Correlated Neural Activity in Cortex and Thalamus Following Brain Injury
It has been known that a characteristic
Burst-Suppression (BS) pattern appears in EEG during the early
recovery period following Cardiac Arrest (CA). Here, to explore the
relationship between cortical and subcortical neural activities
underlying BS, extracellular activity in the parietal cortex and the
centromedian nucleus of the thalamus and extradural EEG were
recorded in a rodent CA model. During the BS, the cortical firing rate
is extraordinarily high, and that bursts in EEG correlate to dense spikes
in cortical neurons. Newly observed phenomena are that 1) thalamic
activity reemerges earlier than cortical activity following CA, and 2)
the correlation coefficient of cortical and thalamic activities rises
during BS period. These results would help elucidate the underlying
mechanism of brain recovery after CA injury.
[1] The American Heart Association Statistics Committee and Stroke
Statistics Subcommittee, “Heart Disease and Stroke Statistics—2007
Update,” Circulation, vol. 115, pp. e69-e171, 2007.
[2] G. Chatrian, L. Bergamini, M. Dondey, D. Klass, M. Lennox-Buchthal,
and I. Petersen, “A glossary of terms most commonly used by clinical
electroencephalographers,” Electroencephalogr. Clin. Neurophysiol.,vol.
37, pp. 538-548, 1974.
[3] R. L. Swank and C. W. Watson, “Effects of barbiturates and ether on
spontaneous electrical activity of dog brain,” J. Neurophysiol., vol. 12,
pp. 137-160, 1949.
[4] A. J. Derbyshire, B. Rempel, A. Forbes, and E. F. Lambert, “Effect of
anesthetics on action potentials in cerebral cortex of the cat,” Amer. J.
Physiol., vol. 116, pp. 577-596, 1936.
[5] E. O. Jorgensen and S. Holm, “The natural course of neurological
recovery following cardiopulmonary resuscitation,” Resuscitation, vol.
36, pp. 111-122, 1998.
[6] R. Geocadin, J. Muthuswamy, D. Sherman, N. Thakor, and D. Hanley,
“Early electrophysiological and histologic changes after global cerebral
ischemia in rats,” Mov. Disord., vol. 15, suppl. 1, pp. 14-21, 2000.
[7] R. Geocadin, D. Sherman, H. Hansen, T. Kimura, E. Niedermeyer, N.
Thakor, and D. Hanley, “Neurological recovery by EEG bursting after
resuscitation from cardiac arrest in rats,” Resuscitation, vol. 55, pp.
193-200, 2002.
[8] N. Schaul, “The fundamental neural mechanisms of
electroencephalography,” Electroencephalogr. Clin. Neurophysiol., vol.
106, pp. 101-107, 1998.
[9] D. Contreras, A. Destexhe, T. Sejnowski, and M. Steriade,
"Spatiotemporal Patterns of Spindle Oscillations in Cortex and
Thalamus,” J. Neurosci., vol. 17, no. 3, pp. 1179-1196, 1997.
[10] M. Steriade, F. Amzica and D. Contreras, “Cortical and thalamic cellular
correlates of electroencephalographic burst-suppression,”
Electroencephalogr. Clin. Neurophysiol., vol. 90, pp. 1-16, 1994.
[11] N. Schiff N and F. Plum, “The role of arousal and "gating" systems in the
neurology of impaired consciousness,” J. Clin. Neurophysiol., vol. 17, pp.
438-452, 2000.
[12] Z. Nenadic and J. W. Burdick, “Spike detection using the continuous
wavelet transform,” IEEE T. Bio-med. Eng., vol. 52, pp. 74-87, 2005.
[13] T. Ohmoto, Y. Mimura, Y. Baba, T. Miyamoto, Y. Matsumoto, A.
Nishimoto, and K. Matsumoto, “Thalamic control of spontaneous
alpha-rhythm and evoked responses,” Appl. Neurophysiol., vol. 41, pp.
188-192, 1978.
[14] S. A. Mitelman, W. Byne, E. M. Kemether, R. E. Newmark, E. A. Hazlett,
M. M. Haznedar, and M. S. Buchsbaum, “Metabolic thalamocortical
correlations during a verbal learning task and their comparison with
correlations among regional volumes,” Brain Res., vol. 1114, pp.
125-137, 2006.
[1] The American Heart Association Statistics Committee and Stroke
Statistics Subcommittee, “Heart Disease and Stroke Statistics—2007
Update,” Circulation, vol. 115, pp. e69-e171, 2007.
[2] G. Chatrian, L. Bergamini, M. Dondey, D. Klass, M. Lennox-Buchthal,
and I. Petersen, “A glossary of terms most commonly used by clinical
electroencephalographers,” Electroencephalogr. Clin. Neurophysiol.,vol.
37, pp. 538-548, 1974.
[3] R. L. Swank and C. W. Watson, “Effects of barbiturates and ether on
spontaneous electrical activity of dog brain,” J. Neurophysiol., vol. 12,
pp. 137-160, 1949.
[4] A. J. Derbyshire, B. Rempel, A. Forbes, and E. F. Lambert, “Effect of
anesthetics on action potentials in cerebral cortex of the cat,” Amer. J.
Physiol., vol. 116, pp. 577-596, 1936.
[5] E. O. Jorgensen and S. Holm, “The natural course of neurological
recovery following cardiopulmonary resuscitation,” Resuscitation, vol.
36, pp. 111-122, 1998.
[6] R. Geocadin, J. Muthuswamy, D. Sherman, N. Thakor, and D. Hanley,
“Early electrophysiological and histologic changes after global cerebral
ischemia in rats,” Mov. Disord., vol. 15, suppl. 1, pp. 14-21, 2000.
[7] R. Geocadin, D. Sherman, H. Hansen, T. Kimura, E. Niedermeyer, N.
Thakor, and D. Hanley, “Neurological recovery by EEG bursting after
resuscitation from cardiac arrest in rats,” Resuscitation, vol. 55, pp.
193-200, 2002.
[8] N. Schaul, “The fundamental neural mechanisms of
electroencephalography,” Electroencephalogr. Clin. Neurophysiol., vol.
106, pp. 101-107, 1998.
[9] D. Contreras, A. Destexhe, T. Sejnowski, and M. Steriade,
"Spatiotemporal Patterns of Spindle Oscillations in Cortex and
Thalamus,” J. Neurosci., vol. 17, no. 3, pp. 1179-1196, 1997.
[10] M. Steriade, F. Amzica and D. Contreras, “Cortical and thalamic cellular
correlates of electroencephalographic burst-suppression,”
Electroencephalogr. Clin. Neurophysiol., vol. 90, pp. 1-16, 1994.
[11] N. Schiff N and F. Plum, “The role of arousal and "gating" systems in the
neurology of impaired consciousness,” J. Clin. Neurophysiol., vol. 17, pp.
438-452, 2000.
[12] Z. Nenadic and J. W. Burdick, “Spike detection using the continuous
wavelet transform,” IEEE T. Bio-med. Eng., vol. 52, pp. 74-87, 2005.
[13] T. Ohmoto, Y. Mimura, Y. Baba, T. Miyamoto, Y. Matsumoto, A.
Nishimoto, and K. Matsumoto, “Thalamic control of spontaneous
alpha-rhythm and evoked responses,” Appl. Neurophysiol., vol. 41, pp.
188-192, 1978.
[14] S. A. Mitelman, W. Byne, E. M. Kemether, R. E. Newmark, E. A. Hazlett,
M. M. Haznedar, and M. S. Buchsbaum, “Metabolic thalamocortical
correlations during a verbal learning task and their comparison with
correlations among regional volumes,” Brain Res., vol. 1114, pp.
125-137, 2006.
@article{"International Journal of Medical, Medicine and Health Sciences:71096", author = "Young-Seok Choi", title = "Correlated Neural Activity in Cortex and Thalamus Following Brain Injury", abstract = "It has been known that a characteristic
Burst-Suppression (BS) pattern appears in EEG during the early
recovery period following Cardiac Arrest (CA). Here, to explore the
relationship between cortical and subcortical neural activities
underlying BS, extracellular activity in the parietal cortex and the
centromedian nucleus of the thalamus and extradural EEG were
recorded in a rodent CA model. During the BS, the cortical firing rate
is extraordinarily high, and that bursts in EEG correlate to dense spikes
in cortical neurons. Newly observed phenomena are that 1) thalamic
activity reemerges earlier than cortical activity following CA, and 2)
the correlation coefficient of cortical and thalamic activities rises
during BS period. These results would help elucidate the underlying
mechanism of brain recovery after CA injury.", keywords = "Cortex, thalamus, cardiac arrest, burst-suppression.", volume = "9", number = "8", pages = "656-4", }
