Cardiovascular deconditioning and impact of artificial gravity during 60-day head-down bed rest—Insights from 4D flow cardiac MRI

Rabineau, Jérémy; Issertine, Margot; Hoffmann, Fabian; Gerlach, Darius A.; Caiani, Enrico Gianluca; Haut, Benoı̂t; Borne, Philippe van de; Tank, Jens; Migeotte, Pierre-François

doi:10.3389/fphys.2022.944587

Cited by 9 publications

(3 citation statements)

References 123 publications

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“…Later methodologies, including Earth-based simulations of microgravity, particularly exposure to head-down-tilt bed rest (HDBR), have shown changes in the functional connectivity in the brain network in a relatively short time-three days [43]. However, this study joins that of Rabineau and colleagues [44] in having somewhat inconclusive results when the test subjects are exposed daily for 30 min to artificial gravity.…”

Section: Mitigations Using Artificial Gravitymentioning

confidence: 69%

Toward an Etiology of Spaceflight Neuroplastic Syndrome: Evolutionary Science Leads to New Hypotheses and Program Priorities

Rappaport,

Corbally

2023

NeuroSci

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Evolutionary theory is applied to recent neuroscientific findings on factors associated with risk-and-reward systems, and consequently, aspects of human decision making in spaceflight. Factors include enzymes aiding metabolic pathways of dopamine and serotonin; neurotrophic factors supporting neuronal functioning and plasticity; and genes associated with serotonin and dopamine systems. Not all factors are at risk in spaceflight. Some remain stable. It is hypothesized that neural deconditioning in spaceflight arises from faulty signals sent to the brain and gut in attempting to adapt phenotypically to a novel space environment. There is a mismatch between terrestrial selection pressures during human evolution and conditions of cosmic radiation, microgravity, and higher CO2, which together cause scattered results. A contrary question is broached: Given these findings, why are human sequelae not worse? Discussion of programmatic issues then focuses on methodologies to determine the suitability of civilians for spaceflight, an issue that grows more pressing while more varied populations prepare for spaceflight in LEO and on, and in orbit around the Moon.

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Section: Mitigations Using Artificial Gravitymentioning

confidence: 69%

Toward an Etiology of Spaceflight Neuroplastic Syndrome: Evolutionary Science Leads to New Hypotheses and Program Priorities

Rappaport,

Corbally

2023

NeuroSci

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“…Microgravity, or the partial absence of the Earth's gravitational forces as experienced in ISS, leads to unique physiological adaptations in the human body. Skeletal muscle atrophy [17,18], bone demineralization [19,20], and alterations in cardiovascular function [21,22] are among the well-documented consequences of prolonged exposure to microgravity. The absence of gravitational cues challenges the body's homeostatic mechanisms, necessitating countermeasures to mitigate the deleterious effects on astronaut health.…”

Section: Microgravitymentioning

confidence: 99%

Cultivation of Vitamin C-Rich Vegetables for Space-Radiation Mitigation

Mortazavi,

Yarbaksh,

Zarandi

et al. 2024

Radiation

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Space exploration introduces astronauts to challenges, such as space radiation and microgravity. Researchers have investigated vitamin C as a potential radiation mitigator, as well as antioxidants for sustaining astronaut health. Our own studies demonstrate vitamin C’s life-saving radioprotective effects and its potential as a radiation mitigator, thus highlighting promise, even when administered 24 h post-exposure. This is particularly relevant in scenarios where astronauts may be exposed to sudden large solar particle events, potentially resulting in lethal doses of space radiation. The success of vegetable cultivation on the International Space Station using NASA’s Veggie system offers fresh, vitamin C-rich food. While approved supplements address somatic function, further research is needed to optimize vitamin C’s efficacy in humans, and to develop appropriate antioxidant cocktails for space missions. The variable vitamin C content in vegetables underscores the necessity for the utilization of artificial intelligence (AI) to assist astronauts in selecting and cultivating the vitamin C-rich vegetables best-suited to combat high levels of space radiation and microgravity. Particularly, AI algorithms can be utilized to analyze various factors, such as nutritional content, growth patterns, and cultivation methods. In conclusion, vitamin C shows significant potential for mitigating space radiation, and ongoing research aims to enhance astronaut health through optimal dietary strategies.

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“…the impacts of the microgravity environment on VSMCs, asRabineau et al (2022) noted in their review how the menstrual cycle can impact smooth muscle sensitivity to NO. Another research group reported that clinostat simulated microgravity in combination with EC-conditioned media helped mitigate the anti-proliferative effects of the media on bovine aortic VSMCs.…”

mentioning

confidence: 99%

The Effects of Simulated and Real Microgravity on Vascular Smooth Muscle Cells

Ludtka,

Allen

2024

Gravitational and Space Research

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As considerations are being made for the limitations and safety of long-term human spaceflight, the vasculature is important given its connection to and impact on numerous organ systems. As a major constituent of blood vessels, vascular smooth muscle cells are of interest due to their influence over vascular tone and function. Additionally, vascular smooth muscle cells are responsive to pressure and flow changes. Therefore, alterations in these parameters under conditions of microgravity can be functionally disruptive. As such, here we review and discuss the existing literature that assesses the effects of microgravity, both actual and simulated, on smooth muscle cells. This includes the various methods for achieving or simulating microgravity, the animal models or cells used, and the various durations of microgravity assessed. We also discuss the various reported findings in the field, which include changes to cell proliferation, gene expression and phenotypic shifts, and renin-angiotensin-aldosterone system (RAAS), nitric oxide synthase (NOS), and Ca2+ signaling. Additionally, we briefly summarize the literature on smooth muscle tissue engineering in microgravity as well as considerations of radiation as another key component of spaceflight to contextualize spaceflight experiments, which by their nature include radiation exposure. Finally, we provide general recommendations based on the existing literature's focus and limitations.

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Cardiovascular deconditioning and impact of artificial gravity during 60-day head-down bed rest—Insights from 4D flow cardiac MRI

Cited by 9 publications

References 123 publications

Toward an Etiology of Spaceflight Neuroplastic Syndrome: Evolutionary Science Leads to New Hypotheses and Program Priorities

Toward an Etiology of Spaceflight Neuroplastic Syndrome: Evolutionary Science Leads to New Hypotheses and Program Priorities

Cultivation of Vitamin C-Rich Vegetables for Space-Radiation Mitigation

The Effects of Simulated and Real Microgravity on Vascular Smooth Muscle Cells

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