23rd SpaceX Cargo Resupply Services Mission Via Scientific Research

The 23rd SpaceX cargo resupply services mission carrying scientific research and technology demonstrations to the International Space Station is targeted to launch in late August from NASA’s Kennedy Space Center in Florida.

Cargo Resupply Services and Experiments aboard include an investigation into protecting bone health with botanical byproducts, testing a way to monitor crew eye health, demonstrating improved dexterity of robots, exposing construction materials to the harsh environment of space, mitigating stress in plants, and more.

Building bone with byproducts

READI FP evaluates the effects of microgravity and space radiation on growth of bone tissue and tests whether bioactive metabolites, substances such as antioxidants formed when food is broken down, might protect bones during spaceflight. The metabolites tested come from vegetal extracts generated as waste products in wine production in the Cargo Resupply Services.

Protecting the health of crew members from the effects of microgravity is crucial for the success of future long-duration space missions. This study could improve understanding of the physical changes that cause bone loss and identify potential countermeasures. This insight also could contribute to prevention and treatment of bone loss on Earth, particularly in post-menopausal women. Sourcing metabolites from materials that otherwise would become waste is an additional benefit.

Keeping an eye on eyes

Retinal Diagnostics tests whether a small, light-based device can capture images of the retinas of astronauts to document progression of vision problems known as Space-Associated Neuro-Ocular Syndrome (SANS). The device uses a commercially available lens approved for routine clinical use and is lightweight, mobile, and noninvasive. Videos and images can be downlinked to test and train models for detecting common signs of SANS in astronauts. The investigation is sponsored by ESA (European Space Agency) with the German Aerospace Center (DLR) Institute of Space Medicine and European Astronaut Centre (EAC) in that Cargo Resupply Services.

“SANS is present in over two-thirds of astronauts and thought to be associated with long duration (30 days or longer) exposure to microgravity,” said principal investigator Juergen Drescher of DLR. “Currently, visual problems that may manifest from SANS are mitigated by providing glasses or contact lenses to crew members. Multi-year missions to Mars may worsen these symptoms, and there is a need for a mobile device for retinal image diagnostics. While developed for space, this mobile technology has potential to provide diagnostics in remote and extreme environments on Earth at reduced cost. Mobile biomedical diagnostic devices such as these will likely emerge as both an enabler of human deep space exploration and a sustainable model for health care on Earth.”

Robotic helpers

Nanoracks-GITAI Robotic Arm demonstrates the versatility and dexterity in microgravity of a robot designed by GITAI Japan Inc. Results could support development of robotic labor to support crew activities and tasks, as well as servicing, assembly, and manufacturing tasks while in orbit in this Cargo Resupply Services. Robotic support could lower costs and improve crew safety by having robots take on tasks that could expose crew members to hazards. The technology also has applications in extreme and potentially dangerous environments on Earth, including disaster relief, deep-sea excavation, and servicing nuclear power plants. The experiment will be conducted under the pressurized environment inside the Bishop Airlock, the space station’s first commercial airlock.

“This technology demonstration is to show the world that the capabilities necessary for automation in space are finally available,” said company chief technology officer Toyotaka Kozuki. “It provides an inexpensive and safer source of labor in space, opening the door to the true commercialization of space.”

Putting materials to the test

MISSE-15 NASA is one of a series of MISSE investigations testing how the space environment affects the performance and durability of specific materials and components. These tests provide insights that support development of better materials for future spacecraft, spacesuits, planetary structures, and other components needed for space exploration. Testing materials in space has the potential to significantly speed up their development. Materials capable of standing up to space also have potential applications in harsh environments on Earth and for improved radiation protection, better solar cells, and more durable concrete. Alpha Space provides the MISSE-FF lab that hosts these investigations and Cargo Resupply Services.

“MISSE-15 includes tests of concrete, spacecraft materials, fiberglass composites, thin-film solar cells, radiation protection materials, a micro-optical chip, 3D printed polymers, and more,” said MISSE project engineer Ian Karcher. “In addition, the availability of this platform for commercial technology development contributes to the ongoing commercialization of space and development of new space technologies.”

Helping plants deal with stress

Plants grown under microgravity conditions typically display evidence of stress. APEX-08 examines the role of compounds known as polyamines in the response of thale cress to microgravity stress. Because expression of the genes involved in polyamine metabolism remain the same in space as on the ground, plants do not appear to use polyamines to respond to stress in microgravity. APEX-08 attempts to engineer a way for them to do so. Results could help identify key targets for genetic engineering of plants more suited to microgravity.

“On Earth, polyamines have been shown to contribute significantly to the mitigation of multiple environmental stresses in plants,” said principal investigator Patrick Masson, a professor at University of Wisconsin-Madison. “Altering the metabolism of a polyamine to mitigate the stress of microgravity could have an impact on our ability to use plants as key components of bioregenerative life support systems on long-term space exploration missions. It also may improve our understanding of the molecular mechanisms that allow plants to respond to general environmental stress on Earth, with impacts on agriculture, horticulture, and forestry.”

Easier drug delivery, Girl Scouts send science to space

The Faraday Research Facility is a multipurpose research facility that uses the space station’s EXPRESS racks. On this first flight, the facility hosts a Houston Methodist Research Institute experiment and two STEM collaborations, including “Making Space for Girls” with the Girl Scouts of Citrus Council.

“The ProXopS Faraday Research Facility, developed in partnership with L2 Solutions Inc., is designed to operate remotely and provide a controlled environment for power, command and control, telemetry responses, and safety assurance for microgravity experiments,” said Chad Brinkley, president of ProXopS LLC and L2 Solution Inc. “An added benefit with the facility is that experiments return to the ground for evaluation.” 

Faraday-NICE tests an implantable, remote-controlled drug delivery system using sealed containers of saline solution as surrogate test subjects. The device could provide an alternative to bulky, cumbersome infusion pumps, a possible game changer for long-term management of chronic conditions on Earth. Potential problems with such pumps include high infection risk, electromechanical failures, and double dosing. NICE is minimally invasive, implantable, has no moving mechanical components, and does not require catheters. Remote-controlled drug delivery could increase patient compliance, especially for children, elderly, and disabled individuals.

Faraday-Girl Scouts places control experiments with a Girl Scout troop and provides students with images of the same experiments in space. The studies include plant growth, ant colonization, and the brine shrimp lifecycle.

Source Scitech Daily

Arsalan Ahmad

Arsalan Ahmad is a Research Engineer working on 2-D Materials, graduated from the Institute of Advanced Materials, Bahaudin Zakariya University Multan, Pakistan. LinkedIn: https://www.linkedin.com/in/arsalanahmad-materialsresearchengr/

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