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Space Tissue Loss - Stem Cell Regeneration (STL-Regeneration)
03.22.12

Overview | Description | Applications | Operations | Results | Publications | Images

Experiment/Payload Overview

Brief Summary

Space Tissue Loss - Stem Cell Regeneration (STL-Regeneration) is a Department of Defense Space Test Program payload studying stem cell regeneration in mouce cell culture in microgravity examining the effects of tissue regeneration in space. Cell culture in microgravity serves as a model system for understanding necrosis of tissue following severe injuries on Earth.

Principal Investigator

  • Eduardo Almeida, Ph.D., Ames Research Center, Moffett Field, CA, United States

    • Co-Investigator(s)/Collaborator(s)

  • Ruth Globus, Ph.D., Ames Research Center, Moffett Field, CA, United States

    • Payload Developer

    Walter Reed Army Institute of Research, Silver Spring, MD, United States

    Sponsoring Space Agency

    National Aeronautics and Space Administration (NASA)

    Sponsoring Organization:

    National Laboratory - Department of Defense (NL - DOD)

    ISS Expedition Duration:

    March 2010 - September 2010



    Expeditions Assigned

    23/24

    Previous ISS Missions

    The STL experiment model has not previously flown in the CCM, although the hardware has flown on several previous Space Shuttle mission.

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    Experiment/Payload Description

    Research Summary

    • The Space Tissue Loss - Stem Cell Regeneration (STL-Regeneration) investigation examines the effects of space flight on the biology of mouse stem cell differentiation.


    • The STL-Regeneration experiment determines the space flight affects on the cellular biology of differentiation,gene expression patterns, and modifications to DNA sequences that regulate genes that control cell differentiation.

    Description

    The Space Tissue Loss - Stem Cell Regeneration (STL-Regeneration) studies how cells develop into specialized tissue types, or "differentiate" in space. The experiment will use mouse embryoid bodies, which are ball-shaped collections of mouse embryonic stem cells, to study the effects of microgravity on the cells' ability to differentiate.

    On Earth, the mouse embryoid body is considered a model to study how the cells and tissue of a whole organism differentiate and develop. Because mouse embryonic stem cells can differentiate into any type of adult tissue found in the body, scientists are using them to investigate the ways cells grow and regenerate to better understand the cellular, biochemical, and genetic processes of healing wounds and tissue development in space.

    STL-Regeneration plans to identify common conserved cellular and molecular space flight response mechanisms in cells relevant to normal cellular function and disease progression by profiling expression levels of Sm proteins and changes in cellular differentiation, immune function, and stress response before and after pathogenic bacteria infection of tissue culture cells.

    The Cell Culture Module (CCM) hardware used in STL investigation is designed specifically to study the effects of microgravity on cell culture. For this experiment, off-the-shelf hollow fiber bioreactors are used as basic cell support structures. The CCM allows controlled physiologic maintenance, manipulation, and testing of the cells. The CCM is a completely automated, temperature controlled system designed to help scientists study the effects of microgravity on cells in space. The study includes cultured tissue test materials in continuous flow modules.

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    Applications

    Space Applications

    Exposure to microgravity causes cells to react in a destructive cascade similar to wounds. This breakdown of tissue and function presents serious challenges to the health of humans in space. Astronauts traveling to the moon or Mars in microgravity may experience injury or, initiating the wound healing process. Astronauts exposed to pathogens in space may also experience reduced immune function and susceptibility to infection. The experiment results could help determine new and improved wound healing treatment for astronauts as well as provide further insight into bacteria/host interactions in space.

    Earth Applications

    Cellular and bacterial microgravity experiments are used to research methods of treating Earth-bound injuries and infection where cellular degeneration and decreased immune response can occur in traumatic wounds and unused limbs. The application spans both military and civilian injuries and immune response on Earth.

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    Operations

    Operational Requirements

    Four rails with individual flow paths and biocreactors will be housed inside the CCM hardware. Two rails will be used for each investigator. The configuration will allow for redundancy in experiments, increasing the probability of successful tests and samples returning to Earth for analysis.

    Operational Protocols

    The STL investigations are self contained and require crew interaction for activation, status checks, and reentry. Rails will contain cell lines treated with different agents. Following return to Earth, the rails will be returned to the respective investigator for in-depth analysis.

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    Results/More Information

    Pending flight of experiment.

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    Related Web Sites
  • Flight Systems Implementation: Space Tissue Loss
  • US Army Medical Research and Materiel Command

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    Publications

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    Ground Based Results Publications

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    ISS Patent Publications

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    Related Publications
    • Ishizaki K ,Nishizawa K ,Kato T ,Kitao H ,Han Z-B ,Hirayama J ,Suzuki F ,Cannon T F,Kamigaichi S ,Shimazu T ,Ikenaga M ,Genetic Changes Induced in Human Cells in Space Shuttle Experiment (STS-95) Aviation, Space and Environmental Medicine 2001 72 794-798
    • Landis W J,Hodgens K J,Block D ,Toma C D,Gerstenfeld L ,Spaceflight Effects on cultured embryonic chick bone cells The Journal of Bone and Mineral Research 2000 15 1099-1112
    • Reece J ,Miller M ,Arnold M ,Waterhouse C ,Cohn L ,Delaplaine E ,Cannon T ,Continuous Oxygen Monitoring of Mammalian Cell Growth on Space Shuttle Mission STS-93 with a Novel Radioluminescent Oxygen Sensor Applied Biochemistry and Biotechnology 2003 104 1-11
    • Ikenaga M ,Hirayama J ,Kato T ,Kitao H ,Han Z-B ,Ishizaki K ,Nishizawa K ,Suzuki F ,Cannon T F,Fukui K ,Shimazu T ,Kamigaichi S ,Ishioka N ,Matsumiya H ,Gravity-Directed Calcium Current in Germinating Spores of Ceratopteris Richardii Planta 2000 210 607-610
    • Effects of Orbital Spaceflight on Human Osteoblastic Cell Physiology and Gene Expression Bone 2000 26 325-331
    • Landis W J,Hodgens K J,Block D ,Toma C D,Gerstenfeld L C,Effect of Space Flight on the Frequency of Micronuclei and Expression of Stress-Responsive Proteins in Cultured Mammalian Cells Journal of Radiation Research 2002 43 Suppl S141-S147

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    Images

    Information provided by the investigation team to the ISS Program Scientist's Office.
    If updates are needed to the summary please contact JSC-ISS-Program-Science-Group. For other general questions regarding space station research and technology, please feel free to call our help line at 281-244-6187 or e-mail at JSC-ISS-Payloads-Helpline.
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