Hibernation: Difference between revisions

"hibernate" redirects here. For the Java database library, see Hibernate (Java). For the power management process in computing, see hibernation (computing).

Northern Bat hibernating in Norway

Hibernation is a state of inactivity and metabolic depression in animals, characterized by lower body temperature, slower breathing, and/or lower metabolic rate. Hibernating animals conserve energy, especially during winter when food supplies are limited, tapping energy reserves, body fat, at a slow rate. Although traditionally reserved for "deep" hibernators such as rodents, the term has been redefined based on specialized metabolic reductions^[1] and many experts believe that the processes of daily torpor and hibernation form a continuum. Hibernation during summer months is known as aestivation. Some reptile species are said to brumate, or undergo brumation, but the connection to this phenomenon with hibernation is not clear.

Although often associated with cold temperatures, the root purpose of hibernation is to conserve food during a period when sufficient food is scarce. It is the animal's slowed metabolic rate which leads to a reduction in body temperature and not the other way around. Hibernation may last several days, weeks, or months depending on the species, ambient temperature, time of year, individual animal's body condition, and fur on the animal's body.

Before entering hibernation, most species eat a large amount of food and store energy in fat deposits to survive the winter. Some species of mammals hibernate while gestating young, which are either born while the mother hibernates or shortly afterwards.^{[citation needed]}

Hibernating mammals

Previously no primate or tropical mammal was known to hibernate. Animal physiologist Kathrin Dausmann of Philipps University of Marburg, Germany, and coworkers presented evidence that the Fat-tailed Dwarf Lemur of Madagascar hibernates in tree holes for seven months of the year.^{[citation needed]} This is interesting because Malagasy winter temperatures sometimes rise to over 30 °C (86 °F), so hibernation is not exclusively an adaptation to low ambient temperatures. The hibernation of this lemur is strongly dependent on the thermal behavior of its tree hole: if the hole is poorly insulated, the lemur's body temperature fluctuates widely, passively following the ambient temperature; if well insulated, the body temperature stays fairly constant and the animal undergoes regular spells of arousal.^{[citation needed]} Dausmann found that hypometabolism in hibernating animals is not necessarily coupled to a low body temperature.^{[citation needed]}

Obligate hibernators

Animals that are obligate hibernators include some species of ground squirrels and other rodents, mouse lemurs, the European Hedgehog and other insectivores, monotremes and marsupials. These undergo what has been traditionally called "hibernation": the physiological state where the body temperature drops to near ambient (environmental) temperature, heart and respiration rates slow drastically, and the animal appears to be in a deep sleep. The typical winter season for these hibernators is characterized by periods of hibernation interrupted by sporadic euthermic arousals, wherein body temperatures and heart rates are restored to more typical levels. These arousals are driven by internal mechanisms, and external stimuli often fail to wake them. This can make them subject to predation if discovered.

Hibernating ground squirrels may exhibit abdominal temperatures as low as 0 °C, maintaining sub-zero abdominal temperatures for more than three weeks at a time, although the temperatures at the head and neck remain at 0 ˚C or above.^[2]

There is a hypothesis that hibernators build a need for sleep during hibernation more slowly than normally, and must occasionally warm up in order to sleep. This has been supported by some evidence in the arctic ground squirrel.^[3]

Black bear mother and cubs "denning"

Facultative hibernation

Unlike obligate hibernators, facultative hibernators such as bats and bears can be aroused by external stimuli but unless so alarmed, they are able to sleep for the entire winter. They are therefore easily disturbed if their locations are discovered.

Bats otherwise undergo a state of hibernation similar to rodents in relation to body temperature and other traits, but bears have a different type of hibernation that some have not considered "true hibernation".^[4] During a bear's winter sleep state, the degree of metabolic depression is much less than that observed in smaller mammals and the bear's body temperature remains relatively stable (depressed from 37 °C (99 °F) to approximately 31 °C (88 °F)). Increasing the body temperature for such a large animal would take a long time. Many prefer to use the term "denning" or "winter lethargy" but others just consider it a different form of hibernation.^[5]

Hibernating birds

Historically, Pliny the Elder believed swallows hibernated, and ornithologist Gilbert White pointed to anecdotal evidence in The Natural History of Selborne that indicated as much. Birds typically do not hibernate, instead utilizing torpor. One known exception is the Common Poorwill (Phalaenoptilus nuttallii), first documented by Edmund Jaeger.^[6][7]

Hibernating fish

For a couple of generations^[vague] during the 20th century it was thought that basking sharks settled to the floor of the North Sea and hibernated. Research by Dr David Sims in 2003 dispelled this hypothesis,^[8] showing that the sharks actively traveled huge distances throughout the seasons, tracking the areas with the highest quantity of plankton. The epaulette sharks have been documented to be able to survive for long periods of time without oxygen, even being left high and dry, and at temperatures of up to 26 °C (79 °F).^[9] Other animals able to survive long periods without oxygen include the goldfish, the red-eared slider turtle, the wood frog, and the bar-headed goose.^[10]

Artificial hibernation

See also: Suspended animation

There are many research projects currently investigating how to achieve "induced hibernation" in humans.^[11] The ability for humans to hibernate would be useful for a number of reasons, such as saving the lives of seriously ill or injured people by temporarily putting them in a state of hibernation until treatment can be given (compare induced coma). In addition, hibernation would be useful for humans during various proposed plans for interstellar travel in the future. Similar to human hibernation, suspended animation deals with the slowing of life processes in general, by external means and without termination.

See also

• Sleep (non-human)
• Cryobiology

References

1. Watts PD, Oritsland NA, Jonkel C, Ronald K (1981). "Mammalian hibernation and the oxygen consumption of a denning black bear (Ursus americanus)". Comparative Biochemistry and Physiology Part A: Physiology. 69 (1): 121–3.
2. Barnes, Brian M. (30 June 1989). "Freeze Avoidance in a Mammal: Body Temperatures Below 0 °C in an Arctic Hibernator" (PDF). Science. 244 (4912). American Association for the Advancement of Science: –1616. doi:10.1126/science.2740905. PMID 2740905. Retrieved 2008-11-23.
3. Daan S, Barnes BM, Strijkstra AM (1991). "Warming up for sleep? Ground squirrels sleep during arousals from hibernation". Neurosci. Lett. 128 (2): 265–8. doi:10.1016/0304-3940(91)90276-Y. PMID 1945046.
4. Secrets of Hibernation; nova, pbs.org
5. Do Black Bears Hibernate? North American Bear Center North American Bear Center
6. Jaeger, Edmund C. (1949). "Further Observations on the Hibernation of the Poor-will". The Condor. 3. 51: 105–109. JSTOR 1365104. Earlier I gave an account (Condor, 50, 1948:45) of the behavior of a Poor-will (Phalaenoptilus nuttallinii) which I found in a state of profound torpidity in the winter of 1946-47 in the Chuckawalla Mountains of the Colorado Desert, California. {{cite journal}}: Unknown parameter |month= ignored (help)
7. McKechnie, Andrew W. "Torpor in an African caprimulgid, the freckled nightjar Caprimulgus tristigma" (PDF). Journal of Avian Biology. 38 (3): 261–266. doi:10.1111/j.2007.0908-8857.04116.x. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
8. "Seasonal movements and behavior of basking sharks from archival tagging". Marine Ecology Progress Series (248): 187–196. 2003.
9. "A Shark With an Amazing Party Trick". New Scientist. 177 (2385): 46. 8 March 2003. Retrieved 2006-10-06.
10. Breathless: A shark with an amazing party trick is teaching doctors how to protect the brains of stroke patients. Douglas Fox, New Scientist vol 177 issue 2385 - 8 March 2003, page 46. Last accessed November 9, 2006.
11. Hibernation

Further reading

• Carey, H.V., M.T. Andrews and S.L. Martin. 2003. Mammalian hibernation: cellular and molecular responses to depressed metabolism and low temperature. Physiological Reviews 83: 1153-1181.

External links

• Do Black Bears Hibernate?
• Hibernation on Demand
• Freeze avoidance in a Mammal: Body Temperatures Below 0°C in an Arctic Hibernator
• Can Humans Hibernate?