The Significance of Electroencephalography in the Hypothermic Circulatory Arrest in Human.
- Author:
Yang Bin JEON
1
;
Chang Ha LEE
;
Chan Young NAH
;
Jung Ho KANG
Author Information
1. Department of thoracic and cardiovascular surgery, Sejong General Hospital, Puchon.
- Publication Type:Original Article
- Keywords:
Total circulatory arrest, induced;
Electroencephalography;
Hypothermia
- MeSH:
Aorta, Thoracic;
Aortic Diseases;
Body Temperature;
Brain;
Cardiopulmonary Bypass;
Electroencephalography*;
Humans*;
Hypothermia;
Metabolism;
Nasopharynx;
Transplants
- From:The Korean Journal of Thoracic and Cardiovascular Surgery
2001;34(6):465-471
- CountryRepublic of Korea
- Language:Korean
-
Abstract:
BACKGROUND: Hypothermia protects the brain by suppressing the cerebral metabolism and it is performed well enough before the total circulatory arrest(TCA) in the operation of aortic disease. Generally, TCA has been performed depending on the rectal or nasopharyngeal temperatures; however, there is no definite range of optimal temperature for TCA or an objective indicator determining the temperature for safe TCA. In this study, we tried to determine the optimal range of temperature for safe hypothermic circulatory arrest by using the intraoperative electroencephalogram(EEG), and studied the role of EEG as an indicator of optimal hypothermia. MATERIAL AND METHOD: Between March, 1999 and August 31, 2000, 27 patients underwent graft replacement of the part of thoracic aorta using hypothermia and TCA with intraoperative EEG. The rectal and nasopharyngeal temperatures were monitored continuously from the time of anesthetic induction and the EEG was recorded with a ten-channel portable electroencephalography from the time of anesthetic induction to electrocerebral silence(ECS). RESULT: On ECS, the rectal and nasopharyngeal temperatures were not consistent but variable(rectal 11degree C -25degree C, nasopharynx 7.7degree C -23degree C). The correlation between two temperatures was not significant(p=0.171). The cooling time from the start of cardiopulmonary bypass to ECS was also variable(25-127min), but correlated with the body surface area(p=0.027). CONCLUSION: We have found that ECS appeared at various body temperatures, and thus, the use of rectal or nasopharyngeal temperature were not useful in identifying ECS. Conclusively, we can not fully assure cerebral protection during hypothermic circulatory arrest in regards to the body temperatures, and therefore, the intraoperative EEG is one of the necessary methods for determining the range of optimal hypothermia for safe circulatory arrest.