【 摘 要 】

Background

+Gz-time tolerance curves were developed to predict when exposure to +Gz stress exceeds human tolerance resulting in neurologic signs and symptoms. The +Gz-induced loss of consciousness (G-LOC) curves were developed to predict when +Gz stress induces G-LOC. The G-LOC curves are based on a theoretical understanding of how acceleration affects underlying physiological mechanisms affording tolerance to acceleration, their limits, and what happens when they are exceeded. The foundation of previous +Gz-time tolerance curves was based on a minimal dataset of sign and symptom endpoints.

Methods

Two G-LOC curves were established from the analysis of 888 centrifuge induced G-LOC episodes in completely healthy humans. The time from the onset of +Gz stress to the onset of unconsciousness was plotted as a function of +Gz level and the G onset rate.

Results

The two new G-LOC curves differed significantly from previous curves in temporal characteristics and key aspects underlying neurologic response to acceleration. The new acceleration onset rate curve reveals that for onset rates ≥ 1.0 G/s, G-LOC will occur in a mean time of 9.10 s and is independent of the onset rate. The new +Gz-level curve demonstrates that G-LOC will occur in a mean time of 9.65 s for rapid onset rate exposures to +Gz levels ≥ +7 Gz. The minimum +Gz-level threshold tolerance was defined as +4.7 Gz. When +Gz onset rates are gradual, ≤ 0.2 G/s, G-LOC occurs in a mean time of 74.41 s. G-LOC did not occur earlier than 5 s for any acceleration exposure.

Conclusions

These G-LOC curves alter previous temporal predictions for loss of consciousness and advance the understanding of basic neurophysiological function during exposure to the extremes of acceleration stress. Understanding the acceleration kinetics of the loss and recovery of consciousness provides the characteristics of uncomplicated and purely ischemic causes of LOC for application in medical diagnosis of syncope, epilepsy, and other clinical causes of transient loss of consciousness. The curves are applicable to education, training, medical evaluation, and aerospace operations.

【 授权许可】

   
2013 Whinnery and Forster; licensee BioMed Central Ltd.

【 预 览 】

附件列表

Files	Size	Format	View
20140708070007139.pdf	1284KB	PDF	download
Figure 5.	578KB	Image	download
Figure 4.	586KB	Image	download
Figure 3.	571KB	Image	download
Figure 2.	45KB	Image	download
Figure 1.	595KB	Image	download

【 图 表 】

【 参考文献 】

• [1]Burton RR, Whinnery JE: Operational G-induced loss of consciousness: something old; something new. Aviat Space Environ Med 1985, 56:812-817.
• [2]Burton RR, Leverett SD Jr, Michaelson ED: Man at high sustained +Gz acceleration: a review. Aviat Space Environ Med 1974, 45:1115-1136.
• [3]Burton RR: Conceptual model for predicting pilot group G tolerance for tactical fighter aircraft. Aviat Space Environ Med 1986, 57:733-744.
• [4]Burton RR, Smith AH: Adaptation to acceleration environments. [http://www.comprehensivephysiology.com/WileyCDA/CompPhysArticle/refId-cp040240.html webcite]
• [5]Burton RR: Mathematical models for predicting G level tolerances. Aviat Space Environ Med 2000, 71:506-513.
• [6]Burton RR: Mathematical models for predicting G duration tolerances. Aviat Space Environ Med 2000, 71:981-990.
• [7]Gauer O: The physiological effects of prolonged acceleration. In German Aviation Medicine, World War II. Chapter VI-B. Volume I. Washington, D.C: US Government Printing Office; 1950:578-579. [Department of the Air Force]
• [8]Gauer O, Henry JP: Physiology of Flight. In Air Force Manual 160–30. Washington, D.C: Government Printing Office; 1953:133-134. [Department of the Air Force]
• [9]Gauer O, Henry JP: Physiology of flight. In Air Force Pamphlet 160-10-4. Washington, D.C: Government Printing Office; 1961:136-137. [Department of the Air Force]
• [10]Gauer OH, Zuidema GD: The physiology of positive acceleration. In Gravitational Stress. Chapter 13. 1st edition. Edited by Gauer OH, Zuidema GD. Boston: Little, Brown and Company; 1961:115-133.
• [11]Burton RR: Panel on deliberate G-induced loss of consciousness: introduction. Aviat Space Environ Med 1991, 62:609-611.
• [12]Burton RR, Whinnery JE: Biodynamics: sustained acceleration. In Fundamentals of Aerospace Medicine. 3rd edition. Edited by DeHart RL, Davis JR. Philadelphia: Lippincott Williams and Wilkins; 2002:122-153.
• [13]Gillingham KK, Fosdick JP: High-G training for fighter aircrew. Aviat Space Environ Med 1988, 59:12-19.
• [14]Lyons TJ, Harding R, Freeman J, Oakley C: G-induced loss of consciousness accidents: USAF experience 1982–1990. Aviat Space Environ Med 1992, 63:60-66.
• [15]Lyons TJ, Kraft NO, Copley GB, Davenport C, Grayson K, Binder N: Analysis of mission and aircraft factors in G-induced loss of consciousness in the USAF: 1982–2002. Aviat Space Environ Med 2004, 75:479-489.
• [16]Lyons TJ, Davenport C, Copley GB, Binder H, Grayson K, Kraft NO: Preventing G-induced loss of consciousness: 20 years of operational experience. Aviat Space Environ Med 2004, 75:150-153.
• [17]Buchheim RW: Environment of manned systems. In Space Handbook: Astronautics and its Applications. Edited by Horgan NJ, Palmatier MA, Vogel J. New York: Random House; 1958:133-155.
• [18]Whinnery JE: Observations on the neurophysiologic theory of acceleration (+Gz) induced loss of consciousness. Aviat Space Environ Med 1989, 60:589-593.
• [19]Stoll AM: Human tolerance to positive G as determined by physiological endpoints. Aviat Med 1956, 27:356-367.
• [20]Moore TW, Jaron D, Hrebien L, Bender D: A mathematical model of G time-tolerance. Aviat Space Environ Med 1993, 64:947-951.
• [21]Banks RD, Brinkley JW, Allnutt R, Harding RM: Human response to acceleration. In Fundamentals of Aerospace Medicine. 4th edition. Edited by Davis JR, Johnson R, Stepanek J, Fogarty JA. Philadelphia: Lippincott Williams and Wilkins; 2008:83-109.
• [22]Whinnery JE, Whinnery AM: Acceleration-induced loss of consciousness. a review of 500 episodes. Arch Neurol 1990, 47:764-776.
• [23]Forster EM: A Database to Evaluate +Gz Acceleration-Induced Loss of Consciousness (GLOC) in the Human Centrifuge. Warminster, PA: Naval Air Warfare Center; 1993. Technical Report No. NAWCADWAR-93089-60
• [24]Cohen MM: Combining techniques to enhance protection against high sustained accelerative forces. Aviat Space Environ Med 1983, 54:338-342.
• [25]Kydd GH, Stoll AM: G tolerance in primates. J Aviat Med 1958, 29:413-421.
• [26]Martin EE, Henry J: The effects of time and temperature upon tolerance to positive acceleration. J Aviat Med 1951, 22:382-390.
• [27]Newman DG, Callister R: Cardiovascular training effects in fighter pilots induced by occupational high G exposure. Aviat Space Environ Med 2008, 79:774-778.
• [28]Hrebien L: Blood Flow Measurements Under High-G Conditions: Early Prediction of G Tolerance. Warminster, PA: Naval Air Development Center; 1983. Technical Report No. NADC-83115-60
• [29]Rossen R, Kabat H, Anderson JP: Acute arrest of cerebral circulation in man. Arch Neurol 1943, 50:510-528.
• [30]Forster EM, Whinnery JE: Statistical Analysis of the Human Strangulation Experiments: Comparison to +Gz-Induced Loss of Consciousness. Warminster, PA: Naval Air Warfare Center; 1992. Report No. NAWCADNWA-92026-60
• [31]Mitchell JR, Roach DE, Tyberg JV, Belenkie I, Sheldon RS: Mechanism of loss of consciousness during vascular neck compression. J Appl Physiol 2012, 112:396-402.
• [32]Sauvageau A, LaHarpe R, King D, Guay JP, Geberth VJ: Agonal sequences in 14 filmed hangings with comments on the role of type of suspension, ischemic habituation, and ethanol intoxication on the timing of agonal responses. Am J Forensic Medical Pathol 2011, 32:104-107.
• [33]Houghton JO, McBride DK, Hannah K: Performance and physiological effects of acceleration-induced (+Gz) loss of consciousness. Aviat Space Environ Med 1985, 56:956-965.
• [34]Cochran LB, Gard PW, Norsworthy ME: Variations in Human Tolerance to Positive Acceleration. Pensacola, Florida: US Naval School of Aviation Medicine; 1954. Research Report NM 001 059.02.10
• [35]Palena PV, Jaeger EA, Behrendt T, Duane TD: Quantitative effect of increased intraocular pressure on blackout. Arch Ophthal 1970, 83:84-88.