Human Adaptability for Deep Space Missions: An Exploratory Study

Bartone, Paul T.; Roland, Róbert; Bartone, Jocelyn V; Krueger, Gerald P.; Sciarretta, Albert A.; Johnsen, Bjørn Helge

doi:10.7771/2327-2937.1124

Cited by 10 publications

(6 citation statements)

References 21 publications

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“…Human adaptability for deep space environment is crucial for mission success. In addition to traditional coping and resource strategies for astronauts' adaptation [1], a space robot's social adaptability to astronauts could also facilitate their adaptation to deep space with the long-term goal of maintaining their health and productivity. Multiple social-affective signal modalities of astronauts could be leveraged to develop a robot social adaptation system, including their physiological signals (e.g., blood pressure, sleep patterns), physical conditions (e.g., malnutrition), as well as their psychological and cognitive states (e.g., depressive mood, anxiety, loneliness), alongside the robot's audiovisual observation of the naturalistic crew interactions.…”

Section: Robot Social Adaptation Designmentioning

confidence: 99%

Toward Designing Social Human-Robot Interactions for Deep Space Exploration

Chen,

Breazeal

2021

Preprint

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In planning for future human space exploration, it is important to consider how to design for uplifting interpersonal communications and social dynamics among crew members. What if embodied social robots could help to improve the overall team interaction experience in space? On Earth, social robots have been shown effective in providing companionship, relieving stress and anxiety, fostering connection among people, enhancing team performance, and mediating conflicts in human groups. In this paper, we introduce a set of novel research questions exploring social human-robot interactions in long-duration space exploration missions.

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Section: Robot Social Adaptation Designmentioning

confidence: 99%

Toward Designing Social Human-Robot Interactions for Deep Space Exploration

Chen,

Breazeal

2021

Preprint

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“…These results corroborate the cognitive–motivational–relational theory [ 10 ] and emphasize that the interaction between the person and the environment is mediated by the degree to which a situation is appraised as stressful and controllable. These findings suggest that individual differences could help explain the differences in psychological responses within a challenging situation [ 25 ].…”

Section: Introductionmentioning

confidence: 99%

Emotional Intelligence in Ultra-Marathon Runners: Implications for Recovery Strategy and Stress Responses during an Ultra-Endurance Race

Marilleau

Gaudino

Bagneux

et al. 2022

IJERPH

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The aim of this research was to investigate the role of trait emotional intelligence (EI) in recovery stress states in a mountain ultra-marathon (MUM) race. Recovery stress states of 13 finishers were assessed before, during, and immediately after the end of an extreme MUM, whereas emotional intelligence was assessed 2 days before the MUM race. Temporal evolutions of recovery stress states were examined. Stress states increased after the race whereas recovery states decreased in all participants. In addition, recovery states were influenced by the trait EI level assessed before the competition. Results supported the hypothesis that trait EI tends to have a positive effect by boosting recovery strategies. In this perspective, trait EI could have a protective role against stress and improve pre-competition mental preparation. High scores of trait EI (in comparison to low scores of trait EI) could have helped athletes to increase recovery states in order to improve their psychological adaptation to one of the most difficult races in the world.

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“…NASA is planning for a variety of deep space exploration activities, including a manned mission to Mars in the early 2030s [ 1 ]. Major risks have been identified for these long-duration expeditions, including isolation and having to endure and work in extreme environmental conditions [ 2 ]. Risk factors are related to both interplanetary flight and surface activity on planets [ 3 ].…”

Section: Introductionmentioning

confidence: 99%

“…Risk factors are related to both interplanetary flight and surface activity on planets [ 3 ]. Psychological strain, such as isolation from friends and family, boredom, fear of injuries and death, is ever present [ 4 , 5 ]. On the planet surface, severe physical demands during extreme temperatures will be experienced.…”

Section: Introductionmentioning

confidence: 99%

“…Antarctic expeditions have been described as “earth-bound” analogs to deep-space explorations [ 6 ]. Bartone et al [ 2 ], in their interview of subject matter experts, used both astronauts and a polar explorer as the basis for mapping various coping mechanisms during long-term space missions. Polar expeditions are characterized by some of the same psychological, physical and environmental stressors as long duration space flights.…”

Section: Introductionmentioning

confidence: 99%

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Crossing the Antarctica: Exploring the Effects of Appetite-Regulating Hormones and Indicators of Nutrition Status during a 93-Day Solo-Expedition

et al. 2021

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Future deep space astronauts must maintain adequate nutrition despite highly stressful, isolated, confined and dangerous environments. The present case-study investigated appetite regulating hormones, nutrition status, and physical and emotional stress in a space analog condition: an explorer conducting a 93-day unsupported solo crossing of Antarctica. Using the dried blood spot (DBS) method, the subject drew samples of his blood on a regular basis during the expedition. The DBSs were later analyzed for the appetite regulating hormones leptin and adiponectin. Energy intake and nutritional status were monitored by analysis of albumin and globulin (including their ratio). Interleukin-6 (IL-6) was also analyzed and used as an energy sensor. The results showed a marked reduction in levels of the appetite-reducing hormone, leptin, and the appetite stimulating hormone, adiponectin, during both extreme physical and psychological strain. Nutrition status showed a variation over the expedition, with below-normal levels during extreme psychological strain and levels abutting the lower bounds of the normal range during a phase dominated by extreme physical hardship. The IL-6 levels varied substantially, with levels above the normal range except during the recovery phase. It was concluded that a daily intake of 5058 to 5931 calories seemed to allow recovery of both appetite and nutritional status between extreme physical and psychological hardship during a long Arctic expedition. Furthermore, IL-6 may be a sensor in the muscle-liver, muscle-fat and muscle-brain crosstalk. These results may help guide nutrition planning for future astronaut crews, mountaineers and others involved in highly demanding missions.

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Human Adaptability for Deep Space Missions: An Exploratory Study

Cited by 10 publications

References 21 publications

Toward Designing Social Human-Robot Interactions for Deep Space Exploration

Toward Designing Social Human-Robot Interactions for Deep Space Exploration

Emotional Intelligence in Ultra-Marathon Runners: Implications for Recovery Strategy and Stress Responses during an Ultra-Endurance Race

Crossing the Antarctica: Exploring the Effects of Appetite-Regulating Hormones and Indicators of Nutrition Status during a 93-Day Solo-Expedition

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