Together, the teams used the device’s powerful edge processing capability to apply a sophisticated machine learning (ML)-based object recognition model and quickly analyze images of various scientific experiments on orbit. As a first step on this path, Axiom Space and AWS worked together to integrate and operate an AWS Snowcone device on the International Space Station as part of the Axiom Mission 1 (Ax-1) in April 2022. In order to support a thriving global space economy in low-Earth orbit, Axiom Station will require cloud-based technology to quickly and reliably analyze data on orbit, closer to where the data is collected, even when operating with limited bandwidth and connectivity. We remain excited to collaborate with AWS on advancing the state of the art of cloud infrastructure on-orbit as we build a multi-cloud and multi-user environment for our future space station customers.” Going all-in on enterprise IT needs provides us the necessary cloud services foundation on Earth to support our engineering, operations, and business teams as they build Axiom Station and the markets it will serve. Axiom Space and AWS are also collaborating on the development and demonstration of in-space cybersecurity solutions that set the foundation for operating a cybersecure Axiom Station.Ĭhristian Maender, EVP of Space Commercialization for Axiom Space said, “We are very excited to expand our collaboration with AWS. These include cutting-edge scientific research and discovery that Axiom Space supports on-orbit to benefit new pharmaceuticals development, stem cell research, regenerative medicine, and other areas of study in the microgravity environment. Once astronauts are more adequately prepared and protected for space travel, that means we can travel further than we ever have before.In parallel to going all-in on AWS for enterprise IT needs, Axiom Space and AWS will continue to collaborate on validating cloud-based hardware and software capable of supporting in-space workloads. For example, if researchers can understand the damage caused by ionized radiation to astronauts’ DNA, they might be able to engineer methods of protecting them from those dangers. The news has some very big implications for long-term space travel. "Therefore, which specific DNA-repair strategies are employed by the body in space may be particularly important." Furthering Space Travel "Astronauts traveling outside of Earth's protective atmosphere face increased risk of DNA damage due to the ionizing radiation that permeates space," said a press release from PLoS regarding the findings. The findings will help researchers better understand how DNA can (or can’t) repair itself during space travel. The scientists would use the CRISPR technology to create extremely precise damage to the yeast DNA strands and then observe how it repaired itself. The researchers were also able to develop a new technique for studying DNA repair in space using yeast cells. However, the findings were finally published last Wednesday in the journal PLoS ONE. The experiment itself actually occurred in 2019. The team of researchers were able to leverage CRISPR-Cas9 aboard the ISS, and show how they can study the impact of microgravity on DNA repair and damage, according to Engadget. CRISPR on the ISSĪstronauts aboard the International Space Station (ISS) has successfully leveraged CRISPR gene editing in space for the first time ever. This can help humans travel further and further into space.
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