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The effects of hypergravity and microgravity on biomedical experiments

Take one elephant and one man to the top of a tower and simultaneously drop. Which will hit the ground first? You are a pilot of a jet fighter performing a high-speed loop. Will you pass out during the maneuver? How can you simulate being an astronaut with your feet still firmly placed on planet Ear...

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Bibliographic Details
Main Author: Russomano, Thais.
Other Authors: Dalmarco, Gustavo., Falcão, Felipe Prehn.
Format: Electronic
Language:English
Published: San Rafael, Calif. (1537 Fourth St, San Rafael, CA 94901 USA) : Morgan & Claypool Publishers, c2008.
Series:Synthesis lectures on biomedical engineering, #18.
Subjects:
Gravity > Physiological effect.
Space biology.
Online Access:Abstract with links to resource
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020 # # |a 1598295799 (electronic bk.) 
020 # # |a 9781598295795 (electronic bk.) 
020 # # |a 1598295780 (pbk.) 
020 # # |a 9781598295788 (pbk.) 
024 7 # |a 10.2200/S00105ED1V01Y200801BME018  |2 doi 
035 # # |a (CaBNvSL)gtp00531391 
040 # # |a WAU  |c WAU  |d CaBNvSL 
050 # 4 |a QP82.2.G7  |b R874 2008 
082 0 4 |a 612/.014412  |2 22 
100 1 # |a Russomano, Thais. 
245 1 4 |a The effects of hypergravity and microgravity on biomedical experiments  |c Thais Russomano, Gustavo Dalmarco, and Felipe Prehn Falcão.  |h [electronic resource] / 
260 # # |a San Rafael, Calif. (1537 Fourth St, San Rafael, CA 94901 USA) :  |b Morgan & Claypool Publishers,  |c c2008. 
300 # # |a 1 electronic text (vi, 70 p. : col. ill.) :  |b digital file. 
490 1 # |a Synthesis lectures on biomedical engineering,  |v #18  |x 1930-0336 ; 
500 # # |a Part of: Synthesis digital library of engineering and computer science. 
500 # # |a Title from PDF t.p. (viewed on Nov. 5, 2008). 
500 # # |a Series from website. 
504 # # |a Includes bibliographic references (p. 65-68). 
505 0 # |a General concepts in physics : definition of physical terms -- Gravity and related concepts -- Weight versus mass and inertial mass -- Apparent weight and normal force -- The Einstein principle -- Microgravity -- Hypogravity -- Partial-gravity environments on earth hypergravity -- The effects of hypergravity on biomedical experiments -- Hypergravity and human physiology -- G impact in space missions -- Human centrifuges -- The microgravity centre hypergravity experiments -- Test models -- The effects of microgravity on biomedical experiments -- Ground-based microgravity simulation -- Collection of peripheral blood and isolation of mononuclear cells -- Cell proliferation/viability assay. 
506 # # |a Abstract freely available; full-text restricted to subscribers or individual document purchasers. 
510 0 # |a Compendex 
510 0 # |a INSPEC 
510 0 # |a Google scholar 
510 0 # |a Google book search 
520 # # |a Take one elephant and one man to the top of a tower and simultaneously drop. Which will hit the ground first? You are a pilot of a jet fighter performing a high-speed loop. Will you pass out during the maneuver? How can you simulate being an astronaut with your feet still firmly placed on planet Earth? In the aerospace environment, human, animal, and plant physiology differs significantly from that on Earth, and this book provides reasons for some of these changes. The challenges encountered by pilots in their missions can have implications on the health and safety of not only themselves but others. Knowing the effects of hypergravity on the human body during high-speed flight led to the development of human centrifuges. We also need to better understand the physiological responses of living organisms in space. It is therefore necessary to simulate weightlessness through the use of specially adapted equipment, such as clinostats, tilt tables, and body suspension devices. Each of these ideas, and more, is addressed in this review of the physical concepts related to space flights, microgravity, and hypergravity simulations. Basic theories, such as Newton's law and Einstein's principle are explained, followed by a look at the biomedical effects of experiments performed in space life sciences institutes, universities, and space agencies. 
530 # # |a Also available in print. 
538 # # |a Mode of access: World Wide Web. 
538 # # |a System requirements: Adobe Acrobat Reader. 
650 # 0 |a Gravity  |x Physiological effect. 
650 # 0 |a Space biology. 
690 # # |a Microgravity. 
690 # # |a Weightlessness. 
690 # # |a Hypergravity. 
690 # # |a Clinostats. 
690 # # |a Ground-based simulations. 
690 # # |a Space physiology. 
690 # # |a Centrifuge. 
700 1 # |a Dalmarco, Gustavo. 
700 1 # |a Falcão, Felipe Prehn. 
730 0 # |a Synthesis digital library of engineering and computer science. 
830 # 0 |a Synthesis lectures on biomedical engineering,  |v #18.  |x 1930-0336 ; 
856 4 2 |u https://ezaccess.library.uitm.edu.my/login?url=http://dx.doi.org/10.2200/S00105ED1V01Y200801BME018  |3 Abstract with links to resource 

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