News and Stress Current Events is a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to