Thermoelectric Device «ALTEC-7012» for Human Head Cooling

TitleThermoelectric Device «ALTEC-7012» for Human Head Cooling
Publication TypeJournal Article
Year of Publication2016
AuthorsAnatychuk, LI, Knyshov, GV, Krykunov, ОА, Kobyliansky, RR, Tyumentsev, VA, Moskalyk, ІА
Short TitleSci. innov.
DOI10.15407/scine12.05.052
Volume12
Issue5
SectionResearch and Engineering Innovative Projects of the National Academy of Sciences of Ukraine
Pagination52-58
LanguageEnglish
Abstract
The results of computer simulation of thermophysical processes in the human head at given heat fluxes on its surface have been presented. The disadvantages of the existing physical models of the human head have been established and the ways for their improvement have been proposed. A prototype ALTEC-7012 thermoelectric device for cooling the human head has been designed and manufactured. The device is promising for human brain hypothermia.
Keywordsbrain hypoxia, computer simulation, human head cooling, thermoelectric cooling
References
1. Negovsky V.A. Resuscitation and artificial hypothermia. Moscow: Medgiz, 1960 [in Russian].
2. Bukov V.A. Cold and Organism. Issues of Deep Cooling of Animals and Humans. Leningrad: S.M. Kirov Military Medical Academy, 1964 [in Russian].
3. Ugriumova V.M. Heavy closed trauma of the skull and brain (diagnosis and treatment). Moscow: Meditsina Publ., 1974 [in Russian].
4. Artificial Hypothermia. Great Medical Encyclopedia in 29 volumes, Ed.by B.V. Petrovsky, 3-d ed. Moscow: Soviet Encyclopedia, 1989, Vol. 5, P. 568.
5. Ivaschenko E.I. Change in Constant Potential Level for Patients Suffering from Brain Hemorrhage on Exposure to Local Craniocerebral Hypothermia During the First Hours of Stroke: Proc. of Age-Specific Physiology Laboratory of the Brain Research Institute of Russian Academy of Medical Sciences. Moscow, 1995. 23 p. [in Russian].
6. The hypothermia after cardiac arrest study Group. Mild therapeutic hypothermia to improve the neurologic outcome after cardiac arrest. NEJM. 2002. 364(8): 549-556.
7. Prandini M.N., Neves Filho A., Lapa A.J., Stavale J.N. Mild hypothermia reduces polymorphonuclear leukocytes infiltration in induced brain inflammation. Arq. Neu ropsiquiatr. 2005. 63(3B): 779-784.
https://doi.org/10.1590/S0004-282X2005000500012
8. Usenko L.V., Tsarev A.V. Artificial Hypothermia in Modern Resuscitation Science. Obschaya Reanimatologiya. 2009. V(1): 21-23 [in Russian].
9. Belous A.M., Grischenko V.I. Cryobiology. Kyiv: Naukova Dumka, 1994 [in Russian].
10. Shevelyov O.A., Butrov A.V. Curative Hypothermia Technologies in the Intensive Therapy and Resuscitation. Emergency Medicine. 2010. No. 3: 45-49 [in Russian].
11. Harris B., Andrews P.J.D., Murray G.D., Forbes J., Moseley O. Systematic review of head cooling in adults after traumatic brain injury and stroke. Health Technology Assessment. 2012. 16(45). 175 p.
12. Smirnov O. New Method of Body Cooling (or Heating) and Craniocerebral Hypothermia Device. Biomedical J. 1968. No. 2: 343-347 [in Russian].
13. Smirnov O. Method for Improving the Efficiency of Air Hypothermia and Brain Cooling Device. Biomedical J., 1969. No. 3: 257-260 [in Russian].
14. Cincinnati Sub-Zero. [Electronic Resource]: Web-site. Mode of access: http://www.cszmedical.com/. Title from the screen.
15. Harris O.A., Muh C.R., Surles M.C., Pan Y., Rozycki G., Macleod J. and Easley K. Discrete cerebral hypothermia in the management of traumatic brain injury: a randomized controlled trial. J Neurosurg. 2009. No. 110: 1256-1264. 16. Patent US 20100168825 A1. Device for cooling a body part. Ingrid Barbknecht. 2010.
17. Centermed. [Electronic Resource]: Web-site. Mode of access : http://www.cmed-plus.ru/atg.html. Title from the screen.
18. Cool-Cap System Gets FDA Nod. Medgadget.com. Retrieved 2009-10-13.
19. Cool-Cap System — Children’s Hospital — Scott & White — Central Texas. Sw.org. Retrieved, 2009. pp. 10-13.
20. Ahiska R., Gűler İ.,YavuzA. H., Toprak A. Neuro-fuzzy inference system for control of a thermoelectric brain cooler. Journal of Thermoelectricity. 2008. No. 2: 64-70 [in Ukrainian].
21. Fiala D., Lomas K.J., Stohrer M.A. Computer model of human thermoregulation for a wide range of environmental conditions: the passive system. J. Appl. Physiol. (1985). 1999 Nov; 87(5): 1957-1972.
22. Xiaojiang Xu, Peter Tikuisis and Gordon Giesbrecht. A mathematical model for human brain cooling during cold-water near-drowning. J Appl Physiol. 1999. No. 86: 265-272.
23. Brian H. Dennis, Robert C. Eberhart, George S. Dulikravich, Steve W. Radons. Finite element simulation of cooling of realistic 3-d human head and neck. Journal of biomechanical engineering. January 2004. No. 125: 832-840.
24. Matthew A. Neimark, Angelos-Aristeidis Konstas, Jae H. Choi, Andrew F. Laine, John Pile-Spellman. Brain cooling maintenance with cooling cap following induction with intracarotid cold saline infusion: A quantitative model. Journal of Theoretical Biology. 2008. No. 253: 333-344.
25. Michael Christiansen, Nikolai Rakhilin, Anna Tarakanova, Kevin Wong. Modeling brain cooling treatment approved for hypoxic-ischemic encephalopathy in infants to treat stroke and cardiac arrest in adult patients. Cornell University. Fall. 2010. 24 p.
26. Harris B.A., Andrews P.J.D., Marshall I., Robinson T.M. and Murray G.D. Forced convective head cooling device reduces human cross-sectional brain temperature measured by magnetic resonance: a non-randomized healthy volunteer pilot study. British Journal of Anaesthesia. 2008. 100(3): 365-72.
https://doi.org/10.1093/bja/aem405
27. COMSOL Multiphysics User’s Guide. COMSOLAB, 2010. 804 p.
28. Jiang S.C., Ma N., Li H.J., Zhang X.X. Effects of thermal properties and geometrical dimensions on skin burn injuries. Beijing, China, 2002. pp.713-117.
29. Kobylianskyi R.R., Moskalyk I.A. The prospects of using thermoelectricity for human head cryotherapy. Journal of Thermoelectricity. 2015. No. 4: 85-94 [in Ukrainian].
30. Kobylianskyi R.R., Moskalyk I.A. On temperature distribution in human head at given thermal fluxes on its surface. Journal of Thermoelectricity. 2015. No. 5: 89-95 [in Ukrainian].