Biodruk 3D na Międzynarodowej Stacji Kosmicznej, czyli kosmiczne kolano i wiele więcej

Autor

  • Jakub Ramotowski Międzyuczelniany Wydział Biotechnologii Uniwersytetu Gdańskiego i Gdańskiego Uniwersytetu Medycznego

DOI:

https://doi.org/10.26881/tutg.2025.2.02

Słowa kluczowe:

biodruk 3D, mikrograwitacja, Międzynarodowa Stacja Kosmiczna

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Bibliografia

Garrett-Bakelman, F. E., Darshi, M., Green, S. J., Gur, R. C., Lin, L., Macias, B. R., McKenna, M. J., Meydan, C., Mishra, T., Nasrini, J., Piening, B. D., Rizzardi, L. F., Sharma, K., Siamwala, J. H., Taylor, L., Vitaterna, M. H., Afkarian, M., Afshinnekoo, E., Ahadi, S., … Turek, F. W. 2019. The NASA twins study: A multidimensional analysis of a year-long human spaceflight. Science, 364(6436).

George, J. Klarmann, Aaron J. Rogers, Kristin, H. Gilchrist, Vincent, B. Ho. 2024. 3D bioprinting meniscus tissue onboard the International Space Station, Life Sciences in Space Research, Volume 43, 82-91.

Gładysz, K., Szydłowska, J., Żuchnik, O., Król, O., Kwiatkowski, P., Kuczyńska, B., Czelej, M., Kłos, A., Gieroba, K., Szydłowski, M. 2023. 3D bioprinting as a future of regenerative medicine and hope for transplantology. Journal of Education, Health and Sport. 13(1): 38-44.

Gungor-Ozkerim, P. S., Inci, I., Zhang, Y. S., Khademhosseini, A., & Dokmeci, M. R. 2018. Bioinks for 3D bioprinting: an overview. Biomaterials Science, 6(5), 915–946.

Klebe RJ. 1988. Cytoscribing: a method for micropositioning cells and the construction of two- and three-dimensional synthetic tissues. Exp Cell Res.

Kumar SA, Delgado M, Mendez VE, Joddar B. 2019. Applications of stem cells and bioprinting for potential treatment of diabetes. World J Stem Cells. Jan 26;11(1):13-32.

Kwok, A.T., Mohamed, N.S., Plate, J.F. et al. 2021. Spaceflight and hind limb unloading induces an arthritic phenotype in knee articular cartilage and menisci of rodents. Sci Rep 11, 10469.

Levine HG, Richards JT, Koss LL, Weislogel MM, Reed DW, Nguyen A, Barea H, Kusuma D. 2022. PONDS: A new method for plant production in space. In-Space Manufacturing and Resources. 235-249.

Liu Z, Li J, Qiu Z, Zhang S, Chen W. 2020. Electrospinning and emerging healthcare and medicine possibilities. Front Bioeng Biotechnol.; 8:565.

Mair DB, Tsui JH, Higashi T, Koenig PM, Dong Z, Chen JF, Meir JU, Smith AS, Lee PH, Ahn EH, Countryman S, Sniadecki N, Kim D. 2024. Spaceflight-induced contractile and mitochondrial dysfunction in an automated heart-on-a-chip platform. Proceedings of the National Academy of Sciences of the United States of America; 121(40).

Min S, Ko IK, Yoo JJ. 2019. State-of-the-Art Strategies for the Vascularization of Three- Dimensional Engineered Organs. Vasc Specialist Int. 35(2):77-89.

Rettig TA, Ward C, Pecaut MJ, Chapes SK. 2017. Validation of Methods to Assess the Immunoglobulin Gene Repertoire in Tissues Obtained from Mice on the International Space Station. Gravitational and Space Research. July; 5(1): 2-23. PMID: 29270444. GeneLab.

Rezapour Sarabi M, Yetisen AK, Tasoglu S. 2023. Bioprinting in Microgravity. ACS Biomater Sci Eng. 12;9(6):3074-3083.

Savchenko, A., Yin, R. T., Kireev, D., Efimov, I. R., & Molokanova, E. 2021. Graphenebased scaffolds: Fundamentals and applications for cardiovascular tissue engineering. Frontiers in Bioengineering and Biotechnology, 9, 797340.

Wu, D., Pang, S., Berg, J., Mei, Y., Ali, A., Röhrs, V., Tolksdorf, B., Hagenbuchner, J., Ausserlechner, M., Deubzer, H., Gurlo, A., & Kurreck, J. 2024. Bioprinting of Perfusable Vascularized Organ Models for Drug Development via Sacrificial-Free Direct Ink Writing. Advanced Functional Materials.

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Źródła internetowe:

[1] Narodowa Agencja Aeronautyki i Przestrzeni Kosmicznej (ang. National Aeronautics and Space Administration) [online], https://www.nasa.gov/ [dostęp: 12.04.2024]

[2] Strona Główna UMCS, Centrum Prasowe UMCS, Okiem eksperta, Komentarze eksperckie, 2022, Styczeń, Transplantologia przyszłości – komentarz ekspercki [online], https://www.umcs.pl/pl/komentarze-eksperckie, 22097,transplantologia-przyszloscikomentarz-ekspercki,111675.chtm [dostęp: 12.04.2024]

[3] PennState Material Reasearch Institute, 3Dprinted skin closes wounds and contains hair follicle precursors [online], https://www.mri.psu.edu/mri/newsmedia/news/3d-printed-skin-closeswounds-and-contains-hair-follicle-precursors [dostęp: 12.04.2024]

[4] Cellink A Bico Company, Bioprinting – explained simply! [online], https://www.cellink.com/blog/bioprinting-explainedsimply [dostęp: 12.04.2024]

[5] Europejska Agencja Kosmiczna (ang. European Space Agency), Science & Exploration, Human and Robotic Exploration, European reasearchers on weightless parabolic flight [online], https://www.esa.int/Science_Exploration/Human_and_Robotic_Exploration/European_researchers_on_weightless_parabolic_flight [dostęp: 12.04.2024]

[6] ISS National Laboratory Center For Advancement of Science in Space, 3D Printer for Human Tissue Now Available for Research Onboard the ISS National Laboratory [online], https://iss-nationallab.org/iss360/3dprinter-for-human-tissue-nowavailable-for-research-onboard-the-issnational-laboratory/?utm_source=chatgpt.com [dostęp: 19.10.2025]

Pobrania

Opublikowane

2025-11-27

Jak cytować

Ramotowski, J. (2025). Biodruk 3D na Międzynarodowej Stacji Kosmicznej, czyli kosmiczne kolano i wiele więcej. Tutoring Gedanensis, 10(2), 11–27. https://doi.org/10.26881/tutg.2025.2.02

Numer

Tom 10 Nr 2 (2025)

Dział

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