Biotechnology in post -traumatic regeneration of bone tissue

Bone regeneration is a complex, well-organized physiological process of bone formation that can be observed during normal fracture healing and that participates in continuous remodeling throughout life. Bone has the potential for regeneration, which can best be seen by its repair after a fracture. Bone is capable of healing fractures or local defects with new tissue and regeneration without loss of high structural organization and scarring. Despite the fact that with reparative osteogenesis there are prerequisites for the complete restoration of bone structures to replace the lost ones, the percentage of complications after traumatic injuries remains quite high. This necessitates the development of new experimental and theoretical approaches to the problem of bone regeneration, including elucidating the biological mechanisms underlying the process of chemotaxis and cell differentiation in the area of traumatic injury, studying the formation of complex cellular and tissue components of the regenerate, the conditions under which this occurs, and the factors governing osteoreparation.

1. Steinle A.V. Post-traumatic regeneration of bone tissue (part 1). Siberian Medical Journal (Tomsk). 2009;Vol. 24, No. 4-1: 101-108. (in Russ)

2. Steinle A.V. Post-traumatic regeneration of bone tissue (part 2). Siberian Medical Journal (Tomsk). 2010;Vol. 25, No. 1-1: 114-118. (in Russ)

3. Zelenevsky N.V., Shchipakin M.V., Zelenevsky K.N. Animal anatomy : A practical guide for universities. Second edition, stereotypical. Saint Petersburg: Lan. 2025. 696 p. (in Russ) ISBN 978-5-507-52119-7

4. Raginov A.I., Raginov I.S. Prospects of using targeted drugs to stimulate post-traumatic bone regeneration. Challenges and innovations in traumatology and orthopedics: focus on the patient: Proceedings of a scientific and practical conference with international participation dedicated to the 95th anniversary of the birth of Professor N.P. Demichev Astrakhan. April 27, 2024. Astrakhan: Astrakhan State Medical University. 2024. pp. 89-90. (in Russ)

5. Rakhmatova M.H., Makhmurov A.M., Rakhmatov A.A. The composition of cell populations of red bone marrow and peripheral blood in optimizing post-traumatic reparative regeneration of bone tissue. Journal of Theoretical and Clinical Medicine. 2020;3: 14-17 (in Russ)

6. Zinnurov R.R., Khaliullina G.A. Development of a method for stimulating post-traumatic bone regeneration with bioactive resorbable bone matrix. Science Week 2017: Proceedings of the All-Russian youth forum with international participation. Stavropol. November 23-24. 2017. Stavropol: Stavropol State Medical University. 2017. pp. 488-489. (in Russ)

7. Burmatova A.Y. Features of the participation of KMB-2 in the regulation of post-traumatic bone regeneration in conditions of immobilization osteoporosis. Genes and Cells. 2019;Vol. 14, No. S.:44. (in Russ)

8. Akulov A.A., Gaiduk I.A., Gorbulich A.V. Clinical and histological aspects of regenerative osteohystogenesis. Proceedings of the Russian Military Medical Academy. 2020;Vol. 39, No. S1-2: 11-12. (in Russ)

9. Miromanov A.M., Gusev K.A. Hormonal regulation of osteogenesis: a review of the literature. Traumatology and Orthopedics of Russia. 2021; Vol. 27, No. 4: 120-130. (in Russ) DOI 10.21823/2311-2905-1609

10. Kamilov F.H., Farshatova E.R., Enikeev D.A. Cellular and molecular mechanisms of bone tissue remodeling and its regulation. Fundamental research. 2014; 7-4: 836-842. (in Russ)

11. Chernykh E.R., Shevela E.Ya., Starostina N.M. et al. Reparative potential of macrophages in pathology: from experiment to clinic. Genes and Cells. 2018;Vol. 13, No. S1: 20-21.(in Russ)

12. Kazakova V.S., Chuev V.P., Novikov O.O. et al. The use of growth factors in bone tissue repair (review). Scientific Bulletin of Belgorod State University. Series: Medicine. Pharmacy. 2011;4-2(99): 5-12 (in Russ)

13. Lopatin, A.E., Semenikova N.V. The use of A-PRF technology in dental implantation and the effect on healing time. Scientist (Russia). 2024;3(29): 166-170. (in Russ)

14. Kostiv R.E. Osteoinductive molecules and their significance in reparative osteogenesis in experimental fracture (literature review). Bulletin of New Medical Technologies. 2020;Vol. 27, No. 3: 84-87. (in Russ) DOI 10.24411/1609-2163-2020-16705

15. Kurdyukov E.E., Pronin I.A., Vodopyanova O.A. et al. Acceleration of bone fracture healing by stimulating neoangiogenesis. International Scientific Research Journal. 2022; 12(126). (in Russ) DOI 10.23670/IRJ.2022.126.88

16. Fednina A.S., Kurdyukov E.E., Pronin I.A. et al. Stimulation of neoangiogenesis in the bone fracture zone. Trends in the development of science and education. 2022;92-13: 85-87. (in Russ) DOI 10.18411/trnio-12-2022-613

17. Isaeva T., Surovtseva M.A., Kim I.I. et al. Treatment of diabetic peripherial artery disease with autologous bone marrow or peripherial blood derived cells. Genes & Cells. 2019;Vol. 14, No. S1: 13. (in Russ)

18. Luneva S.N., Nakoskin A.N., Talashova I.A. et al. The complex of low molecular weight proteins of bone tissue and its effect on bone regeneration. Bulletin of new medical Technologies. 2013;Vol. 20, No. 1: 28-31. (in Russ)

19. Samodai V.G., Borisov A.K., Tokar V.A. et al. Skeletal injury: current issues of etiopathogenesis, diagnosis, and choice of rational tactics for fracture treatment at the present stage (literature review). Department of Traumatology and Orthopedics. 2018;2(32): 60-65. (in Russ) DOI 10.17238/issn2226-2016.2018.2.60-65