18 highlights from an 18-day mission on the International Space Station  

1. The Axiom Mission 3 (Ax-3) crew spent 18 days, about 435 hours, aboard the International Space Station (ISS) and orbited Earth approximately 346 times, covering about 9.1 million miles.

Ax-3 Commander Michael López-Alegría, Pilot Walter Villadei, Mission Specialist Alper Gezeravcı, and Mission Specialist Marcus Wandt, embarked on their awe-inspiring journey to the orbiting laboratory at 4:49 p.m. ET on Jan. 18. They flew to space aboard a SpaceX Dragon, launched by a Falcon 9 rocket from NASA’s Launch Complex 39A at the Kennedy Space Center in Florida.

After approximately 36-hours of spaceflight, the Dragon spacecraft and Ax-3 crew docked with the International Space Station at 5:42 a.m. ET on Jan. 20, while soaring over the Pacific Ocean.

Eighteen days later, the crew undocked from the ISS at 9:20 a.m. ET on Feb. 7 to begin their homeward journey, carrying with them a lifetime of unforgettable memories and invaluable scientific data.

2. Longest Axiom Space private astronaut mission

The Ax-3 mission holds the record as the longest Axiom Space Private Astronaut Mission (PAM) to the ISS. With 18 days docked to the station and a spaceflight duration of nearly 22 days. Axiom Mission 1 (Ax-1) concluded after 17 days.

These commercial missions are building the human experience, paving the way for future human spaceflight activities in low-Earth orbit (LEO).

3. Ax-3 was the first all-European commercial astronaut mission to the space station

In a historic venture, three countries – Italy, Türkiye, and Sweden through the European Space Agency (ESA) – united for Ax-3, with Axiom Space’s Chief Astronaut and Commander Michael López-Alegría leading the commercial mission, representing both the U.S. and Spain as a dual-citizen. The Ax-3 pilot was Italian Air Force Col. Walter Villadei, and the two mission specialists were Alper Gezeravcı of Türkiye and ESA project astronaut Marcus Wandt of Sweden. This all-European commercial astronaut mission showcased an unprecedented level of collaboration. As we unite to explore, we also celebrate the power of bridging cultural divides to advance human knowledge and prosperity.

4. Ax-3 was the first commercial spaceflight mission made up of government and ESA-sponsored national astronauts

Ax-3 Pilot Walter Villadei and Mission Specialist Alper Gezeravcı were both government-sponsored astronauts with Villadei representing the Italian Air Force and Gezeravcı representing Türkiye. Mission Specialist Marcus Wandt represented Sweden as an ESA-sponsored project astronaut. Together, they proved that space knows no boundaries — where nations converge and unite to explore.

Ax-3 represents a ground-breaking venture that provides new pathways to access to the orbiting laboratory and perform microgravity research, technology demonstrations, and outreach activities.

5. Mission Specialist Marcus Wandt blazed a trail as ESA’s first project astronaut  

ESA partnered with Axiom Space to send its first project astronaut to space, Marcus Wandt of Sweden. ESA’s project astronaut concept was introduced during its astronaut selection in 2022.

Project astronauts are hired as ESA staff on a fixed-term contract and have posts that are linked to a specific flight or project. These assignments can include missions of opportunity where ESA or its Member States want to send a European to space. The length of a project astronaut’s contract is directly connected to the duration of their mission.

6. First Turkish astronaut went to space 

For Türkiye, Ax-3 represents a beacon of national pride as Mission Specialist Alper Gezeravcı etched his name in history as the first-ever Turkish astronaut. Türkiye sent the first Turkish astronaut to space as part of a larger effort to expand the country’s space exploration capabilities and establish a national human spaceflight program. As a fighter pilot with the Turkish Air Force, Gezeravcı has 15 years of flying experience on multiple aircraft and served as a captain with the Turkish Airlines for seven years. Through this mission, Gezeravcı inspired generations and fueled Türkiye’s pursuits in human spaceflight and microgravity research.

7. Italy establishes role in the new era of commercial spaceflight

Italy’s involvement in Ax-3 has not only fortified its rich legacy in space exploration but also paved the way for groundbreaking scientific and technological advancements. This whole-of-country endeavor, led by the Italian Air Force, and supported by governments, institutions, and industries, is fueling Italy’s willingness to strengthen its role as a player in the burgeoning space economy.

Ax-3 provided Italy with a platform to seize opportunities presented by the commercial space industry. This has enabled Italy to accomplish significant goals in research and innovation, while continuing promoting the nation’s commitment towards safe and effective access to space.

8. Ax-3 commander becomes the first astronaut to fly in SpaceX’s Dragon spacecraft for a second time

Michael López-Alegría commanded Axiom Space’s first private astronaut mission to the ISS and Ax-3 marked his second flight aboard a SpaceX Dragon, making him the first astronaut to have this unique distinction.

9. Ax-3 astronauts performed 54 different experiments

The Ax-3 crewmembers performed scientific experiments and demonstrations in LEO that were of high national importance. During the mission, they successfully completed a total of 54 research activities — to include 39 conducted aboard the space station — focusing on life, physical and Earth science, human research, and technology demonstrations.

Axiom Space partnered with many scientific organizations to continue understanding the effects of spaceflight on the human body, as well as explore opportunities of applied research in space to benefit health and medical treatments on Earth.

10. Crew conducted a total of 28 outreach and media engagements

The Ax-3 crew actively engaged with the global community through 28 media and outreach events. These interactions involved news outlets, government officials, organizations, and key stakeholders from their countries. Notably, nine of these engagements were dedicated to educating and inspiring hundreds of students worldwide.

12. First time studying metastatic breast cancer organoids on ISS

Led by the Sanford Stem Cell Institute, the Ax-3 crew conducted a study on metastatic breast cancer (breast cancer that spread to other parts of the body), by investigating 3D structures called organoids — cancer organoids from patients with a rare and aggressive form of breast cancer flew for the first time on Ax-3. The research conducted during the mission showed that the organoids, which included a bone marrow component to model the immune system, tripled in size in microgravity compared to growth rates seen on the ground. The results from this project, which has previously flown on Ax-1, Ax-2, and now Ax-3, are helping to identify a cancer “kill switch” (an RNA-editing enzyme) that can prevent cancers from growing and multiplying. The suite of experiments on Axiom Space missions are testing drugs on orbit that are FDA-approved for cancer, as well as a new cancer drug that is under development.

The team plans expanded studies on upcoming Axiom Space missions to continue this important work to accelerate understanding of the cancer disease process and develop drugs that can be used to treat patients in need.

13. ItAF conjunction warning system demonstrated on orbit for first time  

Developed by the Italian Air Force (ItAF), the ISOC system (Italian Space Operations Centre) provides an updated space object catalogue and state-of-the-art algorithms for detecting potential events such as collisions. This system was operated in space for the first time during the Ax-3 mission as a proof-of-concept demonstration, showcasing how the system could provide near real-time collision warnings with minimal Earth ground support or even autonomously. The Ax-3 crew also tested the capability to monitor solar activity and report onboard events related to space weather by means of the ISOC web portal.

14. Türkiye brought its agricultural endeavors to space

Advanced genetic editing techniques were applied to plants to explore how altering the plant’s stress responses could improve agricultural practices on Earth, in space, or on other terrestrial bodies.

Microalgae’s response to microgravity and hardware that can culture it in space could help develop new life support systems, food, and even fuel for future space exploration applications.

This work builds on previous microgravity investigations showing how microgravity affects the growth, movement and genetics of plants, and could provide valuable insights into plant adaptation to extreme environments and help develop more resilient crops for agriculture.

15. Research was conducted to better understand formation of proteins implicated in Alzheimer's disease

Beta amyloid proteins, implicated in Alzheimer’s Disease, were ‘activated’ for different lengths of time on orbit, allowing researchers to understand how microgravity affects the folding and aggregation of the proteins over time in ways not possible on Earth. This experiment, promoted by Italian Space Agency (ASI), could provide insight into the formation of these proteins in neurodegenerative disorders and offer new avenues for therapeutic development.

16. Progress made on understanding brain activity in space

During the Ax-3 mission, Mission Specialist Marcus Wandt documented his stress levels and stress recovery rate, tested his cognitive performance, and monitored his brain activity with a headcap that can record neural activity. Cortivision, the company that created the headcap, is developing innovative applications to analyze neural activity in space and on Earth using functional near infrared spectroscopy (fNIRS).  Using the fNIRS cap aboard the ISS helps researchers better understand the impact of microgravity on brain activity and how to optimize human health and performance of astronauts on missions beyond Earth. 

Learn more about this Ax-3 study from Axiom Space Chief Scientist Dr. Lucie Low and Cortivision Chief Operating Officer Wojciech Broniatowski, here.

17. GiGi became a second-time flyer

Axiom Space and Build-A-Bear Workshop partnered for a second time to fly a furry fifth crew member alongside the Ax-3 astronauts. The teddy bear, named GiGi, took flight a second time, as the Ax-3 mission’s zero-gravity indicator wearing Axiom Space’s next-generation spacesuit. As the fifth crewmember of Ax-3, GiGi’s mission was to inspire children around the world to learn about space and consider careers in STEAM.  

18. Ax-3 represented important milestones for Italy, Türkiye, and Sweden

Ax-3 represented an important milestone for Türkiye as the nation commemorated the centennial anniversary of the Turkish Republic on October 29, 2023. On March 28, 2023, the Italian Air Force celebrated its centennial anniversary as one of the oldest air forces in the world.  

Sweden celebrated five centuries as an independent nation on June 6, 2023. Marcus Wandt became the second Swedish ESA astronaut in history to fly to the space station, embodying opportunity and freedom to explore the unknown.

Applications for future space habitats, cancer research, and biomanufacturing are among investigations headed to the International Space Station on second all-private astronaut mission to the orbiting laboratory

Axiom Space, a leader in human spaceflight and architect of the world’s first commercial space station, announced today further details on the groundbreaking research planned for the upcoming Axiom Mission 2 (Ax-2) mission to the International Space Station (ISS) – including initial studies focused on developing future therapeutic applications, studying immune dysfunction in tumor organoid models that can help to predict and prevent cancer, understanding how commercial spaceflight crew members adapt to microgravity, and exploring how weather modification works in low-gravity conditions.

Axiom Space’s crew of four astronauts will conduct more than 20 different experiments while aboard the space station. Data collected in flight will impact understanding of human physiology on Earth and on orbit, as well as establish the utility of novel technologies that could be used for future human spaceflight pursuits and improving life on Earth.  

Unique to this mission, there is a strong focus on projects developing in-space biomanufacturing applications. Four experiments flying on Ax-2 are part of larger partnerships between Axiom Space and academic and industrial partners to perform proof-of-concept studies for in-space biomanufacturing, which has the potential to address current roadblocks in regenerative medicine, drug development, and technology advancement.

"It is exciting to see the wide range of important research that will be conducted on this mission and to be taking the first steps in developing future in-space manufacturing applications for some of our biomedical products," said Christian Maender, executive vice president of in-space solutions at Axiom Space. "We are pleased to have the opportunity with our private astronaut missions to advance this important work as we build a future commercial space economy. 

Axiom Space’s Chief Scientist Dr. Lucie Low echoed Maender’s excitement for the science on the mission, “We’re delighted to support these scientific and research and manufacturing projects on the Ax-2 mission, as well as provide opportunities to conduct research in microgravity for partner countries and nations with limited access.” said Low. “The projects flying on this mission will advance the use of low-Earth orbit as a manufacturing platform for technologies that could advance human health on Earth, add to our understanding of health in space, and demonstrate how to best operate safely and effectively on orbit.”

The Ax-2 crew members are Commander Peggy Whitson and Pilot John Shoffner, both from the United States, and Mission Specialists Ali Alqarni and Rayyanah Barnawi representing the Kingdom of Saudi Arabia.

A SpaceX Falcon 9 rocket will launch the Ax-2 crew aboard a Dragon spacecraft to the International Space Station no earlier than spring 2023 from Launch Complex 39A at NASA’s Kennedy Space Center in Florida. 

Select Ax-2 Mission Investigations 

The following are some of the investigations and demonstrations flying on Ax-2, more information will be available on axiomspace/ax2-research.

DNA nano therapeutics in collaboration with University of Connecticut, Eascra Biotech, and Advanced Solutions Life Sciences (ASLS)

DNA inspired Janus-based nanomaterials are biologically inspired nanotubes that can be used for therapeutic mRNA delivery or other therapeutics at room temperature, and as a first-in-kind injectable scaffold for cartilage repair. This project will leverage microgravity to optimize the assembly of DNA-based nanomaterials for multiple therapeutic uses and ultimately develop standards for in-space manufacturing of nanomaterials for a wide range of therapeutic applications. Axiom Space is contributing to the NASA-funded In-Space Production Applications project through the Ax-2 mission.

Stellar stem cells in collaboration with Board of Governors Regenerative Medicine Institute at Cedars-Sinai

This project seeks insights into the impact of microgravity on producing stem cells and stem cell-derived products in space. Using space to evaluate the steps used in terrestrial manufacturing to reprogram skin cells (fibroblasts) into stem cells capable of producing a variety of tissue types (heart, brain, and blood), could support regenerative medicine uses on Earth.  Axiom Space is contributing to the NASA-funded In-Space Production Applications project through the Ax-2 mission.

Cancer in low-Earth orbit in collaboration with Sanford Stem Cell Institute at UC San Diego

As a follow-on project flown on Ax-1 (Modeling Tumor Organoids), this effort will expand the tumor organoid model to include triple-negative breast cancer cells in order to study immune dysfunction and drug challenge with countermeasures for ADAR1-fueled cancer proliferation and immune evasion: fedratinib and rebecsinib, for the further development of stem cell models that can help predict and prevent cancer. These models can be tools for detection of and therapies for pre-cancer, cancer, and a variety of other diseases on Earth. This project is part of the expanded Integrated Space Stem Cell Orbital Research (ISSCOR) collaboration between the Sanford Stem Cell Institute, JM Foundation, and Axiom Space.

Space tissue and regeneration in collaboration with Wake Forest Institute for Regenerative Medicine and the RegenMed Development Organization (ReMDO)

Bioengineered liver and kidney tissue constructs will be sent to space to assess the impact of microgravity on vascularization of thick tissues. If successful, this platform technology and approach could lead to the in-space bioengineering of ‘building blocks’ of tissue that can serve as a bridge to transplants in patients awaiting a limited supply of donor organs. This project is part of the Axiom Space collaboration with Wake Forest Institute for Regenerative Medicine and the ReMDO to develop an In-Space Biomanufacturing Hub for regenerative medicine. 

Space hematopoietic stem cell aging in collaboration with Sanford Stem Cell Institute at UC San Diego

In this project, the activity of DNA and RNA-editing enzymes involved in mutations that may be related to development of immune dysfunction-related disease states and cancer will be evaluated by analyzing blood samples taken from the crew before, during, and after spaceflight. This will help better understand changes in editing activity of these enzymes in blood stem cells due to spaceflight. This project is part of the expanded Integrated Space Stem Cell Orbital Reseach (ISSCOR) collaboration between the Sanford Stem Cell Institute, JM Foundation, and Axiom Space.

mRNA response and stability in Space in collaboration with King Faisal Specialist Hospital & Research Center, Saudi Space Commission (SSC)   

The set of experiments investigates the inflammatory response of human immune cells in microgravity, specifically the changes in mRNA decay, a process that can turn inflammation off. Moreover, response to therapy is mimicked by utilizing the same cellular model. The crew will take RNA samples for analysis on the ground, where the investigators will monitor RNA expression patterns, and excitedly thousands of mRNA half-lives will be measured. Results could contribute to a better understanding of space health and uncover biomarkers or potential therapies for inflammatory diseases in both Space and Earth. The project is funded by SSC, where one of their astronauts will perform the experiments at the ISS.

Nebula human research biosamples and biodata in collaboration with Nebula Research & Development Company, Keele University, and Weill Cornell Medicine

This portfolio of projects will look at how humans adapt and respond to spaceflight to better understand human physiology in microgravity, which will contribute to our understanding of how to keep humans healthy in space. Projects utilizing novel neuroscience tools include measuring blood flow to the brain and the brain’s electrical activity, assessing intracranial pressure by non-invasive assessment of the pupil of the eye, and monitoring changes in the optic nerve over time. Improved monitoring of neurological health may help make spaceflight safer in the future and allow for the development of rapid, non-invasive monitoring, as well as early interventions and the development of countermeasures. Blood and bio-sample specimens will also be taken to examine multi-omic biomarkers related to spaceflight and also to map changes in the length, structure, and epigenetics of chromosomes and telomeres. This project is in collaboration with the Saudi Space Commission.

TRISH essential measures

The Translational Research Institute for Space Health (TRISH) is developing a battery of tests to be completed by the crew that will inform how commercial spaceflight crew members adapt to microgravity and how countermeasures can be developed to keep crew healthy and enable peak performance during missions. This battery of tests will include physical assessments, questionnaires, taking biological samples from the crew, and wearing devices that sense and measure physiological responses to spaceflight. The tests will be analyzed to determine how quickly and how well crew adapt to moving in space, study how the eye changes during spaceflight, how well the crew can perform cognitively demanding tasks, and what changes the body undergoes in microgravity. Measurements will be added to TRISH’s EXPAND (Enhancing eXploration Platforms and ANalog Definition) program, which seeks to increase understanding of human health and performance through data collected from commercial spaceflight participants.

Gravity loading countermeasure in collaboration with MIT

The Gravity Loading Countermeasure Skinsuit is an intravehicular activity suit for astronauts that has been developed to simulate some of the effects of Earth’s gravity and mitigate some of the physiological effects of microgravity, including spinal elongation, muscle atrophy, and sensorimotor changes. This wearable system is intended to supplement exercise during future missions to the Moon and Mars and to further attenuate microgravity induced physiological effects in future low-Earth orbit mission scenarios. The purpose of this study is to characterize the Skinsuit and its physiological effects on a short-duration low-Earth orbit mission.

Multifunctional shielding polymer demo in collaboration with Cosmic Shielding Corporation

A newly developed polymer nanocomposite, commercially known as Plasteel, is being tested for its ability to protect against space radiation, which consists of heavy charged particles and secondary photons, electrons, and neutrons. During the Ax-2 mission, the newly developed nanocomposite will be tested in the internal radiation environment of the ISS to validate the shielding ability of the material for both electronics and future astronauts. CSC's Plasteel has been tested at particle accelerator facilities on Earth, and this mission will represent the first major on-orbit demonstration of the technology.

Cloud seeding in microgravity in collaboration with King Fahd University of Petroleum & Minerals (KFUPM), Saudi Space Commission, and Nanoracks

Cloud seeding is the process of artificially generating rain by implanting clouds with particles such as silver iodide (AgI) crystals. Cloud seeding has been adopted by many countries to increase precipitation in areas suffering from droughts. In this experiment, cloud seeding will be examined for the first time in space under microgravity conditions. Moist air and AgI crystals will be mixed in a reaction chamber to examine the possibility of nucleation, where water vapor condenses on AgI crystals to form water droplets.  The outcome of this experiment will help develop weather control technology to generate artificial rain in future human settlements on the Moon and Mars.

Imaging of Lightning and Nighttime Electrical Phenomena from Space (ILAN-ES) in collaboration with the Rakia Mission

This night-time experiment will image thunderstorms, lightning, and transient luminous events (TLEs) known as sprites, blue jets, and elves. These electrical phenomena occur at high altitudes above thunderstorms and are a marker of severe weather and extremely powerful lightning, called superbolts. By taking video images from the ISS Cupola, the interactions between the upper and lower atmosphere can be studied. Observations from space will be augmented by ground-based observations conducted by international research groups and schoolchildren in the Middle East, Africa, Asia, and the Americas.

Axiom Space communication systems technical demonstration

The Axiom Space Communications System payload will develop and test alternative ways for onboard communication to be used with a type of mobile device. This test will potentially allow crew members more flexibility to communicate with mission control and loved ones on the ground.

Axiom Space imagery processing and collection 

Axiom Space is investigating the use of an automatic, wireless transfer application tool for downlinking imagery. This demonstration will provide insight on the feasibility and efficiency of this tool for future use on Axiom Station to reduce crew time and ground time on image transferring, allowing the crew and ground more time to focus on science and outreach.

Stowage Tracking & Inventory Intelligent Video System (STIIVS)

Axiom Space’s STIIVS uses computer vision to identify and track items for inventory management, stowage location tracking, and associated analytics. Results could provide insight into the feasibility and efficiency of this tool for use on Axiom Habitation Module 1 (AxH1) once it is attached to the ISS.

Odor visualization in collaboration with Japan Manned Space Systems Corporation (JAMSS)

JAMSS Odor Visualization is a tech demo developed by JAMSS that will use two QCM (quartz crystal microbalance) sensors to detect odors in a low-Earth orbit pressurized environment. The data collected will then be used to visualize the detected odors and could improve the quality of life for space travelers with future applications.

DreamUp DreamKits in collaboration with Nanoracks

The STEM-focused experiments are conducted in microgravity to educate students on the unique environment of the Space Station. These three visual experiments will demonstrate differences in fluid behavior on Earth and in microgravity, explore the aerodynamic behavior of different kite shapes on the ISS, and show effects of the vacuum of space on heat transfer. Students across the Kingdom of Saudi Arabia will participate in ground-based experiments on Earth to gather comparison data with custom-built kits and, in the case of Space Kites, the general public can gather their own data using household materials and instructions provided by DreamUp. This project is in collaboration with the Saudi Space Commission.

Axiom Space and its partners will be releasing more details on the research conducted on Ax-2 in the weeks to come, here: axiomspace.com/ax2-research.