Bethesda, Md. (Dec. 5, 2013)--There are over a million people with spinal cord injuries (SCI) in the United States alone with an estimated 11,000 new cases every year. Furthermore, it is estimated that there are, at least, 100,000 veterans with SCI, making the VA the largest integrated health care system in the world for SCI care. But despite this large prevalence, researchers are still discovering all the various ways that SCI affect those with this condition beyond the obvious paralysis. For example, researchers have long known that SCI patients are significantly more likely than people without SCI to have conditions that cause disordered breathing during sleep. These include central sleep apnea, a serious condition in which patients' breathing stops periodically during sleep due to faulty signals from the brain. However, it's been unknown whether the level of injury has any correlation with the risk of sleep-disordered breathing.
To investigate this question, Abdulghani Sankari and his colleagues at John D. Dingell VA Medical Center-Wayne State University studied breathing during sleep in eight patients with thoracic SCIs, which paralyzed their legs, and eight patients with cervical SCI, which paralyzed their torsos and all four limbs. They found that those subjects with cervical SCI were significantly more likely to have sleep-disordered breathing during sleep or be susceptible to factors that trigger it. These findings suggest that patients who are paralyzed from the neck down--or quadriplegics--have a heightened risk of central sleep apnea.
The article is entitled "Tetraplegia is a Risk Factor for Central Sleep Apnea." It appears in the Articles in PresS section of the Journal of Applied Physiology, published by the American Physiological Society. The article is available online at http://bit.
The researchers studied 16 patients with SCI. Eight of these study subjects had thoracic SCI, in which the spinal cord was damaged at the chest level, paralyzing their legs. Another eight had cervical SCI, in which the spinal cord was damaged at the neck level.
Each of these volunteers underwent initial testing at Detroit VA sleep research laboratory to assess various factors, including their breathing during sleep. Those subjects that testing showed didn't have central sleep apnea underwent another validated test on a different session at the sleep research laboratory that involved sleeping with a nasal mask connected to a ventilator that periodically induced central sleep apnea and calculated the level of carbon dioxide at which breathing stopped "apneic threshold". For those that showed central sleep apnea already during baseline testing, the researchers used a different test that involved introducing gas mixed with carbon dioxide to calculate the level required to abolish their central sleep apnea. In addition they assessed the efficiency of SCI individuals' respiratory system during sleep.
The researchers found that 63 percent of patients with cervical SCI had central sleep apnea, compared to only 13 percent of patients with thoracic SCI. These cervical SCI patients are more susceptible to central apnea and require fewer drops in carbon dioxide in their blood to trigger a bout of central sleep apnea compared to thoracic SCI patients. The efficiency of the respiratory system in cervical SCI individuals was lower and their breathing was shallower during sleep than those with thoracic SCI.
Importance of the Findings
These findings suggest that where the spinal cord is injured--in the neck, or lower--can affect the likelihood and type of breathing problems during sleep, including central sleep apnea. Understanding how and why these patients' nighttime breathing is affected could help doctors better manage their conditions, the authors say, protecting patients' and veterans' health and lives.
In addition to Abdulghani Sankari, the study team includes Amy Bascom, Susmita Chowdhuri, and M. Safwan Badr, all of Wayne State University. Dr. Sankari is a recipient of Career Development Award from the Veterans Affairs Biomedical Laboratory for Research and Development.
Physiology is the study of how molecules, cells, tissues, and organs function in health and disease. Established in 1887, the American Physiological Society (APS) was the first US society in the biomedical sciences field. The Society represents more than 11,000 members and publishes 14 peer-reviewed journals with a worldwide readership.
NOTE TO EDITORS: To schedule an interview with a member of the research team, please contact Donna Krupa at firstname.lastname@example.org, @Phyziochick, or 301.634.7209. The article is available online at http://bit.