Синдром космической адаптации

Синдром космической адаптации
Синдром космической адаптации
	Астронавты НАСА акклиматизируются к синдрому космической адаптации в самолете KC-135, который летает параболическими дугами , чтобы создать короткие периоды невесомости. Примерно в двух третях пассажиров эти рейсы вызывают тошноту, давая плоскости прозвище "рвота комета".
Specialty	Space medicine
Prevalence	50% of individuals

Синдром космической адаптации ( SAS ) или космическая болезнь - это состояние, испытываемое половиной всех космических путешественников во время их адаптации к невесомости один раз на орбите. ^{[ 4 ]} Это противоположность наземной мучительной болезни , поскольку это происходит, когда окружающая среда и человек, кажется, визуально находятся в движении относительно друг друга, даже если нет соответствующих ощущений движения тела, происходящего из вестибулярной системы . ^{[ 5 ]}

Презентация

Космическая укачи может привести к ухудшению производительности астронавта. ^{[ 6 ]}^: 32 SMS угрожает эксплуатационным требованиям, снижает ситуационную осведомленность и угрожает безопасности тех, кто подвергается воздействию среды Micro-G. ^{[ 6 ]} Потерянная мышечная масса приводит к трудностям с движением, особенно когда астронавты возвращаются на Землю. Это может создать проблему безопасности, если возникнут необходимость в чрезвычайной ситуации. Потеря мышечной мощности делает очень трудным, если не невозможным, для астронавтов подниматься через аварийные выходные люки или создавать нетрадиционные выходные пространства в случае аварии после посадки. Кроме того, резорбция кости и неадекватная увлажнение в пространстве могут привести к образованию камней почек и последующему внезапному выводу из -за боли. ^[7] If this were to occur during critical phases of flight, a capsule crash leading to worker injury and/or death could result. Short-term and long-term health effects have been seen in the cardiovascular system from exposure to the micro-g environment that would limit those exposed after they return to Earth or a regular gravity environment. Steps need to be taken to ensure proper precautions are taken into consideration when dealing a micro-g environment for worker safety.^[8]^[9] Orthostatic intolerance can lead to temporary loss of consciousness due to the lack of pressure and stroke volume. This loss of consciousness inhibits and endangers those affected and can lead to deadly consequences.^[10]

Cause

Your body just isn't built to deal with zero-gravity. But there's no way of predicting how someone will handle it. Someone who gets car-sick all the time can be fine in space - or the opposite. I'm fine in cars and on rollercoasters, but space is a different matter.
— Steven Smith^[11]

When the vestibular system and the visual system report incongruous states of motion, the result is often nausea and other symptoms of disorientation known as motion sickness. According to contemporary sensory conflict theory, such conditions happen when the vestibular system and the visual system do not present a synchronized and unified representation of one's body and surroundings. This theory is also known as neural mismatch, implying a mismatch occurring between ongoing sensory experience and long-term memory rather than between components of the vestibular and visual systems, emphasizing "the limbic system in integration of sensory information and long-term memory, in the expression of the symptoms of motion sickness, and the impact of anti-motion-sickness drugs and stress hormones on limbic system function. The limbic system may be the neural mismatch center of the brain."^[12] At present a "fully adequate theory of motion sickness is not presently available" but at present the sensory conflict theory, referring to "a discontinuity between either visual, proprioceptive, and somatosensory input, or semicircular canal and otolith input", may be the best available.^[13] Space adaptation syndrome or space sickness is a kind of motion sickness that can occur when one's surroundings visually appear to be in motion, but without a corresponding sense of bodily motion. This incongruous condition can occur during space travel when changes in g-forces compromise one's spatial orientation.^[5] According to Science Daily, "Gravity plays a major role in our spatial orientation. Changes in gravitational forces, such as the transition to weightlessness during a space voyage, influence our spatial orientation and require adaptation by many of the physiological processes in which our balance system plays a part. As long as this adaptation is incomplete, this can be coupled to nausea, visual illusions, and disorientation."^[5] Sleep deprivation can also increase susceptibility to space sickness, making symptoms worse and longer-lasting.^[12]

According to the sensory conflict hypothesis, space sickness is the opposite of the kinds of motion-related disorientation that occur in the presence of gravity, known as terrestrial motion sickness, such as becoming carsick, seasick, or airsick. In such cases, and in contrast to space sickness, one's surroundings seem visually immobile (such as inside a car or airplane or a cabin below decks) while one's body feels itself to be in motion. Contemporary motion sickness medications can counter various forms of motion disorientation including space sickness by temporarily suppressing the vestibular system, but are rarely used for space travel because it is considered better to allow space travelers to adapt naturally over the first one to seven days rather than to suffer the drowsiness and other side effects of medication taken over a longer period. However, transdermal dimenhydrinate anti-nausea patches are typically used whenever space suits are worn because vomiting into a space suit could be fatal by obscuring vision or blocking airflow. Space suits are generally worn during launch and landing by NASA crew members and always for extra-vehicular activities (EVAs). EVAs are consequently not usually scheduled for the first days of a mission to allow the crew to adapt, and transdermal dimenhydrinate patches are typically used as an additional backup measure.

Management

Just as space sickness has the opposite cause compared to terrestrial motion sickness, the two conditions have opposite non-medicinal remedies. The idea of sensory conflict implies that the most direct remedy for motion sickness in general is to resolve the conflict by re-synchronizing what one sees and what one feels. For most (but not all) kinds of terrestrial motion sickness, that can be achieved by viewing one's surroundings from a window or (in the case of seasickness) going up on deck to observe the seas. For space sickness, relief is available via the opposite move of restricting one's vision to a small area such as a book or a small screen, disregarding the overall surroundings until the adaptation process is complete, or simply to close one's eyes until the nauseated feeling is reduced in intensity during the adjustment period. Some research indicates that blindness itself does not provide relief; "Motion sickness can occur during exposure to physical motion, visual motion, and virtual motion, and only those without a functioning vestibular system are fully immune.^[12]

As with sea sickness and car sickness, space motion sickness symptoms can vary from mild nausea and disorientation to vomiting and intense discomfort; headaches and nausea are often reported in varying degrees. The most extreme reaction yet recorded was that felt by Senator Jake Garn in 1985 on Space Shuttle flight STS-51-D. NASA later jokingly began using the informal "Garn scale" to measure reactions to space sickness. In most cases, symptoms last from 2–4 days. When asked about the origins of "Garn", Robert E. Stevenson said:^[14]

Jake Garn was sick, was pretty sick. I don't know whether we should tell stories like that. But anyway, Jake Garn, he has made a mark in the Astronaut Corps because he represents the maximum level of space sickness that anyone can ever attain, and so the mark of being totally sick and totally incompetent is one Garn. Most guys will get maybe to a tenth Garn if that high. And within the Astronaut Corps, he forever will be remembered by that.

Garn's purpose on the mission was in part to subject him to experiments on space motion sickness.^[15] Predicting whether someone will experience space sickness is not possible. Someone who suffers from car sickness may not suffer from space sickness, and vice versa.^[11] In excellent physical condition, Garn did not become sick on the vomit comet before STS-51-D.^[15] All three astronauts on Skylab 3 suffered from nausea, although the three on Skylab 2 had not; the illness affected their work during the first few days, worrying NASA doctors.^[16]

Experienced aviators and space travelers can suffer from space sickness. Garn began piloting at the age of 16^[15] and piloted a variety of military aircraft for 17,000 hours—more than any NASA astronaut—before STS-51-D. Charles D. Walker became ill on the same flight despite having flown on the shuttle before.^[17]^[18] While the Skylab 3 crew quickly recovered—whether by eating six smaller meals instead of three larger ones, or just by becoming used to space—one of the Skylab 4 crew became sick despite anti-nausea medication.^[16] Steven Smith estimated that on four shuttle flights he threw up 100 times.^[11]

Space sickness that occurs during space flight can also continue for days after landing, until the vestibular system has again adapted to gravity.^[19]

History

In August 1961, Soviet cosmonaut Gherman Titov became the first human to experience space sickness on Vostok 2; he was the first person to vomit in space.^[20]

Apart from that record, space motion sickness was effectively unknown during the earliest spaceflights (Mercury, Gemini series) probably because these missions were undertaken in spacecraft providing very cramped conditions and permitting very little room for head movements; space sickness seems to be aggravated by being able to freely move around, especially in regard to head movement, and so is more common in larger spacecraft.^[21]

References

^ "Mixed Up in Space". NASA. 2001-08-07. Archived from the original on 2009-05-13. Retrieved 2009-05-28.
^ Golightly, Glen (October 20, 1999). "Flying The Vomit Comet Has Its Ups And Downs". space.com. Archived from the original on 2006-03-10.
^ "Reduced Gravity: Vomit Comet Blog". PhysicsCentral. May 10, 2005. Retrieved 2007-11-07.
^ Quine, Tony (April 2007). "Addicted to space: An appreciation of Anousheh Ansari, Part II". Spaceflight. 49 (4): 144. ISSN 0038-6340.
^ Jump up to: ^a ^b ^c "Why Do Astronauts Suffer From Space Sickness?". ScienceDaily. 2008-05-23.
^ Jump up to: ^a ^b Thornton, William; Bonato, Frederick (2017-10-23). The Human Body and Weightlessness. Cham, Switzerland: Springer. doi:10.1007/978-3-319-32829-4. ISBN 978-3-319-32828-7. OCLC 1006502642.
^ Smith, Scott M.; Heer, Martina; Shackelford, Linda C.; Sibonga, Jean D.; Spatz, Jordan; Pietrzyk, Robert A.; Hudson, Edgar K.; Zwart, Sara R. (2015). "Bone metabolism and renal stone risk during International Space Station missions". Bone. 81: 712–720. doi:10.1016/j.bone.2015.10.002. PMID 26456109.
^ Gunga, Hanns-Christian; Ahlefeld, Victoria Weller von; Coriolano, Hans-Joachim Appell; Werner, Andreas; Hoffmann, Uwe (2016-07-14). Cardiovascular System, Red Blood Cells, and Oxygen Transport in Microgravity. Cham, Switzerland: Springer. Bibcode:2016csrb.book.....G. doi:10.1007/978-3-319-33226-0. ISBN 978-3-319-33226-0. OCLC 953694996.
^ Fritsch-Yelle, Janice M.; Leuenberger, Urs A.; D'Aunno, Dominick S.; Rossum, Alfred C.; Brown, Troy E.; Wood, Margie L.; Josephson, Mark E.; Goldberger, Ary L. (1998). "An Episode of Ventricular Tachycardia During Long-Duration Spaceflight". The American Journal of Cardiology. 81 (11): 1391–1392. doi:10.1016/s0002-9149(98)00179-9. PMID 9631987.
^ Clément, Gilles (2011). Fundamentals of space medicine (2nd ed.). El Segundo, Calif.: Published jointly by Microcosm Press. ISBN 9781441999054. OCLC 768427940.
^ Jump up to: ^a ^b ^c Leadbeater, Chris (2020-06-10). "The next astronaut on the moon will be a woman". The Telegraph. Retrieved 2020-06-17.
^ Jump up to: ^a ^b ^c Lackner, J. R. (2014). "Motion sickness: More than nausea and vomiting". Experimental Brain Research. 232 (8): 2493–2510. doi:10.1007/s00221-014-4008-8. PMC 4112051. PMID 24961738.
^ Kohl, R. L. (1983). "Sensory conflict theory of space motion sickness: An anatomical location for the neuroconflict". Aviation, Space, and Environmental Medicine. 54 (5): 464–5. PMID 6870740.
^ "Interview with Dr. Robert Stevenson" (PDF). Johnson Space Center Oral History Project. May 13, 1999. p. 35. Archived from the original (PDF) on 2008-03-08. Retrieved 2022-07-13.
^ Jump up to: ^a ^b ^c Lamar, Jacob V. Jr.; Hannifan, Jerry (April 22, 1985). "Jake Skywalker: A Senator boards the shuttle". Time. Archived from the original on 2010-10-29. Retrieved April 13, 2011.
^ Jump up to: ^a ^b Elder, Donald C. (1998). "The Human Touch: The History of the Skylab Program". In Mack, Pamela E. (ed.). From Engineering Science to Big Science: The NACA and NASA Collier Trophy Research Project Winners. The NASA History Series. NASA. SP-4219.
^ Болден, Чарльз Ф. (6 января 2004 г.). «Чарльз Ф. Болден» . НАСА Джонсон Космический Центр Периоральный Проект История (интервью). Интервью Джонсону, Сандра; Райт, Ребекка; Росс-Наззал, Дженнифер. Хьюстон, Техас . Получено 2020-06-19 .
^ Уокер, Чарльз Д. (14 апреля 2005 г.). «Стенограмма устной истории» . НАСА Джонсон Космический Центр Периоральный Проект История (интервью). Интервью Джонсону, Сандра.
^ Kornilova, L. N.; Naumov, I. A.; Glukhikh, D. O.; Ekimovskiy, G. A.; Pavlova, A. S.; Khabarova, V. V.; Smirnov, Yu. I.; Yarmanova, E. N. (2017). "Vestibular function and space motion sickness". Human Physiology . 43 (5): 557–568. doi : 10.1134/S0362119717050085 . S2CID 39254942 .
^ Glenday, Craig, ed. (2012). Guinness World Records 2013 . Guinness World Records. п. 27 ISBN 9781904994879 .
^ Kozlovskaya, Inessa B.; и др. (2004). «Влияние длительного космического полета на глазу, головку и координацию туловища во время передвижения» . НАСА Джонсон Космический центр. Архивировано с оригинала 2012-02-07 . Получено 2008-02-07 .

У Scholia есть профиль для космического движения (Q1365937) .

[Science@NASA-1] "Mixed Up in Space". NASA. 2001-08-07. Archived from the original on 2009-05-13. Retrieved 2009-05-28.

[SpaceInterviewYaniec-2] Golightly, Glen (October 20, 1999). "Flying The Vomit Comet Has Its Ups And Downs". space.com. Archived from the original on 2006-03-10.

[PhysicsCentral-3] "Reduced Gravity: Vomit Comet Blog". PhysicsCentral. May 10, 2005. Retrieved 2007-11-07.

[sp-4] Quine, Tony (April 2007). "Addicted to space: An appreciation of Anousheh Ansari, Part II". Spaceflight. 49 (4): 144. ISSN 0038-6340.

[sciencedaily-5] Jump up to: ^a ^b ^c "Why Do Astronauts Suffer From Space Sickness?". ScienceDaily. 2008-05-23.

[thornton2017-6] Jump up to: ^a ^b Thornton, William; Bonato, Frederick (2017-10-23). The Human Body and Weightlessness. Cham, Switzerland: Springer. doi:10.1007/978-3-319-32829-4. ISBN 978-3-319-32828-7. OCLC 1006502642.

[:33-7] Smith, Scott M.; Heer, Martina; Shackelford, Linda C.; Sibonga, Jean D.; Spatz, Jordan; Pietrzyk, Robert A.; Hudson, Edgar K.; Zwart, Sara R. (2015). "Bone metabolism and renal stone risk during International Space Station missions". Bone. 81: 712–720. doi:10.1016/j.bone.2015.10.002. PMID 26456109.

[8] Gunga, Hanns-Christian; Ahlefeld, Victoria Weller von; Coriolano, Hans-Joachim Appell; Werner, Andreas; Hoffmann, Uwe (2016-07-14). Cardiovascular System, Red Blood Cells, and Oxygen Transport in Microgravity. Cham, Switzerland: Springer. Bibcode:2016csrb.book.....G. doi:10.1007/978-3-319-33226-0. ISBN 978-3-319-33226-0. OCLC 953694996.

[:1-9] Fritsch-Yelle, Janice M.; Leuenberger, Urs A.; D'Aunno, Dominick S.; Rossum, Alfred C.; Brown, Troy E.; Wood, Margie L.; Josephson, Mark E.; Goldberger, Ary L. (1998). "An Episode of Ventricular Tachycardia During Long-Duration Spaceflight". The American Journal of Cardiology. 81 (11): 1391–1392. doi:10.1016/s0002-9149(98)00179-9. PMID 9631987.

[:2-10] Clément, Gilles (2011). Fundamentals of space medicine (2nd ed.). El Segundo, Calif.: Published jointly by Microcosm Press. ISBN 9781441999054. OCLC 768427940.

[leadbeater20200610-11] Jump up to: ^a ^b ^c Leadbeater, Chris (2020-06-10). "The next astronaut on the moon will be a woman". The Telegraph. Retrieved 2020-06-17.

[auto-12] Jump up to: ^a ^b ^c Lackner, J. R. (2014). "Motion sickness: More than nausea and vomiting". Experimental Brain Research. 232 (8): 2493–2510. doi:10.1007/s00221-014-4008-8. PMC 4112051. PMID 24961738.

[13] Kohl, R. L. (1983). "Sensory conflict theory of space motion sickness: An anatomical location for the neuroconflict". Aviation, Space, and Environmental Medicine. 54 (5): 464–5. PMID 6870740.

[14] "Interview with Dr. Robert Stevenson" (PDF). Johnson Space Center Oral History Project. May 13, 1999. p. 35. Archived from the original (PDF) on 2008-03-08. Retrieved 2022-07-13.

[time19850422-15] Jump up to: ^a ^b ^c Lamar, Jacob V. Jr.; Hannifan, Jerry (April 22, 1985). "Jake Skywalker: A Senator boards the shuttle". Time. Archived from the original on 2010-10-29. Retrieved April 13, 2011.

[elder-16] Jump up to: ^a ^b Elder, Donald C. (1998). "The Human Touch: The History of the Skylab Program". In Mack, Pamela E. (ed.). From Engineering Science to Big Science: The NACA and NASA Collier Trophy Research Project Winners. The NASA History Series. NASA. SP-4219.

[bolden20040106-17] Болден, Чарльз Ф. (6 января 2004 г.). «Чарльз Ф. Болден» . НАСА Джонсон Космический Центр Периоральный Проект История (интервью). Интервью Джонсону, Сандра; Райт, Ребекка; Росс-Наззал, Дженнифер. Хьюстон, Техас . Получено 2020-06-19 .

[walker20050414-18] Уокер, Чарльз Д. (14 апреля 2005 г.). «Стенограмма устной истории» . НАСА Джонсон Космический Центр Периоральный Проект История (интервью). Интервью Джонсону, Сандра.

[19] Kornilova, L. N.; Naumov, I. A.; Glukhikh, D. O.; Ekimovskiy, G. A.; Pavlova, A. S.; Khabarova, V. V.; Smirnov, Yu. I.; Yarmanova, E. N. (2017). "Vestibular function and space motion sickness". Human Physiology . 43 (5): 557–568. doi : 10.1134/S0362119717050085 . S2CID 39254942 .

[Guinness2012-20] Glenday, Craig, ed. (2012). Guinness World Records 2013 . Guinness World Records. п. 27 ISBN 9781904994879 .

[21] Kozlovskaya, Inessa B.; и др. (2004). «Влияние длительного космического полета на глазу, головку и координацию туловища во время передвижения» . НАСА Джонсон Космический центр. Архивировано с оригинала 2012-02-07 . Получено 2008-02-07 .

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v Т и Указывающая болезнь
Types	Airsickness Seasickness Simulator sickness Ski sickness Space adaptation syndrome Virtual reality sickness
Medicine treatment	Bonine Cinnarizine Dramamine Marezine Promethazine Transdermscop
Related	Bárány chair Sickness bag

v Т и Космическая медицина
Main areas	Artificial gravity Astronautical hygiene Bioastronautics Neuroscience in space Space exposure Space food Space nursing Space weather Weightlessness
Illness and injuries	Asthenization Ebullism Illness and injuries during spaceflight Medical treatment during spaceflight Space adaptation syndrome Space and survival Spaceflight osteopenia
Organizations	Aerospace Medical Association National Space Biomedical Research Institute Rubicon Foundation Space Nursing Society
Other topics	Adverse health effects from lunar dust exposure Cardiac rhythm problems during space flight Central nervous system effects from radiation exposure during spaceflight Effect of spaceflight on the human body Effects of sleep deprivation in space Epidemiology data for low-linear energy transfer radiation Sleep in space Health threat from cosmic rays Intervertebral disc damage and spaceflight List of microorganisms tested in outer space Psychological and sociological effects of spaceflight Radiobiology evidence for protons and HZE nuclei Reduced muscle mass, strength and performance in space Renal stone formation in space Spaceflight radiation carcinogenesis Team composition and cohesion in spaceflight missions Visual impairment due to intracranial pressure

Презентация

Cause

Management

History

See also

References