A Simulated Microgravity Environment Causes a Sustained Defect in Epithelial Barrier Function

Alvarez, Rocio; Stork, Cheryl; Sayoc-Becerra, Anica; Marchelletta, Ronald R.; Prisk, G. Kim; McCole, Declan F.

doi:10.1038/s41598-019-53862-3

Cited by 22 publications

(22 citation statements)

References 93 publications

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“…The duration that cells were exposed to simulated microgravity is an important experimental variable, which can range from 1 hour 116 to over 14 days. 105 There is increasing evidence that simulated microgravity exerts temporal effects due to cellular adaptation. For example, prolonged exposure to simulated microgravity (between 2 and 14 days) was shown to reduce dendritic T cell activation whereas short term exposition (<72 hours) increased dendritic cell maturation markers.…”

Section: Duration Of Simulated Microgravity Exposurementioning

confidence: 99%

“…This can significantly reduce autocrine signaling and may be another factor behind apoptosis and lower cell numbers typically reported in simulated microgravity studies. For example, RWV (full vessel) culture of intestinal epithelial cells was shown to disrupt intestinal epithelial barrier integrity 105 and increased culture medium volume was found to reduce osteoblast fusion and mineralization (bone formation) 106 . In paracrine studies, cell‐conditioned medium extracted from s‐μg culture was reported to have a cross‐pathogenic effect on endothelial cell and smooth muscle cell proliferation and migration compared to normal gravity‐conditioned medium 107 .…”

Section: Cell Signaling and The Culture Environmentmentioning

confidence: 99%

“…The duration that cells were exposed to simulated microgravity is an important experimental variable, which can range from 1 hour 116 to over 14 days 105 . There is increasing evidence that simulated microgravity exerts temporal effects due to cellular adaptation.…”

Section: Experimental Designmentioning

confidence: 99%

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Factors implicating the validity and interpretation of mechanobiology studies in simulated microgravity environments

Poon

2020

Engineering Reports

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Simulated microgravity (s-μg) devices provide unique conditions for elucidating the effects of gravitational unloading on biological processes and are increasingly being applied for mechanobiology studies. However, without proper characterization of the mechanical environment generated by these systems, the interpretation of results is confounded and limited. Furthermore, the cell culture approaches central to s-μg experimentation introduces new factors that can fundamentally affect results, but these are currently not addressed. It is essential to understand the complete culture environment and how constituent conditions can individually and synergistically affect cellular responses in order to correctly interpret results, otherwise outcomes may be misattributed to the effects of microgravity alone. For the benefit of the growing space biology community, this article critically reviews a typical s-μg cell culture environment in terms of three key conditions: fluid-mediated mechanical stimuli, oxygen tension and biochemical. These and the implications of other experimental variables for biological analysis are categorically discussed. A new set of controls is proposed to properly evaluate the respective effects of these conditions in s-μg culture, along with a reporting matrix and potential strategies for addressing the current limitations of simulated microgravity devices as a platform for mechanobiology research.

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Section: Duration Of Simulated Microgravity Exposurementioning

confidence: 99%

Section: Cell Signaling and The Culture Environmentmentioning

confidence: 99%

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Factors implicating the validity and interpretation of mechanobiology studies in simulated microgravity environments

Poon

2020

Engineering Reports

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“…Igualmente existen alteraciones en la motilidad, microbiota intestinal, metabolismo de glucosa y lípidos (89,90) , daño de las vellosidades intestinales e interrupción en las uniones celulares epiteliales por la expresión de la proteína proapoptótica Bax y disminución de Bcl2; alterando de esta manera su función defensiva, homeostasis y el riesgo de contraer enfermedades inflamatorias intestinales (76,91,92,93) por el aumento de citosinas y disminución de la inmunoglobulina secretora (IgA) (76) .…”

Section: Sistema Digestivounclassified

Medicina humana espacial: Performance fisiológico y contramedidas para mejorar la salud del astronauta

Rivera¹,

Cornejo²,

Huallpayunca³

et al. 2020

RFMH

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This Review Article is presented based on current scientific evidence on space medicine focused on human physiology and its countermeasures. Therefore, a non-systematic bibliographic search of scientific articles and research books in English-Spanish of the last 7 years was carried out, detailing their application in humans, murine models and in vitro experiments. The conditions of the space environment such as microgravity and radiation that produce considerable physiological changes in the cardiovascular system (redistribution of fluids, cardiovascular remodeling, arrhythmias) were taken into account; nervous (sensorimotor, neurosensory, neurovestibular); respiratory (volume and capacity changes); renal (lithiasis); musculoskeletal (muscular atrophy, osteoporosis); hematological (anemia); immunological (immune dysregulation) and digestive (intestinal microbiota disorder). In addition, there are biological, molecular and genetic processes still to be explored, in order to know and mitigate the uncertain mechanisms triggered in extreme and dangerous environments. Therefore, it is a priority to develop and implement countermeasures to reduce the harmful effects on health, with the aim of guaranteeing the astronaut's adaptation, safety and performance during future space flights.

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“…Professor McCole's group, together with Dr Kim Prisk, investigated the previously little-understood effects of microgravity (low gravity environments, as would be experienced in outer space) on the epithelial cell barrier (5). Previous studies in the field of space biology have demonstrated that microgravity can have a negative impact on the human immune system, via suppression of multiple immune cells.…”

Section: Microgravitymentioning

confidence: 99%

Inflammatory bowel disease and epithelial barrier function

2020

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A Simulated Microgravity Environment Causes a Sustained Defect in Epithelial Barrier Function

Cited by 22 publications

References 93 publications

Factors implicating the validity and interpretation of mechanobiology studies in simulated microgravity environments

Factors implicating the validity and interpretation of mechanobiology studies in simulated microgravity environments

Medicina humana espacial: Performance fisiológico y contramedidas para mejorar la salud del astronauta

Inflammatory bowel disease and epithelial barrier function

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