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Lower body negative pressure as a research tool and countermeasure for the physiological effects of spaceflight: A comprehensive review

Lower Body Negative Pressure (LBNP) redistributes blood from the upper body to the lower body. LBNP may prove to be a countermeasure for the multifaceted physiological changes endured by astronauts during spaceflight related to cephalad fluid shift. Over more than five decades, beginning with the er...

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Bibliographic Details
Published in:Life sciences in space research 2024-08, Vol.42, p.8-16
Main Authors: Paladugu, Phani, Ong, Joshua, Kumar, Rahul, Waisberg, Ethan, Zaman, Nasif, Kamran, Sharif Amit, Tavakkoli, Alireza, Rivolta, Maria Chiara, Nelson, Nicolas, Yoo, Taehwan, Douglas, Vivian Paraskevi, Douglas, Konstantinos, Song, Amy, Tso, Hanna, Lee, Andrew G.
Format: Article
Language:English
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Summary:Lower Body Negative Pressure (LBNP) redistributes blood from the upper body to the lower body. LBNP may prove to be a countermeasure for the multifaceted physiological changes endured by astronauts during spaceflight related to cephalad fluid shift. Over more than five decades, beginning with the era of Skylab, advancements in LBNP technology have expanded our understanding of neurological, ophthalmological, cardiovascular, and musculoskeletal adaptations in space, with particular emphasis on mitigating issues such as bone loss. To date however, no comprehensive review has been conducted that chronicles the evolution of this technology or elucidates the broad-spectrum potential of LBNP in managing the diverse physiological challenges encountered in the microgravity environment. Our study takes a chronological perspective, systematically reviewing the historical development and application of LBNP technology in relation to the various pathophysiological impacts of spaceflight. The primary objective is to illustrate how this technology, as it has evolved, offers an increasingly sophisticated lens through which to interpret the systemic effects of space travel on human physiology. We contend that the insights gained from LBNP studies can significantly aid in formulating targeted and effective countermeasures to ensure the health and safety of astronauts. Ultimately, this paper aspires to promote a more cohesive understanding of the broad applicability of LBNP as a countermeasure against multiple bodily effects of space travel, thereby contributing to a safer and more scientifically informed approach to human space exploration.
ISSN:2214-5524
DOI:10.1016/j.lssr.2024.03.007