The Space Environment on Human Health and Disease

A special issue of Life (ISSN 2075-1729). This special issue belongs to the section "Astrobiology".

Deadline for manuscript submissions: closed (31 December 2023) | Viewed by 35457

Special Issue Editors


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Guest Editor
1. NASA Jet Propulsion Laboratory, California Institute of Technology, Pasadena, CA 91125, USA
2. ZIN Technologies Inc, Middleburg Hts, OH 44017, USA
Interests: microbiome; microbiology; immunology; space life sciences; international space station; altered gravity

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Guest Editor Assistant
Honeybee Robotics, Altadena, CA 41070, USA
Interests: sterilization and inactivation; prions; microbes in extreme environments; spores; astrobiology

Special Issue Information

Dear Colleagues,

Humans have been exploring space for the last sixty-five years, and with the creation of the International Space Station humans have been living and working in space continuously for the past 22 years. Astronauts endure many physiological and psychological changes while in space as a result of altered gravity, radiation, and confinement, to name but a few factors. While some effects are well-known, such as bone and muscle loss, others, such as the taxonomic and functional changes in astronauts’ microbiome, the mechanisms behind immune dysregulation, and the long-term risks to health, are less well-understood. Understanding how all aspects of the human body and its microbiome changes and adapts to space travel is essential to reach our goal of long-duration human exploration in low Earth orbit and beyond.

This Special Issue will solicit original research articles, reviews, and commentaries on the effects of spaceflight on astronauts’ microbiome and physiology. Topics of interest include, but are not limited to:

  • Omics studies on the human microbiome during spaceflight and analog missions.
  • The effects of stress, diet, radiation, and altered gravity on the taxonomic and functional profiles of the microbiome.
  • Studies related to countermeasures, such as training regimes, diet, and probiotics, in maintaining a balanced astronaut microbiome.
  • The impact of spaceflight on bone health, immunity, cognitive function, cancer risk, anxiety, allergies and hypersensitivities, viral reactivation, and GI function (to name but a few).
  • Association studies between various space-related effects on astronaut health—for example, the microbiome and immune function, or the immune system and bone health, during spaceflight.

Dr. Camilla Urbaniak
Guest Editor

Emily Seto
Guest Editor Assistant

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Keywords

  • microbiome
  • astronaut health
  • space life sciences
  • radiation
  • altered gravity
  • omics 
  • spaceflight

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Published Papers (8 papers)

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Research

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18 pages, 8445 KiB  
Article
Predicting Bone Adaptation in Astronauts during and after Spaceflight
by Tannis D. Kemp, Bryce A. Besler, Leigh Gabel and Steven K. Boyd
Life 2023, 13(11), 2183; https://doi.org/10.3390/life13112183 - 9 Nov 2023
Viewed by 1575
Abstract
A method was previously developed to identify participant-specific parameters in a model of trabecular bone adaptation from longitudinal computed tomography (CT) imaging. In this study, we use these numerical methods to estimate changes in astronaut bone health during the distinct phases of spaceflight [...] Read more.
A method was previously developed to identify participant-specific parameters in a model of trabecular bone adaptation from longitudinal computed tomography (CT) imaging. In this study, we use these numerical methods to estimate changes in astronaut bone health during the distinct phases of spaceflight and recovery on Earth. Astronauts (N = 16) received high-resolution peripheral quantitative CT (HR-pQCT) scans of their distal tibia prior to launch (L), upon their return from an approximately six-month stay on the international space station (R+0), and after six (R+6) and 12 (R+12) months of recovery. To model trabecular bone adaptation, we determined participant-specific parameters at each time interval and estimated their bone structure at R+0, R+6, and R+12. To assess the fit of our model to this population, we compared static and dynamic bone morphometry as well as the Dice coefficient and symmetric distance at each measurement. In general, modeled and observed static morphometry were highly correlated (R2> 0.94) and statistically different (p < 0.0001) but with errors close to HR-pQCT precision limits. Dynamic morphometry, which captures rates of bone adaptation, was poorly estimated by our model (p < 0.0001). The Dice coefficient and symmetric distance indicated a reasonable local fit between observed and predicted bone volumes. This work applies a general and versatile computational framework to test bone adaptation models. Future work can explore and test increasingly sophisticated models (e.g., those including load or physiological factors) on a participant-specific basis. Full article
(This article belongs to the Special Issue The Space Environment on Human Health and Disease)
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10 pages, 535 KiB  
Article
Effect of Microgravity on the Gut Microbiota Bacterial Composition in a Hindlimb Unloading Model
by Ruqaiyyah Siddiqui, Rizwan Qaisar, Naveed Ahmed Khan, Ahmad M. Alharbi, Hasan Alfahemi and Adel Elmoselhi
Life 2022, 12(11), 1865; https://doi.org/10.3390/life12111865 - 12 Nov 2022
Cited by 9 | Viewed by 2448
Abstract
We utilised a ground-based microgravity hindlimb unloading (HU) mouse model to elucidate the gut microbiota bacterial changes in mice under a simulated microgravity environment. Four-month-old, male C57/Bl6 mice were randomly divided into ground-based controls and the HU groups and kept under controlled environmental [...] Read more.
We utilised a ground-based microgravity hindlimb unloading (HU) mouse model to elucidate the gut microbiota bacterial changes in mice under a simulated microgravity environment. Four-month-old, male C57/Bl6 mice were randomly divided into ground-based controls and the HU groups and kept under controlled environmental conditions. For the microgravity environment, the mice were suspended in special cages individually for 20 days. At the end of the suspension, the mice were sacrificed; gut dissections were performed, followed by a metagenomic analysis of bacterial species, which was carried out by extracting DNA and 16S rRNA analysis. The results revealed that the gut bacterial communities of mice under gravity and microgravity were different. Notably, our findings revealed differences in the bacterial community structure. Around 449 bacterial OTUs were specific to mice kept under normal gravity versus 443 bacterial OTUs under microgravity conditions. In contrast, 694 bacterial OTUs were common to both groups. When the relative abundance of taxa was analyzed, Bacteroidetes dominated the gut (64.7%) of normal mice. Conversely, mice in the microgravity environment were dominated by Firmicutes (42.7%), and the relative abundance of Bacteroidetes differed significantly between the two groups (p < 0.05). The distribution of Muribaculaceae between normal mice versus microgravity mice was significantly different, at 62% and 36.4%, respectively (p < 0.05). Furthermore, a significant decrease in 11 bacteria was observed in mice under simulated microgravity, including Akkermansia muciniphila, Eubacterium coprostanoligenes, Bacteroides acidifaciens, Clostridium leptum, Methylorubrum extorquens, Comamonas testosterone, Desulfovibrio fairfieldensis, Bacteroides coprocola, Aerococcus urinaeequi, Helicobacter hepaticus, and Burkholderiales. Further studies are needed to elucidate gut bacterial metabolites of these identified bacterial species in microgravity conditions and normal environment. Notably, the influence of these metabolites on obesity, neuroprotection, musculoskeletal and cardiovascular dysfunction, longevity, inflammation, health, and disease in astronauts ought to be investigated and will be important in developing procedures against adverse effects in astronauts following space travel. Full article
(This article belongs to the Special Issue The Space Environment on Human Health and Disease)
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14 pages, 1588 KiB  
Article
The Role of 4-Phenylbutyric Acid in Gut Microbial Dysbiosis in a Mouse Model of Simulated Microgravity
by Shama Shama, Rizwan Qaisar, Naveed Ahmed Khan, Isfahan Tauseef and Ruqaiyyah Siddiqui
Life 2022, 12(9), 1301; https://doi.org/10.3390/life12091301 - 24 Aug 2022
Cited by 10 | Viewed by 2808
Abstract
The altered gut microbes of astronauts during space travel may contribute to health issues after their return to Earth. Previously, an association between the elevated endoplasmic reticulum (ER) stress and gut microbial dysbiosis has been described. Herein, we induced gut microbial changes in [...] Read more.
The altered gut microbes of astronauts during space travel may contribute to health issues after their return to Earth. Previously, an association between the elevated endoplasmic reticulum (ER) stress and gut microbial dysbiosis has been described. Herein, we induced gut microbial changes in mice under a simulated microgravity environment in an established model of hindlimb unloaded (HU) mice. The intestinal metabolomic profiles under microgravity conditions using the HU model were examined, along with the potential role of 4-phenylbutyric acid (4-PBA), a potent ER stress inhibitor. For a microgravity environment, the mice were suspended in special cages individually for three weeks. Mice were sacrificed, and gut dissections were performed, followed by amplicon sequencing analysis of bacterial species via DNA extraction and 16S rRNA analysis. The results indicate that the gut bacterial communities of mice differed under gravity and microgravity conditions. Principal component analyses revealed differences in the bacterial community structure in all groups. Around 434 operational taxonomic units (OTUs) were specific to mice seen in controls, while 620 OTUs were specific to HU mice. Additionally, 321 bacterial OTUs were specific to HU mice treated with 4-PBA. When the relative abundance of taxa was analyzed, Bacteroidetes dominated the gut of control and HU mice treated with 4-PBA.. In contrast, the untreated HU mice were dominated by Firmicutes. At the genus level, a reduction in beneficial species of Akkermansia and Lactobacillus was observed in HU but not the unloaded–treated and control mice. Furthermore, an increase in the relative abundance of Lachnospiraceae and Enterorhabdus, associated with inflammation, was observed in HUmice but not in controls and unloaded-treated mice. Following treatment with 4-PBA, the ratio of Firmicutes to Bacteroidetes was restored in unloaded–treated mice, comparable to controls. Of note, beneficial microbes such as Akkermansia and Lactobacillus were observed in unloaded–treated mice but not or in lesser relative abundance in HU mice. Nonetheless, microbial diversity was reduced in unloaded–treated mice compared to controls, and future studies are needed to mitigate this finding. These may comprise the addition of pre-/pro- and postbiotic species in the diet to increase microbial diversity. Overall, the findings suggest that 4-PBA, a potent ER stress inhibitor, may have therapeutic value in treating patients on prolonged bed rest or astronauts during spaceflight. Full article
(This article belongs to the Special Issue The Space Environment on Human Health and Disease)
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Review

Jump to: Research

27 pages, 3284 KiB  
Review
Impact of Microgravity and Other Spaceflight Factors on Retina of Vertebrates and Humans In Vivo and In Vitro
by Eleonora N. Grigoryan
Life 2023, 13(6), 1263; https://doi.org/10.3390/life13061263 - 26 May 2023
Cited by 5 | Viewed by 2730
Abstract
Spaceflight (SF) increases the risk of developmental, regenerative, and physiological disorders in animals and humans. Astronauts, besides bone loss, muscle atrophy, and cardiovascular and immune system alterations, undergo ocular disorders affecting posterior eye tissues, including the retina. Few studies revealed abnormalities in the [...] Read more.
Spaceflight (SF) increases the risk of developmental, regenerative, and physiological disorders in animals and humans. Astronauts, besides bone loss, muscle atrophy, and cardiovascular and immune system alterations, undergo ocular disorders affecting posterior eye tissues, including the retina. Few studies revealed abnormalities in the development and changes in the regeneration of eye tissues in lower vertebrates after SF and simulated microgravity. Under microgravity conditions, mammals show disturbances in the retinal vascular system and increased risk of oxidative stress that can lead to cell death in the retina. Animal studies provided evidence of gene expression changes associated with cellular stress, inflammation, and aberrant signaling pathways. Experiments using retinal cells in microgravity-modeling systems in vitro additionally indicated micro-g-induced changes at the molecular level. Here, we provide an overview of the literature and the authors’ own data to assess the predictive value of structural and functional alterations for developing countermeasures and mitigating the SF effects on the human retina. Further emphasis is given to the importance of animal studies on the retina and other eye tissues in vivo and retinal cells in vitro aboard spacecraft for understanding alterations in the vertebrate visual system in response to stress caused by gravity variations. Full article
(This article belongs to the Special Issue The Space Environment on Human Health and Disease)
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18 pages, 695 KiB  
Review
Addressing Spaceflight Biology through the Lens of a Histologist–Embryologist
by Paschalis Theotokis, Maria Eleni Manthou, Theodora-Eleftheria Deftereou, Dimosthenis Miliaras and Soultana Meditskou
Life 2023, 13(2), 588; https://doi.org/10.3390/life13020588 - 20 Feb 2023
Cited by 1 | Viewed by 2519
Abstract
Embryogenesis and fetal development are highly delicate and error-prone processes in their core physiology, let alone if stress-associated factors and conditions are involved. Space radiation and altered gravity are factors that could radically affect fertility and pregnancy and compromise a physiological organogenesis. Unfortunately, [...] Read more.
Embryogenesis and fetal development are highly delicate and error-prone processes in their core physiology, let alone if stress-associated factors and conditions are involved. Space radiation and altered gravity are factors that could radically affect fertility and pregnancy and compromise a physiological organogenesis. Unfortunately, there is a dearth of information examining the effects of cosmic exposures on reproductive and proliferating outcomes with regard to mammalian embryonic development. However, explicit attention has been given to investigations exploring discrete structures and neural networks such as the vestibular system, an entity that is viewed as the sixth sense and organically controls gravity beginning with the prenatal period. The role of the gut microbiome, a newly acknowledged field of research in the space community, is also being challenged to be added in forthcoming experimental protocols. This review discusses the data that have surfaced from simulations or actual space expeditions and addresses developmental adaptations at the histological level induced by an extraterrestrial milieu. Full article
(This article belongs to the Special Issue The Space Environment on Human Health and Disease)
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13 pages, 1531 KiB  
Review
Long-Duration Space Travel Support Must Consider Wider Influences to Conserve Microbiota Composition and Function
by Kait F. Al, John A. Chmiel, Gerrit A. Stuivenberg, Gregor Reid and Jeremy P. Burton
Life 2022, 12(8), 1163; https://doi.org/10.3390/life12081163 - 30 Jul 2022
Cited by 3 | Viewed by 3813
Abstract
The microbiota is important for immune modulation, nutrient acquisition, vitamin production, and other aspects for long-term human health. Isolated model organisms can lose microbial diversity over time and humans are likely the same. Decreasing microbial diversity and the subsequent loss of function may [...] Read more.
The microbiota is important for immune modulation, nutrient acquisition, vitamin production, and other aspects for long-term human health. Isolated model organisms can lose microbial diversity over time and humans are likely the same. Decreasing microbial diversity and the subsequent loss of function may accelerate disease progression on Earth, and to an even greater degree in space. For this reason, maintaining a healthy microbiome during spaceflight has recently garnered consideration. Diet, lifestyle, and consumption of beneficial microbes can shape the microbiota, but the replenishment we attain from environmental exposure to microbes is important too. Probiotics, prebiotics, fermented foods, fecal microbiota transplantation (FMT), and other methods of microbiota modulation currently available may be of benefit for shorter trips, but may not be viable options to overcome the unique challenges faced in long-term space travel. Novel fermented food products with particular impact on gut health, immune modulation, and other space-targeted health outcomes are worthy of exploration. Further consideration of potential microbial replenishment to humans, including from environmental sources to maintain a healthy microbiome, may also be required. Full article
(This article belongs to the Special Issue The Space Environment on Human Health and Disease)
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17 pages, 4180 KiB  
Review
Monitoring the Impact of Spaceflight on the Human Brain
by Michael F. Dinatolo and Luchino Y. Cohen
Life 2022, 12(7), 1060; https://doi.org/10.3390/life12071060 - 15 Jul 2022
Cited by 10 | Viewed by 4525
Abstract
Extended exposure to radiation, microgravity, and isolation during space exploration has significant physiological, structural, and psychosocial effects on astronauts, and particularly their central nervous system. To date, the use of brain monitoring techniques adopted on Earth in pre/post-spaceflight experimental protocols has proven to [...] Read more.
Extended exposure to radiation, microgravity, and isolation during space exploration has significant physiological, structural, and psychosocial effects on astronauts, and particularly their central nervous system. To date, the use of brain monitoring techniques adopted on Earth in pre/post-spaceflight experimental protocols has proven to be valuable for investigating the effects of space travel on the brain. However, future (longer) deep space travel would require some brain function monitoring equipment to be also available for evaluating and monitoring brain health during spaceflight. Here, we describe the impact of spaceflight on the brain, the basic principles behind six brain function analysis technologies, their current use associated with spaceflight, and their potential for utilization during deep space exploration. We suggest that, while the use of magnetic resonance imaging (MRI), positron emission tomography (PET), and computerized tomography (CT) is limited to analog and pre/post-spaceflight studies on Earth, electroencephalography (EEG), functional near-infrared spectroscopy (fNIRS), and ultrasound are good candidates to be adapted for utilization in the context of deep space exploration. Full article
(This article belongs to the Special Issue The Space Environment on Human Health and Disease)
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47 pages, 1562 KiB  
Review
Understanding the Complexities and Changes of the Astronaut Microbiome for Successful Long-Duration Space Missions
by Donatella Tesei, Anna Jewczynko, Anne M. Lynch and Camilla Urbaniak
Life 2022, 12(4), 495; https://doi.org/10.3390/life12040495 - 28 Mar 2022
Cited by 30 | Viewed by 12894
Abstract
During space missions, astronauts are faced with a variety of challenges that are unique to spaceflight and that have been known to cause physiological changes in humans over a period of time. Several of these changes occur at the microbiome level, a complex [...] Read more.
During space missions, astronauts are faced with a variety of challenges that are unique to spaceflight and that have been known to cause physiological changes in humans over a period of time. Several of these changes occur at the microbiome level, a complex ensemble of microbial communities residing in various anatomic sites of the human body, with a pivotal role in regulating the health and behavior of the host. The microbiome is essential for day-to-day physiological activities, and alterations in microbiome composition and function have been linked to various human diseases. For these reasons, understanding the impact of spaceflight and space conditions on the microbiome of astronauts is important to assess significant health risks that can emerge during long-term missions and to develop countermeasures. Here, we review various conditions that are caused by long-term space exploration and discuss the role of the microbiome in promoting or ameliorating these conditions, as well as space-related factors that impact microbiome composition. The topics explored pertain to microgravity, radiation, immunity, bone health, cognitive function, gender differences and pharmacomicrobiomics. Connections are made between the trifecta of spaceflight, the host and the microbiome, and the significance of these interactions for successful long-term space missions. Full article
(This article belongs to the Special Issue The Space Environment on Human Health and Disease)
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