MARS-500

Last updated

The mission's official logo Logo of the project <<Mars-500>>.svg
The mission's official logo
Crew of the 520-day simulation before starting the mission Mars-500 mission crew.jpg
Crew of the 520-day simulation before starting the mission
A three-dimensional plan of the Russia-based MARS-500 complex, used for ground-based experiments, which complement ISS-based preparations for a human mission to Mars Mars500.jpg
A three-dimensional plan of the Russia-based MARS-500 complex, used for ground-based experiments, which complement ISS-based preparations for a human mission to Mars

The MARS-500 mission was a psychosocial isolation experiment conducted between 2007 and 2011 by Russia, the European Space Agency, and China, in preparation for an unspecified future crewed spaceflight to the planet Mars. [1] The experiment's facility was located at the Russian Academy of Sciences' Institute of Biomedical Problems (IBMP) in Moscow, Russia. [1]

Contents

Between 2007 and 2011, three different crews of volunteers lived and worked in a mock-up spacecraft at IBMP. The final stage of the experiment, which was intended to simulate a 520-day crewed mission, was conducted by an all-male crew consisting of three Russians (Alexey Sitev, Sukhrob Kamolov, Alexander Smoleevskij), a Frenchman (Romain Charles), an Italian (Diego Urbina), and a Chinese citizen (Yue Wang). The mock-up facility simulated an Earth-Mars shuttle spacecraft, an ascent-descent craft, and the Martian surface. The volunteers who participated in the three stages included professionals with experience in engineering, medicine, biology, and human spaceflight. The experiment yielded important data on the physiological, social, and psychological effects of long-term, close-quarters isolation.

Project overview

Purpose

MARS-500 was intended to study the psychological, physiological, and technological challenges inherent to long-duration space flight. Among other hurdles to overcome, the experiment examined the physiological effects of long-term weightlessness, the effectiveness of resource management, and the effects of isolation in a hermetically sealed environment. MARS-500's communication systems were designed with an average delay of 13 min, to simulate the actual transmission time to and from a Mars-bound spacecraft.

Scientific objectives

The scientific goals of MARS-500 included the study of potential habitat designs, with a particular focus on medical and psychological support for the crew (who would necessarily be confined in a relatively small spacecraft, with relatively limited medical facilities, for the 7- to 9-month journey to Mars). [2]

Experiment stages

In total, 640 experiment days were scheduled between 2007 and 2011, divided into three stages of differing length. During each stage, the crew of volunteers lived and worked in a mockup spacecraft. Communication with the outside world was limited, and was conducted with a realistic time delay of up to 25 minutes, to simulate the real-life communications lag between Mars and Earth. Similarly, a realistically limited supply of on-board consumables was provided for the volunteers. [3] Some conditions, such as weightlessness and cosmic radiation, could not be simulated.

The first 15-day stage of the MARS-500 experiment took place from 15 November 2007 to 27 November 2007.[ citation needed ] The purpose of this stage was to test the technical equipment, facilities, and operating procedures for the voyage. [4]

The second, 105-day stage of the experiment began on 31 March 2009, when six volunteers started living in the experiment's isolated living complex. [5] On 14 July 2009, this stage of the experiment was completed.

The 520-day final stage of the experiment, which was intended to simulate a full-length crewed mission, began on 3 June 2010 and ended on 4 November 2011. [6] [7] [8] This stage was conducted by a six-man international crew, consisting of three Russians, a Frenchman, an Italian-Colombian, and a Chinese citizen. [8] The stage included a simulation of a crewed Mars landing, with three simulated Mars walks carried out on 14, 18, and 22 February 2011. [9] [10] The experiment ended on 4 November 2011, with all the participants reportedly in optimal physical and psychological condition. [8]

In February 2013, the Proceedings of the National Academy of Sciences reported that four of the six crew members had considerable problems sleeping, and increased sleep and rest times, in behaviour compared to animal hibernation. [11] Participants also experienced a disruption to their circadian rhythm during confinement. [12]

Facility

A labelled diagram of the experimental isolation facility Mediko-tekhnicheskii kompleks proekta <<Mars-500>>.png
A labelled diagram of the experimental isolation facility
5-scientistsin.jpg

The experiment facility was located on the Institute of Biomedical Problems' site in Moscow. The complex consisted of the isolation facility, the mission operations room, technical facilities, and offices.

The isolation facility consisted of five different modules. Three – the habitat, utility, and medical modules – simulated the main spacecraft. The fourth module simulated the Martian lander and was connected to the main spacecraft. The fifth module was a simulator of the Martian surface, and is connected to the Martian lander. The combined volume of the modules was 550 m3 (19,000 cu ft).

The facility included all the necessary equipment for running the experiment. These included communications and control systems, ventilation systems, air and water supplies, electrical installations, sewage systems, air- and water-quality monitoring and partial recycling systems, medical equipment, fire and other safety monitoring systems, and emergency equipment. The modules were maintained at Earth-normal barometric pressure. [13]

Habitable module

The habitable module was the main living quarters for the crew. The cylindrical 3.6 m × 20 m (12 ft × 66 ft) module consisted of six individual crew compartments, a kitchen/dining room, a living room, the main control room, and a toilet. The individual bedroom compartments, which had an area around 3 m2 (32 sq ft) each, contained a bed, a desk, a chair, and shelves for personal belongings. [14]

Medical module

Overhead plan of the experimental complex Mars500-facility.svg
Overhead plan of the experimental complex

The cylindrical medical module measured 3.2 m × 11.9 m (10 ft × 39 ft) and housed two medical berths, a toilet, and equipment for routine medical examinations. It also contained equipment for telemedical, laboratory, and diagnostic investigations. Had crew members become ill, they would have been isolated and treated in the module. [13]

Mars landing module simulator

The Mars landing module simulator was only used during the 30-day "Mars-orbiting" phase of the experiment. The 6.3 m × 6.17 m (20.7 ft × 20.2 ft) cylindrical module accommodated up to three crew members, and had three bunk beds, two workstations, and a toilet. Its ancillary systems included a control and data-collection system, a video control and communications system, a gas analysis system, an air-conditioning and ventilation system, a sewage system and water supply, and a fire-suppression system. [13]

Storage module

The cylindrical 3.9 m × 24 m (13 ft × 79 ft) storage module was divided into four compartments: [13]

  1. A refrigerated compartment for food storage
  2. A compartment for storage of nonperishable food
  3. An experimental greenhouse
  4. A compartment containing a bathroom, sauna, and gym

Crew

Advertised volunteer requirements

The MARS-500 project posted a number of basic requirements for any potential candidates. These were:[ citation needed ]

  1. Age: 25–50 years old
  2. Higher education
  3. Professional requirements:
    • general practitioner having skills of medical first aid
    • physician-investigator having skills of clinical laboratory diagnostics
    • biologist
    • engineer – specialist in life support systems
    • engineer – specialist in computer science
    • engineer – specialist in electronics
    • engineer – mechanic
  4. Language skills: knowledge of the Russian and English languages at a professional level

Crew of the first stage

The crew of the first 15-day stage of the isolation experiment was composed of six Russians: five men and a woman. [15] This stage of the experiment was conducted in November 2007.

Marina Tugusheva, the only woman of the crew, was excluded from the longer missions.[ citation needed ]

Crew of the second stage

The 105-day second stage involved a crew of six members, and ended on 14 July 2009. [16]

Crew of the third stage

More than 6,000 people from 40 countries applied for the 520-day third stage of the experiment. [17] The selected volunteers were three Russians, two Europeans, and one Chinese. [18] They had a varying command of English, but not all spoke Russian. [19]

The other member of the crew, a replacement, was Mikhail Sinelnikov (Михаил Олегович Синельников), a 37-year-old Russian engineer. [17] The mission started on 3 June 2010 [25] and concluded on 4 November 2011, whereupon the participants entered a four-day quarantine before leaving the facility. [8] [26]

Satellite experiments

During the MARS-500 experiment, related additional experiments aimed at studying the effects of radiation, health problems associated with weightlessness, the impact of fire on board the spacecraft, and others were conducted. [27]

Cardiac experiments

Crew experiments included monthly operational research, consisting of recording electrocardiogram, respiratory samples and blood pressure, and a questionnaire about lifestyle, stress, and possible complaints over the past month.

Quarterly dynamic complex studies included measurement and recording of blood pressure and complex cardiorespiratory parameters during the performance of functional tests with physical, mental, and orthostatic load. Detailed questionnaires conducting psychological testing and standard outpatient dispensary studies were conducted before and after the series of studies.

Immersion experiments

Because of the long stay in weightlessness, a person gets hypokinetic disorders. To study this phenomenon, IBMP has been conducting research in this area for many years, which has allowed construction of a detailed picture of the cause of hypokinetic disorders. Experimental results show the main cause of violations to be a change in the gravity-dependent mechanisms that are responsible for motoric activity under the influence of gravity on the body. The changes begin to occur because of the disruption of coordinated work by sensory systems, in particular skeletal support and proprioceptive ones. Data obtained during the experiments suggest that the support afferentation in humans acts as a mechanism of activation and regulation of activity of the postural-tonic system, and that the lack of skeletal support is the reason for discharge of the physiological and morphological changes that are common in conditions of weightlessness and microgravity. [27] [ jargon ]

The main purpose of immersion experiments was to study potential effects of the flight (including unloading) on the support mechanisms of the body (spinal, supraspinal), on the state of the central nervous systems, and on motor function and hand-eye co-ordination. [28]

Hyperbaric experiments

During the flight, a risk of fire in the spacecraft existed, and argon is planned as an inhibitor in the spacecraft's atmosphere to reduce this risk. The use of argon can significantly reduce the concentration of oxygen in the atmosphere of a spacecraft without any harm to the crew and to create a so-called hypoxic environment. Hyperbaric experiments complement the knowledge on the effect of fire-resistant oxygen-nitrogen-argon mixture on the human body with the help of an integrated assessment of the subject's body during a long stay in fire-resistant mixture. The tests were to determine the level of mental and physical performance, assess the state of the cardiorespiratory system, hematological, metabolic and immunological parameters in blood, and conduct microbiological research and research that will improve existing support systems. [29]

Radiological experiments

To avoid health problems caused by irradiation during the flight to Mars, creating a prediction model of radiation risk is needed. The model should describe the risk of radiation sickness depending on the total dose received, decreased performance which causes an acute reaction, and the possible reduction of the overall immune system resistance to the other health risks of interplanetary flight.

The prediction model is created by exposing a group of monkeys to a radiation source (caesium-137). Radiological experiments are then conducted to study the radiobiological reactions of the main regulatory body systems (nervous, endocrine, immune, cardiovascular, hematopoietic), and spermatozoa and cytogenetic response to irradiation and analysis of long-term effects of exposure (life expectancy and carcinogenesis). The experiment uses male rhesus macaque aged 3–5 years. They are divided into groups of 10–15 monkeys in each group. The experiments were designed so that they mimic the real exposure of crew during the flight to Mars, including acute and chronic phases of disease. [30]

Study of gastrointestinal tract

Among the biological and medical studies of MARS-500, the crew underwent a 24-hour electrogastroenterography, using on-board medical equipment, to study the electrical activity in the human gastrointestinal tract. [31] [32] [33]

Psychological effects

According to official results, the crew of 520-day isolation underwent the trial as a single unit. No interpersonal conflicts were noted, nor were any situations that would require interrupting or delaying any aspect of the project. [34] The difficulties encountered during the performance of some complicated activities were overcome by the crew together. Cultural differences and language difficulties did not bear any significant influence. Friendly and constructive communication is said to have prevailed throughout the experiment. The crew spent time together, watching films in different languages, and used such recreational activities as an opportunity to discuss the films and interact socially.

The crew prepared surprises for birthdays, major state holidays, and informal holidays (on 31 October, they celebrated Halloween). Some crew members increased the time spent on individual activities, which did not hamper communication or interaction. No language, social, or cultural barriers were observed, and the mission commander exercised his authority as both a formal and informal leader.

Later in the experiment, the crew spent more time in bed or engaged in personal activity. The crew's overall activity levels plummeted in the first three months, and continued to fall for the next year. On their return journey, they spent 700 hours more in bed than on the outward journey. Four of the members suffered from sleep and psychological issues. One crew member slept very badly, suffered chronic sleep deprivation, and accounted for the majority of mistakes made on a computer test used to measure concentration and alertness. [35]

See also

Related Research Articles

<span class="mw-page-title-main">International Space Station</span> Largest modular space station in low Earth orbit

The International Space Station (ISS) is the largest modular space station in low Earth orbit. The project involves five space agencies: the United States' NASA, Russia's Roscosmos, Japan's JAXA, Europe's ESA, and Canada's CSA. The ownership and use of the space station is established by intergovernmental treaties and agreements. The station serves as a microgravity and space environment research laboratory in which scientific research is conducted in astrobiology, astronomy, meteorology, physics, and other fields. The ISS is suited for testing the spacecraft systems and equipment required for possible future long-duration missions to the Moon and Mars.

<span class="mw-page-title-main">Voskhod programme</span> Soviet spaceflight program

The Voskhod programme was the second Soviet human spaceflight project. Two one-day crewed missions were flown using the Voskhod spacecraft and rocket, one in 1964 and one in 1965, and two dogs flew on a 22-day mission in 1966.

<span class="mw-page-title-main">Salyut 1</span> Soviet space station in orbit from April to October 1971

Salyut 1 (DOS-1) was the world's first space station launched into low Earth orbit by the Soviet Union on April 19, 1971. The Salyut program followed this with five more successful launches of seven more stations. The final module of the program, Zvezda (DOS-8), became the core of the Russian segment of the International Space Station and remains in orbit.

<span class="mw-page-title-main">Yuri Usachov</span> Former Russian cosmonaut

Yury Vladimirovich Usachov is a former cosmonaut who resides in Star City, Moscow. Usachov is a veteran of four spaceflights, including two long-duration missions on board the Mir Space Station and another on board the International Space Station. During his career, he also conducted seven spacewalks before his retirement on April 5, 2004.

<span class="mw-page-title-main">Soyuz TM-21</span> 1995 Russian crewed spaceflight to Mir

Soyuz TM-21 was a crewed Soyuz spaceflight to Mir. The mission launched from Baikonur Cosmodrome, atop a Soyuz-U2 carrier rocket, at 06:11:34 UTC on March 14, 1995. The flight marked the first time thirteen humans were flying in space simultaneously, with three aboard the Soyuz, three aboard Mir and seven aboard Space Shuttle Endeavour, flying STS-67.

<span class="mw-page-title-main">Soyuz TM-22</span> 1995 Russian crewed spaceflight to Mir

Soyuz TM-22 was a Soyuz spaceflight to the Soviet space station Mir. It launched from Baikonur Cosmodrome Launch Pad 1 on September 3, 1995. After two days of free flight, the crew docked with Mir to become Mir Principal Expedition 20 and Euromir 95. Mir 20 was a harbinger of the multinational missions that would be typical of the International Space Station. After 179 days, 1 hour and 42 minutes on orbit, Reiter obtained the record for spaceflight duration by a Western European.

Shuttle–<i>Mir</i> program 1993–1998 collaborative Russia–US space program

The Shuttle–Mir program was a collaborative 11-mission space program between Russia and the United States that involved American Space Shuttles visiting the Russian space station Mir, Russian cosmonauts flying on the Shuttle, and an American astronaut flying aboard a Soyuz spacecraft to engage in long-duration expeditions aboard Mir.

<span class="mw-page-title-main">Artificial gravity</span> Use of circular rotational force to mimic gravity

Artificial gravity is the creation of an inertial force that mimics the effects of a gravitational force, usually by rotation. Artificial gravity, or rotational gravity, is thus the appearance of a centrifugal force in a rotating frame of reference, as opposed to the force experienced in linear acceleration, which by the equivalence principle is indistinguishable from gravity. In a more general sense, "artificial gravity" may also refer to the effect of linear acceleration, e.g. by means of a rocket engine.

<span class="mw-page-title-main">Fobos-Grunt</span> A failed spacecraft mission to Mars

Fobos-Grunt or Phobos-Grunt was an attempted Russian sample return mission to Phobos, one of the moons of Mars. Fobos-Grunt also carried the Chinese Mars orbiter Yinghuo-1 and the tiny Living Interplanetary Flight Experiment funded by the Planetary Society.

<span class="mw-page-title-main">Soyuz TMA-20</span> 2010 Russian crewed spaceflight to the ISS

Soyuz TMA-20 was a human spaceflight to the International Space Station (ISS) and was part of the Soyuz programme. It lifted off from the Baikonur Cosmodrome in Kazakhstan on December 15, 2010, and docked with the ISS two days later. The three-person crew of Soyuz TMA-20 – Dmitri Kondratyev, Catherine Coleman and Paolo Nespoli – represented the ISS partner organizations of Roscosmos, NASA and the European Space Agency (ESA). Soyuz TMA-20's crew represented half of the members of Expedition 27; the other three members of the expedition arrived at the station on board Soyuz TMA-21 on April 6, 2011. The COSPAR ID of Soyuz TMA-20 was 2010-067A. It is ISS flight 25S.

<span class="mw-page-title-main">Aleksandr Samokutyaev</span> Russian cosmonaut

Aleksandr Mikhailovich Samokutyaev is a Russian politician and former cosmonaut. Samokutyaev served as a Flight Engineer for the International Space Station (ISS) long duration Expedition 27/28 missions. He also served as the Soyuz TMA-21 commander. He most recently served on the Soyuz TMA-14M Expedition 41/42 crew aboard the ISS. He was hired as a cosmonaut in the summer of 2003.

m ELIPS - European Programme for Life and Physical Sciences in Space and applications utilising the International Space Station started in 2001 and was intended to cover the activities for the following 5 years. This Microgravity Programme at the European Space Agency (ESA) is an optional programme, with currently 17 ESA member states participating. The ELIPS programme prepares and performs research on the International Space Station, and other uncrewed mission platforms like Sounding Rockets, in fundamental and applied life and physical sciences. ELIPS is the continuation of the earlier European microgravity programmes EMIR 1&2, and the Microgravity Facilities for Columbus, MFC.

Human analog missions are activities undertaken on Earth in various environments to simulate aspects of human missions to other worlds, including the Moon, asteroids, and Mars. These remote field tests are performed in locations that are identified based on their physical similarities to the extreme space environments of a target mission. Such activities are undertaken to test hardware and operational concepts in relevant environments.

<span class="mw-page-title-main">Vladimir Pletser</span>

Vladimir Pletser is Visiting Professor – Scientific Adviser at the Technology and Engineering Centre for Space Utilization (CSU) of the Chinese Academy of Sciences in Beijing, China, since April 2016. He supports the preparation of scientific experiments in microgravity for the future Chinese Space Station and for aircraft parabolic flights. He worked previously from 1985 till early 2016 as senior Physicist-Engineer at the European Space Research and Technology Centre (ESTEC) of ESA.

<span class="mw-page-title-main">Astronaut training</span> Preparing astronauts for space missions

Astronaut training describes the complex process of preparing astronauts in regions around the world for their space missions before, during and after the flight, which includes medical tests, physical training, extra-vehicular activity (EVA) training, procedure training, rehabilitation process, as well as training on experiments they will accomplish during their stay in space.

<span class="mw-page-title-main">European Service Module</span> Primary power and propulsion component of the Orion spacecraft

The European Service Module (ESM) is the service module component of the Orion spacecraft, serving as its primary power and propulsion component until it is discarded at the end of each mission. In January 2013, NASA announced that the European Space Agency (ESA) will contribute the service module for Artemis 1, based on the ESA's Automated Transfer Vehicle (ATV). It was delivered by Airbus Defence and Space in Bremen, in northern Germany to NASA at the end of 2018. After approval of the first module, the ESA will provide the ESMs from Artemis 2 to Artemis 6.

<span class="mw-page-title-main">Psychological and sociological effects of spaceflight</span>

Psychological and sociological effects of space flight are important to understanding how to successfully achieve the goals of long-duration expeditionary missions. Although robotic spacecraft have landed on Mars, plans have also been discussed for a human expedition, perhaps in the 2030s, or as early as 2024 for a return mission.

A Mars analog habitat is one of several historical, existing or proposed research stations designed to simulate the physical and psychological environment of a Martian exploration mission. These habitats are used to study the equipment and techniques that will be used to analyze the surface of Mars during a future crewed mission, and the simulated isolation of the volunteer inhabitants allows scientists to study the medical and psychosocial effects of long-term space missions. They are often constructed in support of extensive Mars analogs. However, sometimes existing natural places are also valued as Mars analogs. Crewed Mars habitats are featured in most human Mars missions; an alternative may be terraforming or telepresence.

Scientific International Research in Unique Terrestrial Station (SIRIUS) is a series of experiments that investigate the effects of isolation and simulates a flight to the Moon at the Institute of Biomedical Problems (IBMP) in Moscow, Russia. The first of the series started in 2017. Following the 2019 122-day experiment will be an eight-month experiment in 2020, and a twelve-month experiment in 2021 in which the European Space Agency will participate.

References

  1. 1 2 В Москве завершилась 520-дневная репетиция полета на Марс
  2. "The main purpose of 520-day isolation" . Retrieved 1 June 2010.
  3. "ESA – Mars500 – Mars500: study overview". Esa.int. 21 May 2010. Retrieved 1 June 2010.
  4. "Mars500 quick facts". European Space Agency. 21 May 2010. Retrieved 2 June 2010.
  5. Schwirtz, Michael (30 March 2009). "Staying Put on Earth, Taking a Step to Mars". The New York Times .
  6. Kelly, Jon (1 June 2010). "A space odyssey of the mind". BBC News .
  7. Amos, Jonathan (3 June 2010). "Volunteers begin Mars500 isolation". BBC News .
  8. 1 2 3 4 Amos, Jonathan (4 November 2011). "Simulated Mars mission 'lands' back on Earth". BBC News .
  9. Mars-500: a second walk. Roscosmos (in Russian), 18 February 2011. Retrieved 2011-11-04.
  10. "Marsonauts" started a third walk on the "surface" of the Red Planet. RIAN (in Russian), 22 February 2011. Retrieved 2011-11-04.
  11. Basner, Mathias; Dinges, David F.; Mollicone, Daniel; Ecker, Adrian; Jones, Christopher W.; Hyder, Eric C.; Di Antonio, Adrian; Savelev, Igor; Kan, Kevin; Goel, Namni; Morukov, Boris V.; Sutton, Jeffrey P. (12 February 2013). "Mars 520-d mission simulation reveals protracted crew hypokinesis and alterations of sleep duration and timing". Proceedings of the National Academy of Sciences. 110 (7): 2635–2640. Bibcode:2013PNAS..110.2635B. doi: 10.1073/pnas.1212646110 . PMC   3574912 .
  12. Vigo, Daniel E.; Tuerlinckx, Francis; Ogrinz, Barbara; Wan, Li; Simonelli, Guido; Bersenev, Evgeny; Van den Bergh, Omer; Aubert, André E. (2013). "Circadian Rhythm of Autonomic Cardiovascular Control During Mars500 Simulated Mission to Mars". Aviation, Space, and Environmental Medicine. 84 (10): 1023–1028. doi:10.3357/ASEM.3612.2013. hdl: 11336/25418 . ISSN   0095-6562. PMID   24261053. S2CID   21366352.
  13. 1 2 3 4 "ESA – Mars500 – The isolation facility". Esa.int. 21 May 2010. Retrieved 1 June 2010.
  14. "ESA Mars 500 Isolation Study Information Kit" (PDF). Retrieved 2 February 2011.
  15. (in Russian) Project Mars-500, Состав экипажа 14-суточной изоляции
  16. Mission accomplished: 105-day Mars mission simulation ends in Moscow, ESA Portal, 2009-07-14
  17. 1 2 3 4 5 Russia Picks Space-Pod Team for 520-Day Moscow ‘Voyage’ to Mars, Bloomberg Businessweek, 2010-05-18
  18. 1 2 Mars 500: Countdown starts for gruelling mission in Moscow car park, The Guardian, 2010-06-02
  19. Six Men Get Ready for 520-Day Simulated Mars Trip, ABC News, 2010-05-18
  20. "ESA Mars 500 - Romain Charles". ESA. Retrieved 30 April 2023.
  21. Путешествие к Марсу признали скучным занятием
  22. 1 2 Six Men Get Ready for 520-Day Simulated Mars Trip, ABC News, 2010-05-18, p. 2
  23. 1 2 He married and left on Mars, Russian News Line, 2010-06-03
  24. Chinese Volunteer Wang Yue, China Manned Space Engineering Office – Mars500
  25. ESA Mars500 News, ESA – Mars500
  26. "Call for media: Mars500, welcome back to Earth". ESA, 10 October 2011. Retrieved 2011-10-24.
  27. 1 2 Harland, David M.; Harvey, Brian (14 September 2007). Space Exploration 2008. Berlin Heidelberg New York: Springer. p. 62. ISBN   978-0-387-71667-1.
  28. (in Russian) Official website of MARS-500 project. Иммерсионные эксперименты (Immersion experiments).
  29. (in Russian) Official website of MARS-500 project. Гипербарические эксперименты (Hyperbaric experiments).
  30. (in Russian) Official website of MARS-500 project. Радиологические эксперименты (Radiological experiments).
  31. (in Russian) Official website of the Institute of Biomedical Problems RAS. Department of Nutrition, Gastroenterology, and Hygienic Control Physical Environmental Factors.
  32. Functional Gastroenterology, website. Studies of the gastrointestinal tract in the Mars-500 project.
  33. Functional Gastroenterology, website. Studies of the gastrointestinal tract in the simulation of weightlessness by dry immersion.
  34. Information at the official site IMBP in Russian Archived 19 July 2009 at the Wayback Machine
  35. "Fake mission to Mars leaves astronauts spaced out". TheGuardian.com . 7 January 2013.
News articles on the project
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.