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Editorial Views  |   February 1995
Estimating Brain Temperature during Hypothermia 
Author Notes
  • Department of Anesthesiology, University of Iowa, Iowa City, Iowa 52242.
  • Submitted for publication September 26, 1994. Accepted for publication October 4, 1994.
Article Information
Editorial Views
Editorial Views   |   February 1995
Estimating Brain Temperature during Hypothermia 
Anesthesiology 2 1995, Vol.82, 329-330. doi:
Anesthesiology 2 1995, Vol.82, 329-330. doi:
Key words: Anesthesia; cardiovascular; neurosurgical. Brain: hypothermia; protection. Monitoring: temperature. Temperature: gradients; monitoring.
In this issue of ANESTHESIOLOGY, Stone et al. [1 ] report the findings of a clinical experiment that has been needed for decades. The results are clear and important, and it is unlikely this work will ever be repeated, nor its findings challenged. The authors investigated the concordance between brain temperature and other temperature monitoring sites during perfusion cooling and profoundly hypothermic circulatory arrest (PHCA).
Although PHCA is used most commonly in the repair of congenital heart disease, it also is often used in adult aortic arch procedures and occasionally in selected urologic, hepatic, and, as in the report by Stone et al., neurosurgical procedures. Because hypothermic brain protection is graded, with increasing protection as brain temperature decreases, [2 ] achievement of the desired level of cerebral hypothermia before the onset of ischemia (arrest) is probably the single most important determinant of the effectiveness of the technique. However, in only the rarest of circumstances is it practical or possible to measure brain temperature. Instead, in the vast majority of cases, other sites, most often nasopharynx or tympanic membrane, are used to estimate brain temperature before PHCA. Recent studies by Greeley et al. [3 ] and Kern et al. [4 ] suggest that, in 15–30% of cases, brain temperature may be significantly warmer than that measured at surrogate sites.
Directly measuring brain temperature, Stone et al. found poor concordance between brain temperature and temperatures at other sites. For example, nasopharyngeal temperature varied from 4.9 degrees Celsius greater than to 4.7 degrees Celsius less than actual brain temperature. Tympanic membrane, esophageal, and pulmonary arterial temperatures were no better. That surrogate monitoring sites sometimes overestimate brain temperature (i.e., the brain is colder than indicated) is probably not problematic; at least one is assured of the desired degree brain protection. However, that surrogate monitoring sites sometimes underestimate brain temperature (i.e., the brain is warmer than indicated) almost certainly is a problem. How, in any given patient, can one be assured of achieving desired brain temperature? Stone et al. recommend simultaneous use of at least three “central” sites (nasopharynx, esophagus, tympanic membrane, pulmonary artery) and suggest values must be in near-agreement before PHCA. Although this seems reasonable, their data indicate that this is also no guarantee. Graphic data from three individual patients show that, although central sites agreed before PHCA, brain temperature was underestimated in two patients and overestimated in one. Perhaps the only other thing we have on our side is time. Computer modeling studies indicate brain cooling during cardiopulmonary bypass is principally determined by the temperature of the blood perfusing the brain, cerebral blood flow, and the time allowed for cooling. [5 ] The shorter the period allowed for cooling (especially periods shorter than 20 min), the less likely it is brain temperature equilibration has occurred. Therefore, it would seem reasonable, once a desired surrogate temperature has been reached, to simply continue perfusion cooling for 5–10 min more. This little extra time will increase the likelihood of achieving desired brain temperature.
B. J. Hindman, M.D.; F. Dexter, M.D., Ph.D.; Department of Anesthesiology; University of Iowa; Iowa City, Iowa 52242.
REFERENCES
Stone JG, Young WL, Smith CR, Solomon RA, Wald A, Ostapkovich N, Shrebnick DB: Do standard monitoring sites reflect true brain temperature when profound hypothermia is rapidly induced and reversed? ANESTHESIOLOGY 82:344-351, 1995.
Gillinov AM, Redmond JM, Zehr KJ, Troncoso JC, Arroyo S, Lesser RP, Lee AW, Stuart RS, Reitz BA, Baumgartner WA, Cameron DE: Superior cerebral protection with profound hypothermia during circulatory arrest. Ann Thorac Surg 55:1432-1439, 1993.
Greeley WJ, Kern FH, Ungerleider RM, Boyd JL III, Quill T, Smith LR, Baldwin B, Reves JG, Sabiston DC: The effect of hypothermic cardiopulmonary bypass and total circulatory arrest on cerebral metabolism in neonates, infants and children. J Thorac Cardiovasc Surg 101:783-794, 1991.
Kern FH, Jonas RA, Mayer JE, Hanley FL, Castaneda AR, Hickey PR: Temperature monitoring during CPB in infants: Does it predict efficient brain cooling? Ann Thorac Surg 54:749-754, 1992.
Dexter F, Hindman BJ: Computer simulation of brain cooling during cardiopulmonary bypass. Ann Thorac Surg 57:1171-1179, 1994.