Your search keyword '"Long-duration space flight"' showing total 7 results

1. On-Orbit Mission Assisting and Supporting System Based on AR

Author

Zhu, Xiuqing, Liu, Yuqing, Zhou, Bohe, Long, Shengzhao, editor, and Dhillon, Balbir S., editor

Published

2015

2. Ground reaction force values in cosmonauts during locomotor exercises on board the International Space Station.

Author

Fomina, E., Savinkina, A., and Yarmanova, E.

Subjects

*ASTRONAUTS, *WEIGHTLESSNESS, *REGRESSION analysis, *MANN Whitney U Test, *GROUND reaction forces (Biomechanics), *PHYSIOLOGY

Abstract

Optimal methods for the prevention of negative impact of weightlessness have been developed based on the concept of Kozlovskaya, which states that support afferentation plays a trigger role in the development of the hypogravity motor syndrome. In this study, the maximal vertical ground reaction force (GRF) values were analyzed when locomotor training was performed on a BD-2 treadmill in long-term spaceflights. The study involved 12 cosmonauts. Recorded segments of the locomotor training (4554) performed in active (motor-driven) and passive (non-motor-driven) modes of BD-2 belt motion were analyzed. The data were analyzed by the methods of correlation and regression analysis and the nonparametric Mann-Whitney test. It was found that when running, regardless of the treadmill modes, an increase in the axial load by 1 kg was associated with a more than 1-kg increase in GRF; during walking an increase in GRF was less than 1 kg. As the speed increased, the GRF values increased most quickly when running in a passive mode and most slowly when walking in a passive mode. The GRF values in different BD-2 modes depended on both individual parameters of cosmonauts and locomotion types (walking or running). Our data can be the basis for the individualization of locomotor training onboard the ISS. [ABSTRACT FROM AUTHOR]

Published

2017

3. Model of medical supply and astronaut health for long-duration human space flight.

Author

Assad, Albert and de Weck, Olivier L.

Subjects

*MEDICAL supplies, *SPACE flight, *ASTRONAUTS, *DATA analysis, *RADIATION, *SPACE exploration, *MEDICAL care

Abstract

Planning a safe and productive human space exploration mission involves a dual approach addressing both the health of the vehicle and the crew. The goal of this study was to develop a quantitative model of astronaut health during long-duration space flight and a medical supply demand model in support of such missions. The model provides two outputs, Alpha h and Mass of Medical Consumables ( MMC ), for each set of input parameters. Alpha h is an estimate of total crew health and is displayed as a percentage. MMC is a measure of medical consumables expended during the mission and is displayed in units of kilograms. We have demonstrated that Alpha h is a function of three scaling parameters, the type of mission, duration of mission, and gender mix of the crew. The type of mission and gender of crew are linked to radiation fatality data published by NASA. Mission duration is incorporated into the model with predicted incidence of illness and injury data published on US Navy submarine crews. MMC increases non-linearly with the number of crew, the duration of the mission and the distance of the mission away from Earth. This article describes the relationships between these parameters and discusses implications for future crewed space missions. [ABSTRACT FROM AUTHOR]

Published

2015

4. The large radius human centrifuge 'A human hypergravity habitat, H 3

Author

Loon, J. J. W. A., Wuyts, F., Bäcker, N., Berte, J., Bok, K., Bos, J., Groen, E., Boyle, R., Bravenoer, N., Elisabeth Eekhoff, Chouker, A., Clement, G., Cras, P., Denise, P., Felsenberg, D., Fong, K., Fuller, C., Heer, M., Hinghofer-Szalkay, H., Iwase, S., Karemaker, J. M., Linnarsson, D., Lüthen, C., Mulder, E., Narici, M., Norsk, P., Paloski, W., Rutten, M., Saggini, R., Stephan, A., Ullrich, O., Vautmans, L., Young, L., and TNO Defensie en Veiligheid

Subjects

Space flight, Long duration, Topical team, Long-duration space flight, Cardio-vascular disease, Gravitational environments, Ageing population, Centrifugation, Hypergravity, Human bodies, Organ systems, Ground based, Medical issues, SDG 3 - Good Health and Well-being, Body of knowledge, Health, Gravity conditions, Earth (planet), Long term, Orbital space, Centrifuges, NASA, Gravitation

Abstract

Over the last decades a significant body of knowledge has been gained on the adaptation of the human body going into near weightlessness conditions as well as for the re-adaptation to 1xg Earth conditions after an orbital space flight. Ground-based paradigms for microgravity simulation have been developed such as head down tilted bed rest or dry-immersion studies. In such systems adaptations of the human body to long term immobilization and increased upper-body fluid shifts bed have been studied. But could we learn something on human body adaptations to altered gravity conditions using centrifuges? How does the body adapt to a long duration (days, weeks or longer) exposure to a hypergravity environment? And, once the body has fully adapted to a hypergravity environment, how does it re-adapt going from a hypergravity condition to a relatively hypo-gravity condition of 1xg, or even going from centrifuge / hypergravity environment into a bed-rest setting? Can such transitions learn us something about the gravity transitions as a crew will experience going to Moon or Mars. Is hypergravity therefore a good model to study the effect of re-entry in gravitational environments after long duration space flight? We established a Topical Team sponsored by ESA ans supported by NASA and JAXA in which we address the issues as mentioned above. We like to address the questions for all organ systems known to change under altered gravity conditions. We will identify to which gravity levels the human body can be exposed to for longer periods of time and what protocols could be applied to address the questions at hand. We also need to identify if and how we could perform such long duration hypergravity and re-adaptation studies. Issues like ethics, safety and required technology are addressed. The final outcome of the ESA Topical Team will be a clear answer about the feasibility of long duration hypergravity, and if and how hypergravity studies can provide useful knowledge to support future space flight on the one hand and the medical issues in e.g. the ageing population with its contemporary lifestyle on the other hand (osteoporosis, cardiovascular diseases, obesity).

Published

2009

5. The large radius human centrifuge 'A human hypergravity habitat, H 3

Author

Loon, Jack J. W. A., Floris Wuyts, Natali Bäcker, Johan Berte, Krijn Bok, Jelte Bos, Eric Groen, Boyle, R., Nathalie Bravenoer, Marelise Eekhoff, Alexander Chouker, Gilles Clement, Patrick Cras, Pierre Denise, Dieter Felsenberg, Kevin Fong, Charles Fuller, Martina Heer, Hartmut Hinghofer-Szalkay, Iwase, S., Karemaker, John M., Dag Linnarsson, Christian Lüthen, Edwin Mulder, Narici, Marco V., Peter Norsk, William Paloski, Marcel Rutten, Raoul Saggini, Arndt Stephan, Oliver Ullrich, Luc Vautmans, Larry Young, Sensorimotor Control, IBBA, Research Institute MOVE, Oral and Maxillofacial Surgery / Oral Pathology, AMS - Ageing & Vitality, AMS - Musculoskeletal Health, and Internal medicine

Subjects

Space flight, Long duration, Topical team, Long-duration space flight, Cardio-vascular disease, Gravitational environments, Ageing population, Body of knowledge, Gravity conditions, Ground based, Human bodies, Hypergravity, Long term, Medical issues, Orbital space, Organ systems, Topical team, Centrifugation, Centrifuges, Earth (planet), NASA, Space flight, Gravitation, Centrifugation, SDG 3 - Good Health and Well-being, Gravitation

Abstract

Over the last decades a significant body of knowledge has been gained on the adaptation of the human body going into near weightlessness conditions as well as for the re-adaptation to 1xg Earth conditions after an orbital space flight. Ground-based paradigms for microgravity simulation have been developed such as head down tilted bed rest or dry-immersion studies. In such systems adaptations of the human body to long term immobilization and increased upper-body fluid shifts bed have been studied. But could we learn something on human body adaptations to altered gravity conditions using centrifuges? How does the body adapt to a long duration (days, weeks or longer) exposure to a hypergravity environment? And, once the body has fully adapted to a hypergravity environment, how does it re-adapt going from a hypergravity condition to a relatively hypo-gravity condition of 1xg, or even going from centrifuge / hypergravity environment into a bed-rest setting? Can such transitions learn us something about the gravity transitions as a crew will experience going to Moon or Mars. Is hypergravity therefore a good model to study the effect of re-entry in gravitational environments after long duration space flight? We established a Topical Team sponsored by ESA ans supported by NASA and JAXA in which we address the issues as mentioned above. We like to address the questions for all organ systems known to change under altered gravity conditions. We will identify to which gravity levels the human body can be exposed to for longer periods of time and what protocols could be applied to address the questions at hand. We also need to identify if and how we could perform such long duration hypergravity and re-adaptation studies. Issues like ethics, safety and required technology are addressed. The final outcome of the ESA Topical Team will be a clear answer about the feasibility of long duration hypergravity, and if and how hypergravity studies can provide useful knowledge to support future space flight on the one hand and the medical issues in e.g. the ageing population with its contemporary lifestyle on the other hand (osteoporosis, cardiovascular diseases, obesity).

Published

2009

6. The large radius human centrifuge 'A human hypergravity habitat, H 3

Subjects

Space flight, Long duration, Topical team, Long-duration space flight, Cardio-vascular disease, Gravitational environments, Ageing population, Centrifugation, Hypergravity, Human bodies, Organ systems, Ground based, Medical issues, Body of knowledge, Health, Gravity conditions, Earth (planet), Long term, Orbital space, Centrifuges, NASA, Gravitation

Abstract

Over the last decades a significant body of knowledge has been gained on the adaptation of the human body going into near weightlessness conditions as well as for the re-adaptation to 1xg Earth conditions after an orbital space flight. Ground-based paradigms for microgravity simulation have been developed such as head down tilted bed rest or dry-immersion studies. In such systems adaptations of the human body to long term immobilization and increased upper-body fluid shifts bed have been studied. But could we learn something on human body adaptations to altered gravity conditions using centrifuges? How does the body adapt to a long duration (days, weeks or longer) exposure to a hypergravity environment? And, once the body has fully adapted to a hypergravity environment, how does it re-adapt going from a hypergravity condition to a relatively hypo-gravity condition of 1xg, or even going from centrifuge / hypergravity environment into a bed-rest setting? Can such transitions learn us something about the gravity transitions as a crew will experience going to Moon or Mars. Is hypergravity therefore a good model to study the effect of re-entry in gravitational environments after long duration space flight? We established a Topical Team sponsored by ESA ans supported by NASA and JAXA in which we address the issues as mentioned above. We like to address the questions for all organ systems known to change under altered gravity conditions. We will identify to which gravity levels the human body can be exposed to for longer periods of time and what protocols could be applied to address the questions at hand. We also need to identify if and how we could perform such long duration hypergravity and re-adaptation studies. Issues like ethics, safety and required technology are addressed. The final outcome of the ESA Topical Team will be a clear answer about the feasibility of long duration hypergravity, and if and how hypergravity studies can provide useful knowledge to support future space flight on the one hand and the medical issues in e.g. the ageing population with its contemporary lifestyle on the other hand (osteoporosis, cardiovascular diseases, obesity).

Published

2009

7. Experiments during aircraft parabolic flights to prepare for the international space station

Author

UCL - SST/ICTM/INMA - Pôle en ingénierie mathématique, UCL - SSS/IONS/COSY - Systems & cognitive Neuroscience, UCL - (SLuc) Service de médecine physique et de réadaptation motrice, Pletser, Vladimir, Sundblad, Patrik, Thonnard, Jean-Louis, Lefèvre, Philippe, Mclntyre, Joe, Kassel, Ronald, Desoete, Bart, Derkinderen, Wim, Penta, Massimo, André, Thibaut, 63rd International Astronautical Congress 2012, IAC 2012, UCL - SST/ICTM/INMA - Pôle en ingénierie mathématique, UCL - SSS/IONS/COSY - Systems & cognitive Neuroscience, UCL - (SLuc) Service de médecine physique et de réadaptation motrice, Pletser, Vladimir, Sundblad, Patrik, Thonnard, Jean-Louis, Lefèvre, Philippe, Mclntyre, Joe, Kassel, Ronald, Desoete, Bart, Derkinderen, Wim, Penta, Massimo, André, Thibaut, and 63rd International Astronautical Congress 2012, IAC 2012

Abstract

During exposure to microgravity in parabolic flights, it has been shown that the control of interaction forces when manipulating an object adapts partially to the lack of gravity, yet evidence indicates that anticipation of gravity's effects persists in the short term. The motivation for these experiments to be performed in long-duration space flight is to understand how the central nervous system adapts to an environment without gravity and what will be the consequences of long-term adaptation when an individual returns to a normal (Earth) or partial (Moon or Mars) gravitational field. The experiment "Dexterous Manipulation in Microgravity" (DEX) will target specific questions about the effects of gravity on dexterous manipulation. Some questions have already been studied over the last ten years in experiments conducted in parabolic flights, during which the way how the nervous system copes with repeated transitions between different gravitational environments has been investigated. Results from these experiments provide initial data about short-term adaptation to 0g. The experiments proposed for ISS draws from these short-term precursor experiments, but will emphasize long-term adaptation of sensorimotor processes to 0g and re-adaptation to 1 g. A first conceptual definition phase of a DEX instrument has been completed under an ESA contract. The DEX instrument is now in the design and development phase in view of a launch on ISS in the 2013- 2014 timeframe. The science background is recalled and several experiments performed during parabolic flights are presented, showing how these early breadboards testing in microgravity have helped to refine the DEX conceptual design and how it could be used on ISS. ©(2012) by the International Astronautieal Federation.

Published

2012