Whereas the Worldwide Area Station (ISS) was touring in orbit greater than 267 miles over the South Atlantic Ocean, the
The Dragon launched on SpaceX’s 25th contracted commercial resupply mission for NASA from Launch Complex 39A at the agency’s Kennedy Space Center in Florida at 8:44 p.m. EDT, Thursday, July 14. After Dragon spends about one month attached to the orbiting laboratory, the spacecraft will return to Earth with cargo and research.
Among the science experiments Dragon is delivering to the space station are:
Mapping Earth’s dust
Developed by NASA’s Jet Propulsion Laboratory in Southern California, the Earth Surface Mineral Dust Source Investigation (EMIT) employs NASA imaging spectroscopy technology to measure the mineral composition of dust in Earth’s arid regions. Mineral dust blown into the air can travel significant distances and affect Earth’s climate, weather, vegetation, and more. For instance, an area may be warmed by dust made of dark minerals that absorb sunlight, whereas a region might be cooled by dust made of light-colored minerals. Air quality, surface conditions including the speed at which snow melts, and ocean phytoplankton health are all impacted by blowing dust. For the duration of a year, the investigation will collect images to generate maps of the mineral composition in the dust-producing regions on Earth. Such mapping could advance our understanding of how mineral dust affects human populations now and in the future.
Speedier immune system aging
Immunosenescence is the changes in the immune system due to aging. Microgravity causes changes in human immune cells that resemble immunosenescence, but they happen much faster than the actual process of aging on Earth. Sponsored by ISS National Lab, the Immunosenescence investigation, uses tissue chips to study how microgravity affects immune function during flight and whether immune cells recover post-flight. Tissue chips are small devices that contain human cells in a 3D structure, that allow researchers to test how those cells respond to stresses, drugs, and genetic changes.
“Immune aging impacts tissue stem cells and their ability to repair tissues and organs,” says principal investigator Sonja Schrepfer, professor of surgery at University of California San Francisco (UCSF). “Our studies aim to understand critical pathways to prevent and to reverse aging of immune cells.”
“Spaceflight conditions enable the study of immune aging that would not be feasible in the lab,” says co-investigator Tobias Deuse, professor of surgery at UCSF. This work could support development of treatments for immune system aging on Earth. The investigation also could support development of methods to protect astronauts during future long-duration spaceflight.
The twenty fifth SpaceX cargo resupply companies mission (SpaceX CRS-25) carrying scientific analysis and know-how demonstrations to the Worldwide Area Station launched on July 14 from NASA’s Kennedy Area Heart in Florida. Experiments aboard the Dragon capsule embody research of the immune system, wound therapeutic, soil communities, and cell-free biomarkers, together with mapping the composition of Earth’s mud and testing an alternative choice to concrete. Credit score: NASA
Small satellites, large science
5 CubeSats lauched on this mission sponsored by NASA’s Launch Companies Program, together with BeaverCube, which launched to the area station for deployment into low-Earth orbit. A number of cameras are employed by the small satellite tv for pc together with one which takes coloration photographs of Earth’s oceans and two that acquire thermal photographs of cloud tops and the ocean floor. Cloud high and ocean floor temperatures assist researchers perceive Earth’s local weather and climate techniques. The collected knowledge additionally assist scientists enhance their understanding of the ocean’s focus of phytoplankton, a crucial think about the technology of atmospheric oxygen.
“Most Earth statement missions primarily picture over land, specializing in populated areas and targets of curiosity. BeaverCube will deal with imaging oceans and coastal areas, combining thermal photographs with seen photographs to assist us higher perceive ocean fronts,” says principal investigator Kerri Cahoy, professor of aeronautics and astronautics on the Massachusetts Institute of Expertise (
Soil in space
Complex communities of microorganisms carry out key functions in soil on Earth, including supporting plant growth and cycling of carbon and other nutrients. DynaMoS, an investigation sponsored by NASA’s Division of Biological and Physical Sciences (BPS), examines how microgravity affects metabolic interactions in communities of soil microbes. This research focuses on microbe communities that decompose chitin, a natural carbon polymer on Earth.
“Soil microorganisms carry out beneficial functions that are essential for life on our planet,” says principal investigator Janet K. Jansson, chief scientist and laboratory fellow at Pacific Northwest National Laboratory. “To harness these beneficial activities for future space missions, we need to understand more about how conditions in space, like microgravity and radiation, influence these microbes and the beneficial functions that they provide. Perhaps in the future, we will use beneficial soil microbes to enhance growth of crops on the lunar surface.”
Improved understanding of the function of soil microorganism communities also could reveal ways to optimize these communities to support agricultural production on Earth.
Genes, no cells
Cell-free technology is a platform for producing protein without specialized equipment of living cells that need to be cultured. Genes in Space-9, sponsored by the ISS National Lab, demonstrates cell-free production of protein in microgravity and evaluates two cell-free biosensors that can detect specific target molecules. This technology could provide a simple, portable, and low-cost tool for medical diagnostics, on-demand production of medicine and vaccines, and environmental monitoring on future space missions.
“Biosensors are a class of synthetic biology tools with immense potential for spaceflight applications in contaminant detection, environmental monitoring, and point-of-care diagnostics,” said Selin Kocalar, student winner of Genes in Space 2021. “This investigation seeks to validate their use aboard the space station. If it is successful, Genes in Space-9 will lay the foundation for downstream applications of biosensors for space exploration and resource-limited settings on Earth.”
Genes in Space, an annual research competition, challenges students in grades 7 through 12 to design
Biopolymer Research for In-Situ Capabilities looks at how microgravity affects the process of creating a concrete alternative made with an organic material and on-site materials such as lunar or Martian dust, known as a biopolymer soil composite (BPC). Using resources available where construction takes place makes it possible to increase the mass of the construction material and, therefore, the amount of shielding.
“Astronauts on the Moon and
BPCs also could offer an environmentally friendly concrete alternative for making structures on Earth. In 2018, concrete production represented 8% of global carbon emissions. BPC material has zero carbon emissions and can be made from local, readily available resources, which also simplifies supply chains. This experiment is a part of NASA’s Student Payload Opportunity with Citizen Science (SPOCS) program, which provides students enrolled in institutions of higher learning the opportunity to design and build an experiment to fly to and return from the International Space Station.
These are just a few of the hundreds of investigations currently being conducted aboard the orbiting laboratory in the areas of biology and biotechnology, physical sciences, and Earth and space science. Advances in these areas will help keep astronauts healthy during long-duration space travel and demonstrate technologies for future human and robotic exploration beyond low-Earth orbit to the Moon and Mars through NASA’s Artemis program.