Cold shock response
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Cold shock response is a series of cardio-respiratory responses caused by sudden immersion in cold water.
In cold water immersions, cold shock response is perhaps the most common cause of death,[1] such as by falling through thin ice. The immediate shock of the cold causes involuntary inhalation, which, if underwater, can result in drowning. The cold water can also cause heart attack due to vasoconstriction;[2] the heart has to work harder to pump the same volume of blood throughout the body. For people with existing cardiovascular disease, the additional workload can result in cardiac arrest. Inhalation of water (and thus drowning) may result from hyperventilation. Some people are much better able to survive swimming in very cold water due to body or mental conditioning.[1]
Hypothermia from exposure to cold water is not as sudden as is often believed. A person who survives the initial minute of trauma (after falling into icy water), can survive for at least thirty minutes provided they don't drown. However, the ability to perform useful work (for example to save oneself) declines substantially after ten minutes (as the body protectively cuts off blood flow to "non-essential" muscles).[1][2]
Physiological response
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The physiological response results in temporary breathlessness and vasoconstriction.
Conditioning against cold shock
It is possible to undergo physiological conditioning to reduce the cold shock response, and some people are naturally better suited to swimming in very cold water. Adaptations include the following:
- having an insulating layer of body fat covering the limbs and torso without being overweight;[1]
- ability to experience immersion without involuntary physical shock or mental panic;[1]
- ability to resist shivering;[1]
- ability to raise metabolism (and, in some cases, increase blood temperature slightly above the normal level);[citation needed]
- a generalized delaying of metabolic shutdown (including slipping into unconsciousness) as central and peripheral body temperatures fall.[citation needed]
In these ways, winter swimmers can survive both the initial shock and prolonged exposure. Nevertheless, the human organism is not suited to freezing water: the struggle to maintain blood temperature (by swimming or conditioned metabolic response) produces great fatigue after thirty minutes or less.[3]
Conditioning against the cold shock response is an effective and cost efficient way to prevent drowning.[4] Those who benefit the most from the habituation of a cold shock response are athletes, soldiers and those who are at risk of cold water immersion.[4]
Cold shock response in bacteria
Bacteria express a well-defined set of proteins after a rapid decrease in temperature, which differs from those expressed under heat shock conditions. Cold shock proteins may include helicases, nucleases, and ribosome-associated components that interact with DNA and RNA. Processes such as cold signal perception, membrane adaptation, and the modification of the translation apparatus are involved.[5]
Cold shock response in humans
In humans, the temperature to initiate a cold shock response begins at <15 °C (59 °F).[6] Within the first three minutes of cold water immersion, the skin begins to cool.[6] Within thirty minutes, the human body begins to experience neuromuscular cooling, and then, after thirty minutes, the human body experiences hypothermia.[6]
Benefits of cold shock
Cold water immersion tactics are often employed by athletes to reduce the chance of heat illness and is employed to speed up muscle recovery and reduce soreness.[6]
See also
- Diving reflex – The physiological responses to immersion of air-breathing vertebrates
- Hypothermia – Human body core temperature below 35 °C (95 °F)
References
- ^ a b c d e f "Exercise in the Cold: Part II - A physiological trip through cold water exposure". The science of sport. www.sportsscientists.com. 29 January 2008. Retrieved 2010-04-23.
- ^ a b Staff. "4 Phases of Cold Water Immersion". Beyond Cold Water Bootcamp. Canadian Safe Boating Council. Archived from the original on 3 December 2013. Retrieved 8 November 2013.
- ^ Janský, L.; Janáková, H.; Ulicný, B.; Srámek, P.; Hosek, V.; Heller, J.; Parízková, J. (1996). "Changes in thermal homeostasis in humans due to repeated cold water immersions". Pflügers Archiv : European Journal of Physiology. 432 (3): 368–372. doi:10.1007/s004240050146. PMID 8765994.
- ^ a b Eglin, Clare M; Butt, George; Howden, Stephen; Nash, Thomas; Costello, Joseph (14 September 2015). "Rapid habituation of the cold shock response". Extreme Physiology & Medicine. 4 (S1): A38, 2046–7648–4-S1-A38. doi:10.1186/2046-7648-4-S1-A38. ISSN 2046-7648.
- ^ Weber, M. H.; Marahiel, M. A. (2003). "Bacterial cold shock responses". Science Progress. 86 (1–2): 9–75. doi:10.3184/003685003783238707. PMID 12838604.
- ^ a b c d Tipton, M. J.; Collier, N.; Massey, H.; Corbett, J.; Harper, M. (2017-11-01). "Cold water immersion: kill or cure?: Cold water immersion: kill or cure?". Experimental Physiology. 102 (11): 1335–1355. doi:10.1113/EP086283. PMID 28833689.
Sources
- Introduction to Frozen Mythbusters and Myth #1. Wilderness Medicine Newsletter. Sourced 2008-05-17.