Cardiovascular and fluid volume control in humans in space.

Department of Biomedical Sciences

Cardiovascular and fluid volume control in humans in space.

Research output: Contribution to journal › Journal article › Research › peer-review

Standard

Cardiovascular and fluid volume control in humans in space. / Norsk, Peter.

In: Current Pharmaceutical Biotechnology, Vol. 6, No. 4, 2005, p. 325-30.

Research output: Contribution to journal › Journal article › Research › peer-review

Harvard

Norsk, P 2005, 'Cardiovascular and fluid volume control in humans in space.', Current Pharmaceutical Biotechnology, vol. 6, no. 4, pp. 325-30.

APA

Norsk, P. (2005). Cardiovascular and fluid volume control in humans in space. Current Pharmaceutical Biotechnology, 6(4), 325-30.

Vancouver

Norsk P. Cardiovascular and fluid volume control in humans in space. Current Pharmaceutical Biotechnology. 2005;6(4):325-30.

Author

Norsk, Peter. / Cardiovascular and fluid volume control in humans in space. In: Current Pharmaceutical Biotechnology. 2005 ; Vol. 6, No. 4. pp. 325-30.

Bibtex

@article{65485c10acd711ddb538000ea68e967b,

title = "Cardiovascular and fluid volume control in humans in space.",

abstract = "The human cardiovascular system and regulation of fluid volume are heavily influenced by gravity. When decreasing the effects of gravity in humans such as by anti-orthostatic posture changes or immersion into water, venous return is increased by some 25%. This leads to central blood volume expansion, which is accompanied by an increase in renal excretion rates of water and sodium. The mechanisms for the changes in renal excretory rates include a complex interaction of cardiovascular reflexes, neuroendocrine variables, and physical factors. Weightlessness is unique to obtain more information on this complex interaction, because it is the only way to completely abolish the effects of gravity over longer periods. Results from space have been unexpected, because astronauts exhibit a fluid and sodium retaining state with activation of the sympathetic nervous system, which subjects during simulations by head-down bed rest do not. Therefore, the concept as to how weightlessness affects the cardiovascular system and modulates regulation of body fluids should be revised and new simulation models developed. Knowledge as to how gravity and weightlessness modulate integrated fluid volume control is of importance for understanding pathophysiology of heart failure, where gravity plays a strong role in fluid and sodium retention.",

author = "Peter Norsk",

note = "Keywords: Blood Volume; Body Fluids; Gravitation; Heart; Heart Failure; Humans; Kidney; Space Flight; Water-Electrolyte Balance; Weightlessness",

year = "2005",

language = "English",

volume = "6",

pages = "325--30",

journal = "Current Pharmaceutical Biotechnology",

issn = "1389-2010",

publisher = "Bentham Science Publishers",

number = "4",

}

RIS

TY - JOUR

T1 - Cardiovascular and fluid volume control in humans in space.

AU - Norsk, Peter

N1 - Keywords: Blood Volume; Body Fluids; Gravitation; Heart; Heart Failure; Humans; Kidney; Space Flight; Water-Electrolyte Balance; Weightlessness

PY - 2005

Y1 - 2005

N2 - The human cardiovascular system and regulation of fluid volume are heavily influenced by gravity. When decreasing the effects of gravity in humans such as by anti-orthostatic posture changes or immersion into water, venous return is increased by some 25%. This leads to central blood volume expansion, which is accompanied by an increase in renal excretion rates of water and sodium. The mechanisms for the changes in renal excretory rates include a complex interaction of cardiovascular reflexes, neuroendocrine variables, and physical factors. Weightlessness is unique to obtain more information on this complex interaction, because it is the only way to completely abolish the effects of gravity over longer periods. Results from space have been unexpected, because astronauts exhibit a fluid and sodium retaining state with activation of the sympathetic nervous system, which subjects during simulations by head-down bed rest do not. Therefore, the concept as to how weightlessness affects the cardiovascular system and modulates regulation of body fluids should be revised and new simulation models developed. Knowledge as to how gravity and weightlessness modulate integrated fluid volume control is of importance for understanding pathophysiology of heart failure, where gravity plays a strong role in fluid and sodium retention.

AB - The human cardiovascular system and regulation of fluid volume are heavily influenced by gravity. When decreasing the effects of gravity in humans such as by anti-orthostatic posture changes or immersion into water, venous return is increased by some 25%. This leads to central blood volume expansion, which is accompanied by an increase in renal excretion rates of water and sodium. The mechanisms for the changes in renal excretory rates include a complex interaction of cardiovascular reflexes, neuroendocrine variables, and physical factors. Weightlessness is unique to obtain more information on this complex interaction, because it is the only way to completely abolish the effects of gravity over longer periods. Results from space have been unexpected, because astronauts exhibit a fluid and sodium retaining state with activation of the sympathetic nervous system, which subjects during simulations by head-down bed rest do not. Therefore, the concept as to how weightlessness affects the cardiovascular system and modulates regulation of body fluids should be revised and new simulation models developed. Knowledge as to how gravity and weightlessness modulate integrated fluid volume control is of importance for understanding pathophysiology of heart failure, where gravity plays a strong role in fluid and sodium retention.

M3 - Journal article

C2 - 16101471

VL - 6

SP - 325

EP - 330

JO - Current Pharmaceutical Biotechnology

JF - Current Pharmaceutical Biotechnology

SN - 1389-2010

IS - 4

ER -

ID: 8466278