Harnessing the Space Environment for the Discovery and Development of New Medicines

Abstract: The unique nature of microgravity encountered in space provides both an opportunity and challenge for drug discovery and development that cannot be fully replicated on Earth. Scientific studies have been conducted across most phases of the drug discovery value chain and include the generation of superior protein crystals, identification, and validation of new drug targets, microarray analyses of transcripts attenuated by microgravity, and nonclinical in vivo studies to explore potential therapeutic benefit of … Show more

“…In the area of life sciences, the primary goal is the deep understanding of the cellular and disease mechanisms, biological pathways, and potential protein targets that play a role in mediating the response to microgravity and/or space radiation (Braddock 2020; Ruyters et al 2017;Ryder and Braddock 2020).…”

Chemistry‐Related Innovations in Space, Benefits of Flow Chemistry

“…In the area of life sciences, the primary goal is the deep understanding of the cellular and disease mechanisms, biological pathways, and potential protein targets that play a role in mediating the response to microgravity and/or space radiation (Braddock 2020; Ruyters et al 2017;Ryder and Braddock 2020).…”

Chemistry‐Related Innovations in Space, Benefits of Flow Chemistry

“…Space travel is well known to cause a range of problematic effects in astronauts; the most wellknown related to their central nervous system, cardiovascular system (in part due to fluid redistribution), musculoskeletal atrophy, immune system dysfunction and increased intracranial pressure [1] [2]. On a smaller scale, microorganisms are also affected by microgravity; due to the lack of hydrostatic pressure, sedimentation and convection currents in their culture media, which without stirring will lead to a build-up of metabolites surrounding cells and other effects [3], [4].…”

“…The interaction between microscopic effects and larger in-vivo changes in crew members is of critical importance. Pathogens such as Salmonella, Streptococcus pneumoniae and methicillin-resistant Staphylococcus aureus (MRSA) can exhibit an increased virulence and proliferation [2], drug resistance has been reported in E. coli and E. bugandensis [6], and biofilms (surface-associated cultures that can arise naturally on Earth or on platforms like MIR and the ISS) also from E. coli have been observed to have increased biomass and thickness [3].…”

Biomedical payloads: A maturing application for CubeSats

“…At the molecular and cellular level, the microgravity of space can alter the physico-chemical properties of protein crystals, membranes and cells. Such alterations may be harnessed for better understanding of the structure of BBB receptors and therapeutic proteins, engineering of 3D constructs of the neurovascular unit, and designing new drug formulations (Amselem, 2019;Ryder et al, 2020).…”

The Blood-Brain Barrier in Space: Implications for Space Travelers and for Human Health on Earth