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Astronaut

An astronaut is a person trained by a program to command, pilot, or serve as a crew member of a , with the term generally reserved for those who have reached . The word "astronaut" originates from terms astron () and nautes (), translating to "star sailor," and it specifically refers to crew members launched aboard for space missions. Human spaceflight began in the late 1950s amid the between the and the , with Soviet cosmonaut becoming the first person in space on April 12, 1961, aboard 1. 's inaugural class of astronauts, known as the , was selected in 1959 from military test pilots, marking the start of the U.S. human spaceflight program. Landmark achievements followed, including the first American orbital flight by in 1962 and the mission in 1969, where and became the first humans to walk on the Moon. As of 2025, more than 700 individuals from 47 countries have flown to space, contributing to missions ranging from suborbital flights to long-duration stays on the (ISS). Astronauts are selected through highly competitive processes that prioritize candidates with advanced degrees, exceptional physical and psychological fitness, and relevant experience such as piloting or ; for instance, NASA's selection drew over 12,000 applicants for just 10 spots. Once chosen, they undergo two years of intensive training, including simulations, survival skills, spacewalk practice, and mission-specific preparation for environments like the ISS or lunar operations. In their roles, astronauts conduct scientific research—such as studies on human physiology and materials in microgravity—operate systems, perform extravehicular activities (EVAs or spacewalks), and collaborate internationally on programs like , aimed at returning humans to the Moon and preparing for Mars exploration. Since 2000, the ISS has hosted over 290 visitors from 26 nations, fostering advancements in , , and sustainable space habitation; in November 2025, it marked 25 years of continuous human presence. As of 2025, NASA's active astronaut corps includes 48 flight-eligible members, with ongoing selections to support commercial partnerships and deep-space ambitions, while international agencies like the (ESA) and continue to train diverse crews for collaborative ventures. Astronauts not only drive scientific progress but also inspire global public engagement through outreach, embodying humanity's enduring quest to explore the .

Definition and Terminology

Core Definition

An astronaut is a person trained and selected by a human spaceflight program to serve as a commander, pilot, or crew member aboard a spacecraft, enabling the operation and execution of space missions. The term originates from the Greek words astron (star) and nautes (sailor), literally meaning "star sailor," and applies to individuals launched into space as part of professional crews. This role encompasses responsibilities such as vehicle control, scientific experimentation, and mission coordination during orbital or deep-space flights. Professional astronauts are distinguished from spaceflight participants, such as space tourists, who are non- individuals carried aboard launch or reentry vehicles without undergoing the rigorous or operational duties required of certified members. Under U.S. (FAA) regulations, spaceflight participants do not qualify as astronauts or , as they lack the designation and preparation for active roles. This separation ensures that only trained professionals handle critical functions, while participants engage in passive travel. Internationally, the role of astronauts is enshrined in the 1967 Outer Space Treaty, which designates them as "envoys of mankind" in outer space, obligating signatory states to provide all possible assistance in cases of accident, distress, or emergency landing. Article V of the treaty further requires the safe and prompt return of astronauts to the state of registry of their spacecraft and mandates mutual aid among astronauts from different nations during space activities. This framework underscores the cooperative and humanitarian aspects of human spaceflight, transcending national boundaries. The astronaut role has evolved from its origins in military test pilots, who dominated early selections for their expertise in high-risk vehicle handling, to a broader cadre of specialists including scientists, , physicians, and international partners to support complex, multidisciplinary missions. 's initial 1959 cohort consisted entirely of test pilots, but subsequent groups incorporated mission specialists focused on scientific and technical operations, reflecting the shift toward sustained and international collaboration. Today, astronaut candidates draw from diverse fields to address the demands of programs like , emphasizing adaptability across piloting, , and disciplines.

International Terms

The term "astronaut" derives from the Greek words astron () and nautes (), literally meaning " ," and was coined in scientific speculation as early as 1929 before gaining popularity through in the mid-20th century. It was formally adopted by the U.S. National Aeronautics and Space Administration () in 1958 as the official designation for individuals trained for , and it remains the standard term used by and most Western space agencies, including those in and , to describe professionals who travel beyond Earth's atmosphere. This nomenclature reflects a focus on stellar , aligning with the exploratory ethos of early American space programs. In contrast, the Russian space agency employs the term "cosmonaut," derived from the Greek kosmos () and nautes (sailor), meaning "universe sailor." The word entered usage in 1959, coinciding with the Soviet Union's preparations for manned under the program, and was first applied to during his historic orbital flight in 1961. This term underscores the Soviet emphasis on cosmic exploration and has persisted through 's operations, distinguishing Russian spacefarers from their Western counterparts in international discourse. For China's space program, managed by the (CNSA), the official term is yuhangyuan (宇航员), which translates from as "space navigator" or "universe traveler," reflecting a direct linguistic focus on navigation through the . An English-language , "taikonaut," emerged in 1998 from the Mandarin taikong () combined with the Greek -naut (sailor), and gained traction in following China's first manned in 2003 with the Shenzhou . While taikonaut is not officially endorsed by CNSA, it has become a common informal descriptor for Chinese space personnel, paralleling the cultural adaptations seen in other programs. The (ESA) occasionally uses "spationaut" (or spationaute in ), derived from the Latin spatium (space) and nautes (sailor), meaning "space sailor," particularly in French-speaking contexts to denote European astronauts. This term entered limited usage in the as ESA expanded its astronaut corps, though "astronaut" predominates in official English communications. Similarly, Malaysia's Angkasawan program, launched in 2007 to send its first national to the , adopted angkasawan from , directly meaning "astronaut" or "space traveler," to culturally localize the role within its national space initiatives. These variations highlight how spacefaring nations adapt terminology to blend languages with classical roots, fostering in global space endeavors.

Historical Development

Early Spaceflight Milestones

The era of early human spaceflight began with the Soviet Union's Vostok 1 mission on April 12, 1961, when cosmonaut Yuri Gagarin became the first human to reach space, completing a single orbit of Earth in a 108-minute flight aboard the Vostok spacecraft. This pioneering achievement demonstrated that humans could survive the rigors of launch, weightlessness, and reentry, paving the way for subsequent orbital missions. In response, the accelerated its , initiated in 1958 and spanning until 1963, to achieve manned suborbital and orbital flights using one-person capsules launched by and Atlas rockets. The program's first success came on May 5, 1961, with astronaut Alan Shepard's suborbital flight aboard Freedom 7, lasting 15 minutes and reaching an altitude of about 187 kilometers, marking the initial American step into space. Building on this, became the first American to orbit Earth on February 20, 1962, during the Friendship 7 mission, completing three circuits in under five hours and confirming the viability of human-piloted orbital operations. The Soviet program advanced gender diversity in space with cosmonaut Valentina Tereshkova's flight on June 16, 1963, where she became the first woman in space, orbiting Earth 48 times over nearly 71 hours and conducting observations that contributed to biomedical data on female physiology in microgravity. The culmination of early lunar ambitions arrived with NASA's , which achieved the first human on July 20, 1969, during , as astronauts and descended in the to the Sea of Tranquility, with Armstrong uttering the iconic words upon his first step: "That's one small step for man, one giant leap for mankind." Over the subsequent years, six Apollo missions (11 through 17, excluding the aborted ) successfully landed on the between 1969 and 1972, enabling a total of 12 astronauts—six pairs from those crews—to conduct extravehicular activities, collect 382 kilograms of lunar samples, and perform scientific experiments that expanded knowledge of the Moon's geology and environment. The advanced orbital station technology with the program, launching in 1971 as the world's first , hosting crews for up to 23 days despite the tragic loss of the crew in 1971. A landmark in international cooperation was the Apollo-Soyuz Test Project in July 1975, where American astronauts Thomas Stafford, Vance Brand, and docked with the Soviet Soyuz 19 spacecraft crewed by and Valery Kubasov, marking the first joint U.S.-Soviet space mission and symbolizing during the . Transitioning from lunar exploration to sustained orbital presence, the United States launched in May 1973 as its first , repurposed from a upper stage and serving as an orbital laboratory until 1974. Three crews of three astronauts each visited across missions lasting 28, 59, and 84 days, respectively, conducting over 270 experiments in fields such as , resources, and human adaptation to long-duration , while demonstrating repairs to the station's damaged solar arrays and micrometeoroid shield during the initial crew's arrival.

Modern Achievements and Records

The , operational from 1981 to 2011, marked a significant era in technology, conducting 135 missions that carried a total of 355 individuals into orbit. These flights facilitated the deployment of satellites, conducted scientific experiments, and supported the construction of the , with notable milestones including the first flight of an American woman, , aboard in 1983. Another highlight was the planned inclusion of as the first teacher in space on in 1986, though the mission ended tragically in . The (ISS), continuously inhabited since 2000 following its assembly beginning in 1998, has hosted 290 visitors from 26 countries as of November 2025, fostering unprecedented international collaboration in microgravity research. This era has seen records for long-duration stays, including Russian cosmonaut Valeri Polyakov's 437-day mission on the predecessor station from 1994 to 1995, which remains the longest single human spaceflight to date and informed ISS operations. Private sector advancements have democratized access to space since the , with 's Crew Dragon achieving its first operational crewed flight in May 2020 under NASA's , enabling routine astronaut transport to the ISS. Suborbital tourism emerged through Virgin Galactic's flights, starting with commercial passenger missions in 2023, and Blue Origin's , which conducted its inaugural crewed suborbital flight in July 2021. A pivotal orbital milestone was the mission in September 2021, the first all-civilian crewed flight to reach aboard a Crew Dragon, raising funds for pediatric research while demonstrating private capabilities for extended missions. Diversity in astronaut selection has expanded notably in modern spaceflight, with becoming the first African American in space on in 1983. Age records include John Glenn's return to space at 77 years old on in 1998, the oldest person to fly at that time, and Wally Funk's suborbital flight at 82 aboard Blue Origin's in 2021, setting the record for the oldest woman in space. Regarding LGBTQ+ representation, was posthumously identified in 2012 as the first known LGBTQ+ astronaut, having flown in 1983, though public acknowledgment during active careers has grown in the 2020s. In terms of distance, the mission in 1970 achieved the farthest human venture from at approximately 400,000 km, a record contextualized in modern efforts to push boundaries further. The ongoing aims to return humans to the lunar surface, with targeted for a landing in 2027, building toward sustainable presence on the and preparation for Mars.

Selection and Preparation

Candidacy Criteria

Candidacy criteria for astronauts vary by space agency but generally emphasize citizenship, advanced in , , , or (STEM) fields, relevant professional experience, and rigorous physical and medical to ensure safe performance environments. These requirements have evolved since the earliest selections, such as NASA's group of military test pilots, to include more diverse professional backgrounds while maintaining high standards for mission success. The National Aeronautics and Space Administration () requires candidates to be U.S. citizens with a in a field from an accredited institution, or equivalent qualifications such as two years toward a doctoral program, a , or completion of a school program. Applicants must also demonstrate at least three years of related professional experience following the degree or accumulate 1,000 hours of pilot-in-command time in , with medical residents counting residency toward experience. Physically, candidates must pass NASA's long-duration flight astronaut physical, including distant and near correctable to 20/20 in each eye and not exceeding 140/90 in a sitting position. Russia's Roscosmos State Corporation for Space Activities sets similar educational and experiential thresholds for cosmonauts, requiring Russian citizenship, a higher education degree in engineering, sciences, aviation, or related fields, and relevant professional experience in the specialty. Candidates must be no older than 35 years at application and undergo comprehensive medical evaluations emphasizing physical fitness, with a focus on engineering proficiency to support spacecraft operations. The (ESA) mandates citizenship of an ESA member or associated state, along with a minimum in natural sciences, , , mathematics, or computer sciences, followed by at least three years of professional experience such as or clinical work. Fluency in English and knowledge of another language are essential for international collaboration, with physical fitness demonstrated via a equivalent to a private pilot license or higher; the maximum age at application is 50. China's National Space Administration (CNSA) prioritizes advanced degrees, preferably a or PhD in or related disciplines, drawing from diverse backgrounds including scientists, physicians, and engineers to support missions like the . Multilingual capabilities, particularly in English, aid potential international engagements, though selections often favor military pilots with technical expertise. Private space programs, such as those operated by , apply less rigid criteria compared to government agencies, prioritizing technical skills, adaptability, and problem-solving over formal . For missions like or flights, selections have included civilians from business, science, and engineering fields, with opportunities for self-funded participation to broaden access beyond traditional prerequisites. Selection processes are highly competitive, with typically choosing 10–12 candidates every few years from over 8,000–12,000 applicants; for instance, the 2021 class selected 12 from 12,000, while the 2025 class chose 10 from more than 8,000. Recent selections reflect a shift toward greater inclusivity, exemplified by 's 2025 astronaut candidate class, where women outnumbered men for the first time (six women and four men), aligning with broader efforts to diversify the corps.

Training Regimens

Astronaut training regimens typically commence immediately following selection as candidates, marking the beginning of an intensive multi-year preparation process designed to equip individuals with the technical, operational, and survival skills necessary for . At agencies such as , basic training lasts approximately two years and is conducted primarily at the in , where candidates learn core competencies including systems operations, handling, and extravehicular activities (EVAs), also known as spacewalks. This phase emphasizes hands-on instruction in the intricacies of vehicle controls, life support systems, and robotic manipulators like the Canadarm2 used on the (ISS), ensuring astronauts can perform complex tasks in isolated environments. Training incorporates simulations of mission scenarios to build proficiency in EVA procedures, where candidates practice donning spacesuits and maneuvering in simulated microgravity to repair or assemble orbital structures. Specialized simulations form a critical component of astronaut preparation, replicating the physical and environmental challenges of spaceflight to enhance safety and performance. The Neutral Buoyancy Laboratory at , a 6.2-million-gallon pool, allows astronauts to train for zero-gravity conditions during EVAs by suspending full-scale mockups of and station components underwater, providing realistic practice for tasks lasting up to eight hours. Centrifuge facilities simulate the high G-forces encountered during launch and reentry, with astronauts experiencing up to 8 Gs to acclimate to acceleration stresses and maintain cognitive function under duress, a practice reinstated for crews in recent years. Additionally, wilderness survival training, conducted over three days in remote areas like forests in or deserts in , teaches candidates essential skills such as building shelters, sourcing water, and signaling for rescue in the event of an off-nominal landing. For multinational missions like those to the ISS, cross-training at accommodates partners from agencies including , ESA, , and , fostering interoperability through shared simulations and joint exercises. Astronauts undergo language instruction at the 's Language Education Center, where personnel achieve conversational proficiency in Russian—essential for operations—while international counterparts learn English, supplemented by cultural modules to address communication nuances and team dynamics in diverse crews. This collaborative approach ensures seamless coordination during long-duration flights, with training emphasizing conflict resolution and shared protocols. In contrast, preparation for private astronauts, particularly through companies like , is more condensed, often spanning several months and totaling 700 to 1,000 hours focused on safety protocols, basic vehicle operations, and emergency response rather than exhaustive technical depth. For suborbital flights, such as those offered by commercial providers, training emphasizes passenger safety briefings and physiological adaptation over extended simulations, aligning with shorter mission profiles. By 2025, these programs have evolved to incorporate updates for emerging commercial orbital flights, including enhanced integration with Crew Dragon systems for missions like Axiom's Ax-4. Mission-specific tailoring further refines regimens to align with unique objectives, such as geological field training for lunar explorations under NASA's . Astronauts participate in analog missions in volcanic regions like Arizona's or Norway's lunar-like terrains, learning to identify samples, map craters, and document surface features to support scientific return during landings targeted for the late . This hands-on instruction, ramped up since 2023, equips crews to maximize sample collection efficiency while navigating hazards.

Operational Roles

Mission Duties

Astronauts undertake a range of critical responsibilities during space missions, encompassing vehicle operations, scientific research, and extravehicular activities to ensure mission success from launch through landing. These duties are divided among crew roles such as commander, pilot, and mission specialists, with the commander holding overall authority for crew safety, vehicle management, and mission objectives. In the pre-launch phase, astronauts perform final systems checks, including leak verifications on the and suits, while reviewing procedures and checklists to confirm readiness for ascent. During in-flight operations, pilots and commanders operate controls for navigation, orbital maneuvers, and with targets like the (ISS), where they monitor automated or intervene manually if required. procedures involve rapid response protocols, such as abort sequences or contingency maneuvers, to mitigate risks like system failures. Reentry duties include executing de-orbit burns, monitoring descent trajectories, and piloting the vehicle through atmospheric interface for a safe landing. Science officers and mission specialists conduct experiments in microgravity, focusing on fields like fluid physics—where phenomena such as behave differently without gravity—and , including studies on or protein crystallization to advance and . They also handle payload deployment, such as releasing small satellites from the ISS via systems like the Kaber deployer or , enabling orbit insertion for or technology demonstrations. Extravehicular activity (EVA), or spacewalks, forms a core duty for maintenance and repairs outside the , with astronauts donning suits capable of supporting 6 to 8 hours of activity in the vacuum of space. As of November 2025, the ISS has hosted 277 such EVAs since 1998, totaling over 1,800 hours, primarily for tasks like installing solar arrays, replacing power regulators, and upgrading communication systems. For emerging missions, astronauts adapt duties to new environments; in NASA's , crew members will pilot the to descend to and ascend from the lunar surface, conducting surface operations during approximately 6.5-day stays on the as part of a ~30-day mission. In Mars analog simulations like the Crew Health and Performance Exploration Analog (CHAPEA), participants perform operational tasks such as simulated surface walks, vegetable cultivation in controlled habitats, and robotic arm operations to mimic planetary exploration. These roles build on rigorous training to prepare for extended deep-space operations.

Ground and Support Functions

Astronauts play a vital role in pre-mission planning by developing experiment protocols, mission timelines, and plans to ensure and during spaceflights. These activities involve collaborating with engineers and to refine procedures for scientific , vehicle operations, and responses, often drawing on their prior flight to anticipate challenges. For instance, astronauts contribute to the integration of international payloads on the (ISS), customizing timelines to align with crew schedules and orbital constraints. A key ground support function is the capsule communicator (CAPCOM) role, traditionally filled by active-duty astronauts who relay critical information between mission control and crews in space. Positioned in the at NASA's , CAPCOMs provide real-time updates on technical data, weather conditions, and procedural adjustments, leveraging their expertise to interpret complex situations and maintain clear communication. This position, originating from the Apollo era, continues to be astronaut-exclusive to foster trust and shared understanding with orbiting crews. Astronauts also engage in extensive and efforts, inspiring in through appearances, lectures, and programs. NASA's Astronaut Appearances Office coordinates these engagements, where astronauts speak at schools, universities, and public events to share mission insights and encourage careers in space . Post-flight, they participate in debriefs to analyze mission , documenting physiological effects, equipment performance, and operational lessons to inform future training and protocols. In reserve capacities, astronauts support analog missions and unmanned tests to simulate extraterrestrial environments and validate technologies. For example, they contribute to the NASA-funded HI-SEAS program on , , by providing expertise in habitat operations and psychological factors for Mars preparation, helping evaluate crew dynamics in isolated settings. Additionally, they assist in ground testing of , such as reviewing telemetry from Artemis missions to refine launch procedures. With the rise of commercial , astronauts on private missions, such as Axiom Space's Ax-4 in 2025, perform comparable duties while supporting commercial objectives alongside NASA goals. Many astronauts progress to leadership roles, transitioning from flight assignments to management positions within space agencies or the private sector. , for instance, served as ISS commander during her tenure before retiring in 2018 and becoming vice president of human spaceflight at , where she commanded private missions like in 2023 and Axiom Mission 4 in 2025 and continued executive oversight into late 2025. This evolution allows experienced astronauts to shape program strategies and mentor emerging candidates.

Health and Physiological Effects

Spaceflight Risks

Astronauts face significant physical hazards from microgravity during , which leads to rapid loss at a rate of 1-2% per month in bones such as the hips and . This demineralization occurs due to the absence of gravitational loading, mimicking accelerated and increasing fracture risk upon return to . also develops quickly, with losses of up to 20% in leg muscles after just weeks in orbit, as the body adapts by reducing muscle mass no longer needed for locomotion against . Additionally, fluid shifts toward the head in microgravity cause Spaceflight-Associated Neuro-ocular Syndrome (SANS), resulting in vision impairment from edema and intraocular pressure changes affecting up to 70% of long-duration mission astronauts. Microgravity also contributes to cardiovascular deconditioning, including reduced blood volume, orthostatic intolerance, and diminished aerobic capacity, which can lead to fainting or exercise limitations upon return to Earth. Exposure to space radiation poses another major threat, primarily from galactic cosmic rays—high-energy particles from outside the solar system—and solar particle events from flares, which penetrate spacecraft shielding due to the lack of Earth's atmospheric protection. These ionizing radiations damage DNA, elevating the lifetime cancer risk; for instance, a six-month stay on the International Space Station typically exposes astronauts to 80-160 millisieverts, corresponding to an approximate 0.5-1% increase in fatal cancer probability. NASA limits career exposure to maintain the risk of exposure-induced cancer death below 3% at the 95th confidence interval, yet deep-space missions amplify this hazard beyond low-Earth orbit levels. Launch and reentry phases introduce acute mechanical stresses, with astronauts enduring G-forces up to 3-4g during ascent and deceleration, straining the cardiovascular system and potentially causing disorientation or injury if tolerances are exceeded. Vehicle failures compound these risks, as seen in the 1986 Challenger disaster, where a joint failure caused an explosion 73 seconds after liftoff, killing all seven crew members. Similarly, the 2003 Columbia accident resulted from wing damage during launch leading to structural breakup during reentry, claiming another seven lives due to the intense thermal and aerodynamic loads. Psychological hazards arise from the and confinement of environments, fostering , anxiety, and potential interpersonal conflicts within small crews over extended periods. Prolonged separation from and loved ones, combined with monotonous routines in enclosed habitats, can degrade mood and cognitive performance, with evidence from analog missions showing occasional team tensions that impair . For deep-space exploration, emerging risks include one-way communication delays of up to 20 minutes to Mars, complicating support and increasing demands on crews during emergencies. Extravehicular activities on the or Mars also expose astronauts to toxic dust; lunar regolith's sharp, electrostatic particles can irritate and eyes, potentially causing inflammation similar to . Martian dust, rich in perchlorates and fine silicates, heightens respiratory risks, with leading to damage, systemic absorption, and elevated disease susceptibility due to its asbestos-like properties.

Countermeasures and Adaptations

Astronauts engage in structured exercise regimens to counteract the physiological deconditioning caused by microgravity, particularly the loss of muscle mass and . On the (ISS), crew members typically perform resistance and aerobic exercises for approximately 1.5 to 2 hours daily, six to seven days a week, using specialized equipment like the Advanced Resistive Exercise Device (ARED). This protocol includes high-intensity resistance training to target major muscle groups and cardiovascular workouts on treadmills or cycle ergometers, which have been shown to significantly mitigate and help preserve bone mineral density in key areas like the hips and spine. Medical interventions further support skeletal health and during spaceflight. Bisphosphonates, such as , are administered to astronauts to inhibit , with studies demonstrating their ability to help preserve mass when combined with exercise. Concepts for , including short-radius centrifuges, aim to simulate Earth's gravitational pull intermittently, allowing astronauts to exercise under 0.3-1g conditions to stimulate bone formation and cardiovascular ; prototypes have been evaluated for integration into future habitats like those for Mars missions. For radiation exposure, wearable shielding vests like the AstroRad, developed by StemRad and , provide targeted protection to vital organs using hydrogen-rich polymers, reducing deep-space radiation dose by up to 50% during solar particle events without restricting . Nutritional strategies address deficiencies exacerbated by spaceflight, focusing on bone metabolism. Astronauts receive daily supplements of vitamin D (typically 800-1000 IU) and calcium (1000-1200 mg) to maintain serum levels and support calcium absorption, which drops to 20-25% in microgravity; this regimen has been effective in preventing severe vitamin D insufficiency during six-month ISS stays. Bone health is monitored through pre- and post-flight dual-energy X-ray absorptiometry (DXA) scans, supplemented by in-flight quantitative ultrasound assessments of the tibia and calcaneus to track density changes non-invasively. Psychological countermeasures emphasize and mental in isolated environments. Pre-mission team-building exercises foster and skills, drawing from NASA's behavioral protocols to simulate mission dynamics and reduce interpersonal conflicts. In-flight support includes real-time counseling via delayed communications with ground psychologists, often augmented by automated virtual therapists for confidential sessions addressing anxiety or adjustment issues. (VR) systems provide simulations, such as immersive nature scenes or social interactions, to alleviate ; headsets tested on the ISS have improved mood and cognitive performance by enabling restorative experiences during off-duty time. Technological advances in 2025 continue to enhance adaptability for deep-space missions. The program's next-generation spacesuits, including Axiom Space's AxEMU, incorporate articulated joints and flexible materials for greater mobility in lunar gravity, enabling extended extravehicular activities (EVAs) up to eight hours while supporting physiological monitoring. Emerging gene therapy research targets radiation resistance, with 's Translational Research Institute exploring CRISPR-based edits to upregulate genes like TP53, showing promise in rodent models for enhancing against galactic cosmic rays.

Daily Life and Logistics

Nutrition and Sustenance

Astronaut menus are meticulously planned to meet daily caloric needs ranging from 2,500 to 3,500 calories, depending on individual factors such as age, sex, body weight, and mission demands, while ensuring a balanced macronutrient profile and 100% of required vitamins and minerals. These diets incorporate a variety of preservation methods to combat spoilage in space, including thermostabilization (heating to kill pathogens), (via freeze-drying or air-drying), and (sterilizing with low-dose radiation), alongside freezing and moisture control for extended shelf life up to three years. The evolution of space food reflects advancements in technology and mission requirements, beginning with the Mercury program's simple offerings like applesauce in toothpaste-style tubes and bite-sized cubes or gels to minimize mess in early capsules. By the Space Shuttle era, freeze-dried foods became standard, allowing rehydration with hot water for improved palatability and variety, while Apollo missions introduced the first hot water dispensers. On the International Space Station (ISS), menus have expanded to over 200 items, including rehydratable entrees, thermostabilized pouches, and natural-form foods, with provisions for cultural preferences such as international crew members selecting items like tortillas from Mexico or borscht from Russia to enhance morale and dietary diversity. Microgravity presents unique nutritional challenges, including fluid shifts, , and loss, necessitating dietary adjustments such as increased protein intake—often 1.2 to 1.6 grams per kilogram of body weight daily—to support muscle maintenance and counteract protein breakdown. Food processing can diminish certain vitamins, like B and C, prompting the addition of supplements to restore nutritional completeness and address absorption alterations in . Dining in space requires specialized logistics to manage microgravity, with utensils and trays featuring Velcro patches, magnets, or springs to secure items against floating, and packaging designed to prevent crumbs—such as tortillas replacing or moist, surface-tension-held foods in . relies on advanced water reclamation systems that recover approximately 98% of moisture from , sweat, and humidity, purifying it through and for potable use, ensuring self-sufficiency on long-duration missions. Looking ahead, innovations aim to sustain crews on extended voyages, including 2025 experiments with hydroponic systems on the ISS, such as the Plant Water Management trials, which demonstrate passive, soil-less cultivation of crops like using recirculating nutrient solutions to provide fresh produce and reduce resupply dependence. Additionally, 3D-printed foods, including lab-grown meats like prototypes developed through , offer customizable, nutrient-dense options tailored for texture and taste in microgravity, supporting psychological well-being on Mars-bound missions.

Personal and Environmental Management

Astronauts maintain personal in microgravity without traditional showers, relying instead on -efficient methods to conserve resources and prevent droplets from floating freely. They use no-rinse shampoos, originally developed for hospital patients, to wash their hair by applying the product and towel-drying without . Wet wipes and dry shampoos supplement these practices for body cleaning, while involves standard toothbrushes and from personal kits, with astronauts spitting into a suction device or towel to manage waste. Shaving occurs with battery-powered razors, and all hygiene items are selected pre-mission to suit individual preferences. Waste management systems on the (ISS) employ vacuum toilets to handle bodily waste in zero , where natural expulsion is ineffective. The Universal Waste Management System (UWMS) features a suction-based that separates and using from integrated fans, with directed to processing units for 98% water recovery (as of 2025) through and . are collected in disposable hydrophobic bags within a canister, manually compressed to reduce volume, and stored for later return to or incineration upon reentry, ensuring containment and odor control via air rings and filters. Compact versions of these systems are adapted for smaller like , prioritizing minimal crew time and 75% volume reduction compared to legacy designs. Environmental control and life support systems (ECLSS) on the ISS regulate cabin atmosphere to support human habitation, including (CO2) scrubbing to prevent buildup from crew respiration. Early missions used lithium hydroxide canisters for non-regenerative CO2 absorption, while the current Assembly (CDRA) employs regenerative beds that adsorb CO2 and desorb it for venting or processing, operating in four-bed cycles for continuous air purification. is maintained between 18–27°C through heat exchangers and radiators, with controlled at 40–65% via condensation removal and dehumidifiers to ensure comfort and equipment reliability. Sleep accommodations in space address microgravity challenges, where astronauts float without beds, using restraint bags—essentially zipped sleeping bags with straps—secured to walls or modules to prevent drifting and provide psychological security. These are housed in dedicated crew quarters on the ISS, offering privacy, lighting, and noise mitigation, though the 90-minute orbital cycle causes frequent 16 sunrises and sunsets daily, disrupting circadian rhythms and reducing average to about 6 hours despite scheduled 8-hour rest periods. Eye masks, earplugs, and controlled lighting help counteract these interruptions. In the , suborbital flights like those on Blue Origin's present minimal personal and environmental management needs due to their brevity, lasting about 11 minutes with roughly 4 minutes of , eliminating requirements for dedicated toilets or facilities as passengers remain seated in pressure suits. Cabin environmental controls focus on basic pressurization and temperature stability during ascent and descent, without advanced recycling systems.

Recognition and Legacy

Insignia and Honors

Astronauts are often distinguished by custom mission patches, embroidered emblems unique to each spaceflight that encapsulate the mission's goals, crew, and symbolic motifs. These patches, sewn onto spacesuits, flight suits, and displayed in mission control, trace their origins to NASA's early programs in the , where they fostered team identity and commemorated achievements. For instance, the patch depicts an descending toward the lunar surface with an in its talons, signifying peaceful lunar exploration during the 1969 . Agency-specific insignia further honor astronauts' qualifications and accomplishments. In the United States, presents a silver astronaut pin to candidates upon completing rigorous , featuring a central star encircled by an orbital wreath to symbolize preparation; this is upgraded to a pin following a successful mission. cosmonauts receive the honorary title of Pilot-Cosmonaut of the Federation, accompanied by a distinctive badge and medals like the Order of Gagarin, awarded for exceptional contributions to , as seen in presentations to crews returning from the . International honors recognize groundbreaking service on a national scale. The U.S. , authorized by Congress and presented by the President, salutes astronauts for meritorious efforts in space, with recipients including for his lunar steps and for his pioneering orbital flight. Similarly, early Soviet cosmonauts such as were bestowed the title immediately after their historic missions, marking them as national icons for advancing . Private sector recognitions include certificates and wings for commercial astronauts, such as the FAA's Commercial Astronaut Wings awarded to participants in licensed suborbital or orbital flights, including Crew Dragon crews like those on Demo-2. These honors extend to internal commendations for operational excellence in private missions. Mission and hold significant cultural value as collectibles, traded and displayed by enthusiasts worldwide, while post-mission ceremonies feature patch unveilings that celebrate collective efforts in lunar exploration.

Fatalities and Memorials

Astronaut fatalities have occurred during both spaceflights and ground-based training operations, highlighting the inherent risks of human . The first in-flight death took place on April 24, 1967, when Soviet cosmonaut perished aboard due to a failure during reentry, causing the capsule to at high speed into the ground. This incident marked the initial loss of life during an orbital mission, stemming from multiple technical malfunctions including solar panel deployment issues and control problems that plagued the flight from launch. Subsequent tragedies included the Soyuz 11 mission on June 30, 1971, where cosmonauts , Vladislav Volkov, and died from cabin depressurization caused by a faulty valve that opened prematurely during separation of the modules, leading to rapid loss of pressure at an altitude of about 168 kilometers. This event remains the only known instance of human deaths occurring in space itself, as the crew succumbed to asphyxiation before reentry. In the United States, the Space Shuttle Challenger exploded 73 seconds after launch on January 28, 1986, killing all seven crew members—Francis R. Scobee, Michael J. Smith, Judith A. Resnik, Ronald E. McNair, Ellison S. Onizuka, Gregory B. Jarvis, and Christa McAuliffe—due to the failure of an O-ring seal in the right solid rocket booster, exacerbated by cold weather conditions. The shuttle disintegrated at an altitude of approximately 46 kilometers, scattering debris over the Atlantic Ocean. Similarly, the Space Shuttle Columbia broke apart during reentry on February 1, 2003, resulting in the deaths of its seven crew members—Rick Husband, William McCool, Michael P. Anderson, David M. Brown, Kalpana Chawla, Laurel Clark, and Ilan Ramon—from the catastrophic failure of the thermal protection system, caused by foam debris damaging the left wing during ascent. The orbiter disintegrated over Texas at Mach 18, with no possibility of survival. Training accidents have also claimed lives, most notably the Apollo 1 fire on January 27, 1967, during a launchpad test, where astronauts Virgil I. Grissom, Edward H. White II, and suffocated and burned in a pure-oxygen cabin environment ignited by an electrical spark and fueled by flammable materials. This pre-launch simulation at exposed vulnerabilities in spacecraft design and procedures. In the private sector, a 2014 test flight of Virgin Galactic's ended in disaster on October 31 near , when co-pilot was killed after the vehicle broke apart mid-flight due to premature unlocking of the feather mechanism, while pilot Peter Siebold survived with severe injuries. As of 2025, spaceflight history records 22 fatalities directly attributable to mission-related incidents, encompassing causes such as explosions, structural failures, parachute malfunctions, and decompression events during flights or associated preparations. These losses underscore the perilous nature of pushing human boundaries in space, with most occurring due to vehicle anomalies rather than external factors. Memorials honor these fallen explorers worldwide. The Space Mirror Memorial, a 15-meter-tall polished black granite monolith at Kennedy Space Center Visitor Complex in Florida, etches the names of 24 American astronauts lost in the line of duty, dedicated in 1991 by the Astronauts Memorial Foundation and designated a national memorial by Congress. Annual Day of Remembrance ceremonies at NASA centers, including Kennedy Space Center, commemorate the Challenger and Columbia crews through wreath-layings, moments of silence, and educational events focused on their legacies. Internationally, a 16-meter red granite stele shaped like an airplane wing marks the 1968 crash site near Kirzhach, Russia, where Yuri Gagarin and pilot Vladimir Seryogin died in a MiG-15 training flight, serving as a poignant monument opened in 1975. These tragedies prompted significant safety reforms. Post-Apollo 1, overhauled cabin materials, ignition sources, and hatch designs to prevent fires. The and investigations led to redesigned boosters, stricter launch weather protocols, and reinforced thermal tiles. Following , Soviet engineers modified capsule valves and added pressure suits for reentry. Modern vehicles like SpaceX's Crew Dragon incorporate integrated launch escape systems with engines, capable of rapidly separating the capsule from a failing at any flight phase, a direct evolution from lessons in prior abort system limitations during shuttle-era designs.

References

  1. [1]
    Job: European Astronaut - ESA
    What is an astronaut? An astronaut is a person trained to command or pilot a spacecraft or serve as a crewmember during a space mission.
  2. [2]
    Astronauts - NASA
    The term “astronaut” derives from the Greek words meaning “star sailor,” and refers to all who have been launched as crew members aboard NASA spacecraft ...
  3. [3]
    60 Years and Counting - Human Spaceflight - NASA
    It took eight years and three NASA programs -- Mercury, Gemini and Apollo – but the United States got to the moon.
  4. [4]
    Apollo 11 Mission Overview - NASA
    Apr 17, 2015 · Apollo 11 launched from Cape Kennedy on July 16, 1969, carrying Commander Neil Armstrong, Command Module Pilot Michael Collins and Lunar Module ...
  5. [5]
    Everyone Who Has Ever Been to Space, Charted | Scientific American
    Jan 21, 2025 · Now more than 700 people have flown past the 50-mile-high mark that was considered the boundary of space when spaceflight first got started. At ...<|control11|><|separator|>
  6. [6]
    Become An Astronaut - NASA
    The term "astronaut" derives from the Greek words meaning "star sailor." More than 12,000 people applied to be an astronaut between March 2 and March 31, 2020.How To Be an Astronaut · Astronaut Candidates · Frequently Asked Questions
  7. [7]
    Astronaut Requirements - NASA
    Mar 4, 2020 · Astronauts on the station conduct scientific experiments such as innovative cancer research and research on the human body and living in space.Missing: definition | Show results with:definition
  8. [8]
    International Space Station Overview - NASA
    Over 280 individuals representing 26 countries and five International Partners have visited the International Space Station. See Who Has Visited the Station.
  9. [9]
    Astronaut Fact Book - NASA
    As of November 2024, there are 47 active astronauts, 12 management astronauts, and 332 former astronauts or payload specialists, including those who have left ...
  10. [10]
    Request Astronaut Appearance - NASA
    The Astronaut Appearances Office in Houston, Texas coordinates and arranges astronaut appearances for astronauts who are actively employed by NASA.
  11. [11]
    Human Space Flight - Federal Aviation Administration
    Government astronaut, An individual designated by NASA who is on a launch or reentry vehicle and is either an employee of the U.S. Government or an ...
  12. [12]
    [PDF] HUMAN COMMERCIAL SPACEFLIGHT SAFETY REGULATIONS
    A “space flight participant” is defined as “an individual, who is not crew or a government astronaut, carried within a launch vehicle or reentry vehicle.” See ...
  13. [13]
    Outer Space Treaty - UNOOSA
    Article V. States Parties to the Treaty shall regard astronauts as envoys of mankind in outer space and shall render to them all possible assistance in the ...
  14. [14]
    Astronaut Selection Program - NASA
    NASA has selected 23 more groups of astronauts since the “Original Seven.” The backgrounds of NASA's latest group of astronaut candidates include test pilots, ...
  15. [15]
    Astronaut - Etymology, Origin & Meaning
    Space-traveler, from Greek astro (star) + nautēs (sailor), originated in 1929 scientific speculation, meaning one who travels through space, popularized by ...Missing: NASA | Show results with:NASA
  16. [16]
    The History and Future of the Term "Astronaut" - Supercluster
    Feb 16, 2021 · An 'astronaut,' according to the word's Greek origins, is a star sailor. The term invokes a vision of gliding through the galaxy like a captain navigating ...
  17. [17]
    Cosmonaut - Etymology, Origin & Meaning
    Originating from Russian kosmonavt, from Greek kosmos (universe) + nautes (sailor), cosmonaut means a Russian astronaut, relating to space travel.
  18. [18]
    cosmonaut, n. meanings, etymology and more
    OED's earliest evidence for cosmonaut is from 1959, in A. Shternfeld's Soviet Space Science. cosmonaut is a borrowing from Greek, combined with an English ...
  19. [19]
    Yuhangyuan - WorldWideWords.org
    Oct 25, 2003 · It's a transliteration of Chinese words that literally mean “universe travel worker”, an individual paid to go into space.
  20. [20]
    taikonaut - Wiktionary, the free dictionary
    From Mandarin 太空 (tàikōng, “space”) +‎ -naut, modelled after astronaut, cosmonaut, spationaut, etc. The term was coined on 19 May 1998 by Chiew Lee Yih ...
  21. [21]
    Teachers Note - Science & Exploration - European Space Agency
    “Cosmonaut” means the “sailor of the Universe”. The word means astronaut in Russian. “Spationaute” means the “sailor of space”. The word is French. back > ...
  22. [22]
    spationaut - Wiktionary, the free dictionary
    A European astronaut, specifically one representing ESA. 2004, “EUROPEAN SPACE AGENCY HOPES TO SEND TWO ASTRONAUTS TO THE ISS IN 2005”, in France in Space ...
  23. [23]
    Malaysian Astronaut Delivers Space Talk - AstroX
    The programme was named after the Malay word for astronaut, 'Angkasawan'. He said the main objectives of the angkasawan programme are to increase interest ...<|control11|><|separator|>
  24. [24]
    April 1961 - First Human Entered Space - NASA
    Nov 3, 2023 · Yuri Gagarin from the Soviet Union was the first human in space. His vehicle, Vostok 1 circled Earth at a speed of 27,400 kilometers per hour ...
  25. [25]
    Earth from Space - Image Information - NASA
    On April 12, 1961, cosmonaut Yuri Gagarin became the first human to reach Earth orbit. Launching from Baikonur Cosmodrome on Vostok-1, he flew for 108 minutes ...Missing: details | Show results with:details
  26. [26]
    John Glenn, the First American to Orbit the Earth aboard Friendship 7
    Feb 18, 2022 · The Soviets leaped ahead by placing the first man, Yuri A. Gagarin, in space on April 12, 1961, on a one-orbit flight around the Earth aboard ...
  27. [27]
    Project Mercury - NASA
    Freedom 7 crew of John Glen, Gus Grissom, and Alan Shepard in their space ... John Glenn became the first American to orbit Earth on the Friendship 7 mission.Mercury-Redstone 3: Freedom 7 · In the Beginning · Read More · Go To Gallery
  28. [28]
    60 Years Ago: Alan Shepard Becomes the First American in Space
    May 5, 2021 · Gagarin completed a single orbit around the Earth aboard his Vostok capsule. On May 5, 1961, Alan B. Shepard became the first American in space ...Missing: details | Show results with:details
  29. [29]
    Valentina Tereshkova - StarChild - NASA
    Tereshkova was launched aboard Vostok 6 on June 16, 1963 and became the first woman to fly in space. During the 70.8 hour flight, Vostok 6 made 48 orbits of ...
  30. [30]
    Apollo 11 - NASA
    Oct 11, 2024 · On Aug. 10, 1969, Apollo 11 astronauts Neil A. Armstrong, Michael Collins, and Edwin E. “Buzz” Aldrin completed their 21-day quarantine after ...Mission Overview · July 20, 1969: One Giant Leap... · Who Was Neil Armstrong?
  31. [31]
    Who Has Walked on the Moon? - NASA Science
    Twelve human beings have walked on the Moon, so far. In all, 24 astronauts made the trip from Earth to the Moon between 1968 and 1972.<|separator|>
  32. [32]
    Skylab - NASA
    In 1973 and 1974, NASA pushed the boundaries of long-duration human space missions with Skylab, America's first space station.Skylab Reenters Earth’s... · Learn More · 50 Years Ago: Launch of...
  33. [33]
    50 Years Ago: The Launch of Skylab, America's First Space Station
    May 14, 2023 · Three crews of three astronauts planned to spend 28, 56, and 56 days aboard the orbiting laboratory conducting 270 experiments.Missing: 1973-1974 | Show results with:1973-1974
  34. [34]
    Space Shuttle - NASA
    From the first launch on April 12, 1981 to the final landing on July 21, 2011, NASA's space shuttle fleet flew 135 missions, helped construct the International ...Retired Space Shuttle Locations · NASA Day of Remembrance
  35. [35]
    Challenger STS-51L Accident - NASA
    On January 28, 1986, NASA and the American people were rocked as tragedy unfolded 73 seconds into the flight of Space Shuttle Challenger's STS-51L mission.The Crew of the Space Shuttle... · Challenger Crew Report · STS-51L · TranscriptMissing: 1981-2011 flown 1983
  36. [36]
    International Space Station Visitors by Country - NASA
    Over 280 individuals representing 26 countries and five International Partners have visited the International Space Station.
  37. [37]
    Valeri Polyakov, record-breaking cosmonaut, dies at age 80
    Sep 21, 2022 · Valeri Polyakov is known for carrying out the longest single spaceflight in history, spending 437 days straight on the Mir space station between 1994 and 1995.Missing: countries | Show results with:countries
  38. [38]
    News Details - Virgin Galactic - Investor Relations
    Jun 26, 2023 · (NYSE: SPCE) today announced the crew of its first commercial spaceflight, 'Galactic 01,' with a target flight date of June 29, 2023. The three ...
  39. [39]
    Why Sally Ride waited until her death to tell the world she was gay
    and in death, she's now added to her fame as the first acknowledged gay ...
  40. [40]
    Artemis I – Flight Day 11: Orion Surpasses Apollo 13 Record ... - NASA
    Nov 26, 2022 · As of 1:16 p.m., Orion was 252,133 miles from Earth and 52,707 miles from the Moon, cruising at 2,013 miles per hour. You can track Orion via ...
  41. [41]
    Artemis III: NASA's First Human Mission to Lunar South Pole
    Jan 13, 2023 · Following two Artemis test missions, Artemis III, currently planned for 2027, will mark humanity's first return to the lunar surface in more ...Missing: target | Show results with:target
  42. [42]
    ESA - Attributes of an astronaut - European Space Agency
    Attributes of an astronaut · Citizenship of an ESA member state or associated member state · Minimum of a Master's degree from a recognised academic institution ...
  43. [43]
    https://tass.com/science/935408
  44. [44]
    Roscosmos starts recruitment of cosmonauts for future lunar missions
    Applications will be accepted from Russians no older than 35 years who have higher education in engineering, research or other flight specialties and a previous ...
  45. [45]
    Roscosmos cosmonaut requirements (Russian space agency) 2025
    You must be a russian citizen to become a cosmonaut. The age limit to apply is 35; Men and women are both eligible to become cosmonauts. Physical and medical ...Missing: criteria | Show results with:criteria
  46. [46]
    CNSA taikonaut requirements (chinese space agency) 2025
    A bachelor's degree from college is required, but CNSA's officials said they look for master degree in engineering or a PhD. Nevertheless, since the beginning ...
  47. [47]
    China to recruit civilian astronauts - Xinhua | English.news.cn
    Mar 3, 2018 · The new taikonauts will include not only pilots, but also maintenance engineers and payload specialists for the space station project. To build ...
  48. [48]
    Astronaut requirements changing rapidly with private spaceflyers ...
    Oct 18, 2020 · Astronaut requirements changing rapidly with private spaceflyers, long-duration missions · NASA announced its 2025 Astronaut Candidate Class on ...
  49. [49]
    NASA Selects All-American 2025 Class of Astronaut Candidates
    Sep 22, 2025 · NASA's 10 new astronaut candidates were introduced Monday following a competitive selection process of more than 8,000 applicants from across ...
  50. [50]
    Women Outnumber Men in NASA's Newest Astronaut Class
    Sep 22, 2025 · The 10 astronaut candidates, six of them women, will begin two years of training before becoming eligible for missions to low-Earth orbit ...Missing: inclusivity goals
  51. [51]
    Virtual Reality Training Lab - NASA
    The NASA JSC Virtual Reality Lab (VRL) is an Extravehicular Activity (EVA) and Robotics Operation training facility. The VRL uses the NASA Trick simulation.
  52. [52]
    EVA Systems - NASA
    Sep 3, 2015 · Extravehicular Activity (EVA) systems include space suits, tools and support systems for performing extravehicular activities in space.
  53. [53]
    Neutral Buoyancy Laboratory - NASA
    The Neutral Buoyancy Laboratory (NBL), part of the Sonny Carter Training Facility at NASA's Johnson Space Center in Houston, is one of the world's largest.
  54. [54]
    How astronauts prepare for the velocity of rocket launches
    Aug 24, 2023 · NASA prepares its astronauts for G forces by making them go through centrifuge training. They sit in a seat in a centrifuge machine (called the 20-G Centrifuge ...
  55. [55]
    Astronaut Candidate Survival Training - NASA
    Aug 30, 2013 · Eight new candidates spent three days in the wild participating in their wilderness survival training, near Rangeley, Maine.
  56. [56]
    [PDF] Languages and Flags of Space Exploration - NASA
    They train in Houston at Johnson Space Center's Language Education Center (JLEC) to learn each others' languages. This makes working together much easier.
  57. [57]
    Axiom Mission 1 | Axiom Space Human Spaceflight
    Each Ax-1 crew member completed between 700 and 1,000 hours of training in safety, health, ISS systems, launch site operations, and additional training for ...
  58. [58]
    Preparing for Artemis: NASA's Geology Training for Lunar Exploration
    Mar 25, 2025 · Learn about NASA's rich history of geology training and hear how scientists and engineers are getting ready to bring back samples that will help us learn.
  59. [59]
    Astronauts - StarChild - NASA
    The word astronaut means "star sailor" in Latin. Every two years, NASA must make the difficult decision of selecting new members of the astronaut corps.Missing: definition | Show results with:definition
  60. [60]
    14 CFR Part 1214 -- Space Flight - eCFR
    The ISS Commander is the leader of the crew and is responsible for forming the individual ISS crewmembers into a single, integrated team. During preflight ...
  61. [61]
    Spaceflight Operations - NASA
    Real-time operational support for all space flight phases: ascent, orbit/transit, docking, surface operations, entry and landing · Nominal, contingency, and ...
  62. [62]
    Rendezvous, Proximity Operations & Docking Subsystems - NASA
    Rendezvous, Proximity Operations, and Docking (RPOD) subsystems are critical components of space missions involving the approach, interaction, and connection ...Missing: duties | Show results with:duties
  63. [63]
    [PDF] PILOT RE-ENTRY GUIDANCE AND CONTROL
    Each phase of a space flight mission has its own hazards in terms of both equipment failure and human error, re-entry being one of the most critical phases.
  64. [64]
    Chapter: 2 NASA's Human Spaceflight: The Role and Size of ...
    Pilots monitored and flew the shuttle during launch and landing and performed orbital maneuvering and most major vehicle operations. Mission commanders came ...
  65. [65]
    Station Science 101 | Research in Microgravity: Higher, Faster, Longer
    Apr 18, 2021 · The International Space Station provides unique features that enable innovative research, including microgravity, exposure to space, a unique orbit, and hands- ...
  66. [66]
    Microgravity Science Experiments | National Air and Space Museum
    Nov 14, 2017 · The microgravity of space allows astronauts to carry out experiments that would not be possible in the gravity of Earth.
  67. [67]
    10.0 Integration, Launch, and Deployment - NASA
    Feb 3, 2025 · Satellites are launched to the ISS on a pressurized launch vehicle, mounted to the Kaber deployer, and deployed outside the ISS (48). JEM Small ...Introduction · Deployment Methods · International Space Station...
  68. [68]
    Spacesuits - NASA
    Spacewalks are some of the most physically and mentally demanding tasks an astronaut can do, with each excursion typically six to eight hours in duration.
  69. [69]
    International Space Station Spacewalks - NASA
    ... There have been 275 spacewalks at the International Space Station since December 1998. NASA. 2025. Date: May 1, 2025. Duration: 5 hours, 49 minutes
  70. [70]
    Artemis III - NASA
    Dec 5, 2024 · Over the course of about 30 days, the Artemis III astronauts will travel to lunar orbit, where two crew members will descend to the surface and ...First Human Mission · Human Landing System · Moon to Mars ArchitectureMissing: duties | Show results with:duties
  71. [71]
    NASA Announces CHAPEA Crew for Year-Long Mars Mission ...
    Sep 5, 2025 · Crew members will carry out scientific research and operational tasks, including simulated Mars walks, growing a vegetable garden, robotic ...Missing: duties | Show results with:duties
  72. [72]
    Mission Planning & Execution - NASA
    Jun 20, 2024 · We ensure the highest standards of safety and performance for our missions, preparing astronauts and ground crews for every situation. JSC ...Missing: pre- | Show results with:pre-
  73. [73]
    <title>CapComs - NASA
    Served as Landing and LM Launch CapCom on Apollo 12. Was instrumental in the development of the lunar roving vehicle used by the Apollo 15, 16, and 17 ...
  74. [74]
    Capcoms | Canadian Space Agency
    Mar 18, 2023 · A capcom's chief role is to bridge two worlds: that of Mission Control Center on Earth, and that of astronauts in space.
  75. [75]
    Results of an International Space Crew Debrief
    The debrief focused primarily on preflight training and post flight incidents of misunderstanding, miscommunication, and interpersonal friction among ...
  76. [76]
    HI-SEAS
    HI-SEAS has been the home to five successful long-duration (4 to 12 month) NASA Mars simulation missions and tens of other analog space missions in ...Missions I · About · Apply Now · Emmihs i - iv
  77. [77]
    Analog Missions - NASA
    The Crew Health and Performance Exploration Analog (CHAPEA) is a series of research analog missions that will simulate year-long stays on the surface of Mars.Missing: duties | Show results with:duties
  78. [78]
    Former Astronaut Peggy Whitson - NASA
    Nov 4, 2024 · Dr. Peggy Whitson was the first female, nonmilitary Chief of the Astronaut Office. During her long NASA career she traveled to the International Space Station.
  79. [79]
    Peggy A. Whitson (PH.D.) - NASA
    Peggy A. Whitson (Ph.D.), an Iowa native, completed two six-month tours of duty and a third, nearly one year mission, aboard the International Space Station.
  80. [80]
    Effect of microgravity on bone Tissue - ScienceDirect.com
    Astronauts experience notable bone loss, up to 1 %–2 % per month in a gravity-less environment, predominantly influencing weight-bearing bones.
  81. [81]
    Counteracting Bone and Muscle Loss in Microgravity - NASA
    Dec 1, 2023 · For every month in space, astronauts' weight-bearing bones become roughly 1% less dense if they don't take precautions to counter this loss.
  82. [82]
    Update on the effects of microgravity on the musculoskeletal system
    Jul 23, 2021 · Exposure to microgravity causes both bone and skeletal muscle loss, both of which have significant clinical implications.
  83. [83]
    Risk of Spaceflight Associated Neuro-ocular Syndrome (SANS)
    Chronic weightlessness can cause bodily fluids such as blood and cerebrospinal fluid to move toward the head, which can lead to optic nerve swelling, ...
  84. [84]
    Hazard: Space Radiation - NASA
    Aug 6, 2018 · Radiation exposure increases cancer risk, damages the central nervous system, can alter cognitive function, reduce motor function, and prompt ...
  85. [85]
    Radiation Exposure: Starliner Astronauts Waiting to Come Home
    Sep 5, 2024 · Crews aboard the ISS receive an average of 80 mSv to 160 mSv during a six-month stay, according to a 2017 NASA report. Millisieverts (mSv) ...Missing: 6- | Show results with:6-
  86. [86]
    [PDF] Radiation Risk acceptability and limitations. Cucinotta F. - NASA
    Cancer Risk Limits: Career exposure to radiation is not to exceed 3% risk of exposure induced death (REID) from fatal cancers.Missing: stay | Show results with:stay
  87. [87]
    Launch Accelerations: Values, history
    Jan 15, 2015 · Mercury astronauts took about 11g peak force on re-entry, Apollo about 6.5-7g. The space shuttle was amazingly gentle, with reentry force ...
  88. [88]
    Remembering the Columbia STS-107 Mission - NASA
    The Columbia STS-107 mission lifted off on January 16, 2003, for a 17-day science mission featuring numerous microgravity experiments.
  89. [89]
    Risk of In-Mission Performance and Behavioral Health Decrements ...
    Prolonged exposure to isolation and confinement may lead to inadequate functioning within a team. There is evidence of occasional conflict within crews.Missing: psychological dynamics
  90. [90]
    How long is the communication delay between Mars and Earth ...
    Oct 8, 2023 · Between 3 and 22 minutes each way. That means if you do something and wait to see the result the delay is 6 to 44 minutes for the round trip.
  91. [91]
    Risk of Adverse In-Mission Health and Performance Effects ... - NASA
    Sep 17, 2025 · Lunar dust exposure has not been a hazard since the 1972 Apollo missions. Data collected at that time has provided insight and many years of ...
  92. [92]
    Potential Health Impacts, Treatments, and Countermeasures of ...
    Dust on Mars is more likely to cause lung irritation, absorb into the bloodstream, and lead to diseases in astronauts.
  93. [93]
    Astronaut Exercise - NASA
    May 20, 2024 · Research on the International Space Station is helping astronauts to prevent loss of bone and muscle tissue by using an exercise regimen.
  94. [94]
    Risk of Reduced Cardiorespiratory and Musculoskeletal Fitness
    Six to seven days a week, astronauts on the International Space Station perform resistance training and aerobic exercises for 1.5 hours per day to maintain ...
  95. [95]
    [PDF] Evidence Report
    ... workouts, each 3 days/wk in alternating fashion) exercise program or the standard ISS countermeasure consisting of daily resistance and aerobic exercise.
  96. [96]
    [PDF] Bone Loss OCHMO-TB-030 Rev C - NASA
    There is a consensus among exercise scientists that both endurance. (aerobic) and resistance exercises are needed as countermeasures to maintain overall crew ...Missing: machine | Show results with:machine
  97. [97]
    The Case for Bisphosphonate Use in Astronauts Flying Long ... - NIH
    Aug 13, 2024 · With the use of an intravenous bisphosphonate such as Zoledronic Acid, the prevention of bone resorption for the duration of spaceflight-induced ...
  98. [98]
    Risk of Spaceflight-Induced Bone Changes - NASA
    Moreover, NASA studies have found that medications like bisphosphonate could help mitigate some spaceflight-induced bone loss.
  99. [99]
    [PDF] Bisphosphonates as a Countermeasure to Space Flight Induced ...
    The combined effect of anti-resorptive drugs plus in-flight exercise regimen will have a measurable effect in preventing space flight induced bone mass and.
  100. [100]
    Artificial gravity as a countermeasure for mitigating physiological ...
    During centrifugation in space, the subject is only exposed to the centrifugal force along their longitudinal body axis, referred to as artificial gravity.
  101. [101]
    Improved feasibility of astronaut short-radius artificial gravity through ...
    Aug 26, 2020 · This tool aims to assist in the development of a short-radius, intermittent centrifuge for artificial gravity implementation to enable superior ...
  102. [102]
    AstroRad | Lockheed Martin
    AstroRad is a wearable, radiation-shielding vest designed for space travel by StemRad, with support from the Israel Space Agency and Lockheed Martin.
  103. [103]
    Armor for Astronauts: Developing High-Tech Wearable Radiation ...
    Nov 13, 2024 · The vest is made from high-density polymer rich in hydrogen, which is particularly effective at shielding against cosmic radiation. “It's ...
  104. [104]
    [PDF] Human Adaptation to Spaceflight: The Role of Food and Nutrition
    Vitamin D deficiency is linked to calcium metabolism and can lead to ... and bone turnover markers in vitamin D-deficient bedridden older patients.
  105. [105]
    Space Flight Calcium: Implications for Astronaut Health, Spacecraft ...
    Recent studies have documented that supplementation with 800 IU vitamin D/day will maintain vitamin D stores in astronauts on 6-month space missions [26].Missing: ultrasound | Show results with:ultrasound
  106. [106]
    Nutrition as Fuel for Human Spaceflight
    Aug 25, 2021 · vitamin D has no impact on bone health during space- flight, whereas deficiencies of these nutrients will exacerbate spaceflight-induced ...
  107. [107]
    [PDF] AMPDXA for Precision Bone Loss Measurements on Earth and in ...
    On Earth, the body absorbs 40 to 50% of the calcium intake, whereas only 20 to 25% is absorbed in space. Astronauts also experience reduced levels of vitamin D, ...
  108. [108]
    Mental Health in Space: Ensuring Astronaut Wellbeing | EVONA
    Techniques like virtual reality simulations and team-building exercises help develop skills necessary to handle the stressors they'll encounter. Virtual reality ...
  109. [109]
    Automated Psychotherapy in a Spaceflight Environment - NIH
    Oct 9, 2024 · Automated psychotherapy can be conceptualized as an arm of digital therapeutics that has been proven to be particularly effective on Earth [34] ...Missing: pre- building
  110. [110]
    “Houston: We Have A Problem…But No Worries, Our Virtual ...
    Oct 13, 2014 · The system allows astronauts to seek help confidentially on their laptops and monitors their mental health and conducts therapeutic sessions.Missing: pre- counseling
  111. [111]
    Virtual reality and artificial intelligence as psychological ...
    Virtual reality (VR) and artificial intelligence (AI) technologies can serve as psychological countermeasures as they can digitally simulate immersive ...Missing: building counseling
  112. [112]
    First Virtual Reality Headset for Mental Health in Space Will be Sent ...
    Nov 2, 2023 · A virtual reality headset will be sent to space to treat astronauts for mental health conditions during their next space mission targeted for launch on ...
  113. [113]
    The future potential of virtual reality countermeasures for ... - Frontiers
    Apr 20, 2023 · The aim is to minimise time investment while maximising data collection and enjoyment since the behavioural health of astronauts is already ...Missing: counseling | Show results with:counseling<|separator|>
  114. [114]
    Axiom Suit
    The new Axiom Extravehicular Mobility Unit (AxEMU) spacesuit will provide astronauts advanced capabilities for space exploration.
  115. [115]
    Axiom Space designs the most advanced spacesuit for Artemis III
    Sep 23, 2024 · Featuring innovative joints for the arms and legs, the suit is designed for improved mobility and flexibility, allowing astronauts to walk, ...
  116. [116]
    [PDF] Part 1: The Space Radiation Environment
    Research is ongoing to develop effective countermeasures against GCR exposure, including advanced shielding materials, gene therapy, or pharmacological ...
  117. [117]
    Translational Research Institute for Space Health Research | BCM
    Gene Therapy Countermeasures For Detrimental Effects of Space Radiation ... Mining biology's extremes for new space radiation resistance strategies<|control11|><|separator|>
  118. [118]
    [PDF] Space Food - NASA
    Astronauts select their menus from a large array of food items. Diets are designed to supply each astronaut with 100 percent of the daily value of vitamins and ...
  119. [119]
    Have Food Will Travel - NASA
    May 10, 2023 · Explorers generally burn more calories per day than the average person. Astronauts can burn up to 3,500 calories a day. The increased need for ...
  120. [120]
    Astronaut food – Orion blog
    Aug 18, 2022 · An average astronaut will typically have three meals every day in space and is expected to consume around 2500-3000 calories per day. For ESA ...
  121. [121]
    Preservation Methods Utilized for Space Food
    The preservation techniques used in space flight include freeze-dehydration, thermostabilization, irradiation, freezing and moisture adjustment.
  122. [122]
    Food technologies for space missions - ScienceDirect.com
    In general, thermo-stabilized, irradiated, rehydratable, natural and fresh foods are preferred for space missions. These include ready-to-eat foods ...
  123. [123]
    How the NASA Space Food Research Lab Works | HowStuffWorks
    May 27, 2008 · Thermostabilization, or heat processing, extends shelf life to three years. Irradiated foods are shelf stable because they're sterilized by a ...Missing: preservation dehydrated
  124. [124]
    Space Station 20th: Food on ISS - NASA
    Aug 14, 2020 · On April 12, 1961, Soviet cosmonaut Yuri A. Gagarin made history as the first human in space aboard his Vostok capsule.Missing: details | Show results with:details
  125. [125]
    The History of Space Food - Science | HowStuffWorks
    ". Mercury astronauts had primitive space food. Pictured are packets of mushroom soup, orange-grapefruit juice, cocoa beverage, pineapple juice, chicken with ...
  126. [126]
    Eating in space: Learn about space food | Canadian Space Agency
    Aug 26, 2019 · In addition, dieticians ensure that all the menus contain between 1900 and 3200 calories per day, depending on the astronaut's: weight.
  127. [127]
    Eating in Space 5E Science: Design a Menu for an Astronaut!
    Jul 26, 2024 · Did you know that astronauts eat mac and cheese in space? That's just one of 203 different things on the menu!<|separator|>
  128. [128]
    Nutritional challenges in microgravity environments: A view of ...
    Jun 8, 2025 · Thus, high-protein diets enriched with calcium, vitamin D, antioxidants and omega-3 proved effective in maintaining the health of astronauts.
  129. [129]
    Feeding the cosmos: tackling personalized space nutrition ... - Nature
    Jul 18, 2025 · Long-duration space missions pose serious challenges to astronaut nutrition and health due to the altered environment of Low Earth Orbit ...
  130. [130]
    Space nutrition and the biochemical changes caused in Astronauts ...
    Dec 30, 2023 · Due to the effects of microgravity on digestion and absorption, astronauts may have altered nutritional requirements. Nutritional supplements ...
  131. [131]
    Tray, Meal, Space Shuttle | National Air and Space Museum
    The Velcro patches, magnetic pads, and long spring across one edge kept food and beverage packages and eating utensils in place without floating away. On ...
  132. [132]
    [PDF] Feeding the Astronauts During Long Duration Missions
    All food items are packaged in individual serving sizes. ▫ Minimize crumbs. ▫ Food needs to be wet enough so that surface tension allows for food to.
  133. [133]
    NASA just recycled 98% of all astronaut pee and sweat on the ISS ...
    Jun 25, 2023 · ISS systems hit a water recovery milestone of 98% with the better processing of water contained in brine created when crewmates' urine is ...
  134. [134]
    NASA converts pee to drinkable water on International Space Station
    Jun 26, 2023 · A new NASA system succeeded at reclaiming 98% of waste water aboard the International Space Station (ISS) by converting things like urine into a drinkable ...
  135. [135]
    [PDF] Plant Water Management Experiments 5 & 6 on ISS: Hydroponics ...
    Jul 17, 2025 · Crop production in microgravity will be important to provide whole food nutrition, dietary variety, and psychological benefits to astronauts ...
  136. [136]
    NASA demonstrates passive hydroponics in microgravity aboard the ...
    May 23, 2025 · NASA initiated a series of Plant Water Management (PWM) experiments to test capillary hydroponics aboard the International Space Station in 2021.
  137. [137]
    3D Printed Food System for Long Duration Space Missions
    The 3D printing system will provide hot and quick food in addition to personalized nutrition, flavor and taste.
  138. [138]
    Space Meat – The Future of Astronaut Food | Aleph Farms
    The future is now with 3D printed space meat. Aleph Farms is joining the space race by creating a 3D printed steak for astronauts. Learn more.
  139. [139]
    Meat Grows in Space With 3D Printer on International Space Station
    Oct 8, 2019 · The Israeli food-tech startup Aleph Farms oversaw the growth of meat in space for the first time, with the help of a 3D printer.
  140. [140]
    Morning Routine in Space - NASA
    May 19, 2013 · Astronauts living and working in space have the same hygiene needs as people on Earth. They wash their hair, brush their teeth, shave and go to the bathroom.
  141. [141]
    [PDF] Development of a Universal Waste Management System
    The intent is to build a commode that requires less crew time, improved cleanliness, and a 75% reduction in volume and weight compared to the previous US ISS/ ...
  142. [142]
    Environmental Control and Life Support Systems (ECLSS) - NASA
    Apr 4, 2025 · This involves removing trace contaminants produced by electronics, plastics and human off-gassing, including carbon dioxide exhaled by the crew ...
  143. [143]
    [PDF] Sleep Accommodations OCHMO-TB-041 Rev B - NASA
    The air must be cleared continuously to avoid carbon dioxide to stall around astronaut's faces.<|control11|><|separator|>
  144. [144]
    No Bathrooms, No Barf Bags: What Blue Origin's Space Tourists ...
    Apr 11, 2017 · Once the capsule reaches space, the passengers will be able to unbuckle from their seats and enjoy about 4 minutes of weightlessness. The ...
  145. [145]
    New Shepard | Blue Origin
    Crew Capsule. Pressurized crew capsule with room for six people, environmentally controlled for comfort, and among the largest windows to have flown in space.Fly to Space · Reserve a Seat · Payloads
  146. [146]
    Human Spaceflight Mission Patches - NASA
    A gallery of NASA crew patches including those for Project Mercury, Project Gemini, Apollo, Space Shuttle, and International Space Station Expeditions.
  147. [147]
    nacle achievement: The story behind NASA's astronaut pin
    Jan 6, 2020 · The wings resembled the two branches' aviator badges, but were modified with a device at their center featuring a five-pointed star with three ...
  148. [148]
    Dmitry Medvedev presented state decorations to space industry ...
    Apr 12, 2011 · Test cosmonaut Alexander Skvortsov was awarded the title of the Hero of the Russian Federation and the honorary title of Pilot-Cosmonaut of the ...
  149. [149]
    Congressional Space Medal of Honor - NASA
    List of Awardees ; John W. Young, May 19, 1981, Ronald Reagan ; Thomas P. Stafford, January 19, 1993, George H. W. Bush ; James A. Lovell, July 26, 1995, Bill ...
  150. [150]
    Pilot-Cosmonaut Yuri Alexseyevich Gagarin, Hero of the Soviet Union
    Apr 14, 2025 · Yuri Alexseyevich Gagarin, circa 1968. 14 April 1961: Gagarin is awarded the title Hero of the Soviet Union.
  151. [151]
    FAA Commercial Human Space Flight Recognition
    This table lists individuals who have received FAA human space flight recognition sorted by Qualification (Flight) Date.
  152. [152]
    Artemis II Insignia Honors All - NASA
    Apr 3, 2025 · The four astronauts who will be the first to fly to the Moon under NASA's Artemis campaign have designed an emblem to represent their mission.
  153. [153]
    Every space crew needs a mission patch. This company ... - WGBH
    Feb 24, 2023 · Patch collecting is a wildly popular hobby for space enthusiasts. "There are definitely enthusiastic patch collectors," said Pearlman. "It's ...
  154. [154]
    [PDF] Tragic Tangle | NASA
    The tangled parachutes never opened, hurtling Soyuz-1 towards Earth and killing Vladimir Komarov upon impact (Figure 3).
  155. [155]
    50 Years Ago: Remembering the Crew of Soyuz 11 - NASA
    Jun 30, 2021 · Tragedy struck near the end of their record-setting mission when, shortly before reentry into the Earth's atmosphere, the cosmonauts died as a ...
  156. [156]
    Remembering the crew of Soyuz 11, the only astronauts to die in ...
    Jun 29, 2021 · The crew's deaths were caused by a depressurization of the Soyuz 11 capsule due to a faulty valve that opened during separation of the orbital ...<|separator|>
  157. [157]
    Significant Incidents & Close Calls in Human Spaceflight
    The first human in space, Yuri Gagarin, launched on Vostok 1 on April 12, 1961. There were 8 total and 6 manned spaceflights in the program, which lasted from ...
  158. [158]
    Pilot dies in crash of Virgin Galactic rocket plane - Spaceflight Now
    Oct 31, 2014 · Virgin Galactic's SpaceShipTwo rocket plane crashed during a powered test flight over California's Mojave Desert on Friday, leaving one pilot dead and another ...
  159. [159]
    How many people have died in space? | BBC Sky at Night Magazine
    Jul 14, 2025 · That takes the total number of spaceflight-related fatalities to well over 300, and possibly nearer the 400 mark (the issue being clouded ...
  160. [160]
    Kennedy Space Center Honors Day of Remembrance - NASA
    Feb 11, 2019 · The AMF also built and maintains the Space Mirror Memorial, a 42-foot-high by 50-foot-wide granite monument that displays the names of the ...
  161. [161]
    Kennedy Space Center Honors Fallen Heroes of Human Spaceflight
    Jan 21, 2021 · The mirror was dedicated in 1991 to honor all astronauts who lost their lives on missions or during training. It has been designated a National ...
  162. [162]
    Memorial on the site of the doom of Yu.A. Gagarin and V.S. Seryogin
    On the site of their doom, a memorial was opened on October 17, 1975. The monument is a 16-meter stele in the shape of a wing of an airplane, made of red ...
  163. [163]
    SpaceX Demonstrates Astronaut Escape System for Crew Dragon ...
    ٠٦‏/٠٥‏/٢٠١٥ · The successful test of the spacecraft's launch escape capabilities proved the spacecraft's ability to carry astronauts to safety in the unlikely ...ناقصة: lessons fatalities: overhauls,