A COMPARATIVE HISTOMORPHOMETRIC EVALUATION OF BONE TISSUE REGENERATION DURING EXPERIMENTAL USE OF GENE-ACTIVATED OSTEOPLASTIC MATERIALS IN GEL CARRIER

Authors

  • Kurbonov Khurshed Rakhmatulloevich
  • Oripov Firdavs Suratovich
  • Presnyakov Yevgeniy Valerevich
  • Emelin Aleksey Mikhailovich
  • Deev Roman Vadimovich

Keywords:

bone tissue regeneration, gene-activated gels, VEGF-A165, alginate gel, collagen gel, histomorphometric evaluation, bone formation, biomaterials, bone defects, growth factors

Abstract

This study presents a comparative histomorphometric evaluation of bone tissue regeneration using gene-activated alginate and collagen gels. The primary focus is on the effect of VEGF-A165 on the bone formation process in the central part of the regenerate. The results demonstrate that the addition of VEGF-A165 to the gels significantly enhances bone regeneration compared to gels without this growth factor. A substantial increase in the volume of newly formed bone tissue was observed in the central part of the regenerate when using gene-activated gels with VEGF-A165. These findings highlight the potential of incorporating VEGF-A165 in biomaterials to stimulate effective bone tissue regeneration. The data obtained can be crucial for the development of new treatment strategies and the improvement of clinical approaches for the repair of bone defects.

References

Бозо И. Я. и др. Невирусный генный трансфер в гидрогелевых матриксах с микрогранулами октакальциевого фосфата в оптимизации репаративного остеогенеза //Гены и клетки. – 2021. – Т. 16. – №. 3. – С. 91-96.

Волкова И. М., Коровина Д. Г. Трехмерные матриксы природного и синтетического происхождения для клеточной биотехнологии //Биотехнология. – 2015. – Т. 31. – №. 2. – С. 8-26.

Дубров В. Э. и др. Возможности получения и применения биоматериалов на основе гидрогелей для регенерации костной ткани человека //Вестник трансплантологии и искусственных органов. – 2019. – Т. 21. – №. 3. – С. 141-150.

Деев Р. В. Посттравматическая регенерация костной ткани при трансплантации культуры костно-мозговоых стромальных клеток (экспериментальное исследование): дис. – ГОУВПО" Военно-медицинская академия", 2006.

Стамболиев И. А. и др. Современные подходы инженерии костной ткани //Российский стоматологический журнал. – 2018. – Т. 22. – №. 2. – С. 111-116.

Ali M. et al. Controlled release of vascular endothelial growth factor (VEGF) in alginate and hyaluronic acid (ALG–HA) bead system to promote wound healing in punch-induced wound rat model //Journal of Biomaterials Science, Polymer Edition. – 2023. – Т. 34. – №. 5. – С. 612-631.

Ansari M. Bone tissue regeneration: biology, strategies and interface studies //Progress in biomaterials. – 2019. – Т. 8. – №. 4. – С. 223-237.

Battafarano G. et al. Strategies for bone regeneration: from graft to tissue engineering //International journal of molecular sciences. – 2021. – Т. 22. – №. 3. – С. 1128.

Campana V. et al. Bone substitutes in orthopaedic surgery: from basic science to clinical practice //Journal of Materials Science: Materials in Medicine. – 2014. – Т. 25. – С. 2445-2461.

Elsayed S. Preclinical Evaluation of 3D Printed Biomaterials for Repairing Critical-Size Bone Defects : дис. – 2023.

Endo K. et al. Enhancement of osteoblastic differentiation in alginate gel beads with bioactive octacalcium phosphate particles //Biomedical Materials. – 2015. – Т. 10. – №. 6. – С. 065019.

Fuji T. et al. Octacalcium phosphate–precipitated alginate scaffold for bone regeneration //Tissue Engineering Part A. – 2009. – Т. 15. – №. 11. – С. 3525-3535.

Li J. et al. Building osteogenic microenvironments with a double-network composite hydrogel for bone repair //Research. – 2023. – Т. 6. – С. 0021

Nam J. W., Kim M. Y., Han S. J. Cranial bone regeneration according to different particle sizes and densities of demineralized dentin matrix in the rabbit model //Maxillofacial plastic and reconstructive surgery. – 2016. – Т. 38. – С. 1-9

Quade M. et al. Central growth factor loaded depots in bone tissue engineering scaffolds for enhanced cell attraction //Tissue Engineering Part A. – 2017. – Т. 23. – №. 15-16. – С. 762-772

Takayama T., Imamura K., Yamano S. Growth Factor Delivery Using a Collagen Membrane for Bone Tissue Regeneration //Biomolecules. – 2023. – Т. 13. – №. 5. – С. 809.

Venkatesan J. et al. Alginate-based Composites Microspheres: Preparations and Applications for Bone Tissue Engineering //Current Pharmaceutical Design. – 2022

Wang W., Yeung K. W. K. Bone grafts and biomaterials substitutes for bone defect repair: A review //Bioactive materials. – 2017. – Т. 2. – №. 4. – С. 224-247.

William Jr G. et al. Bone grafts and bone graft substitutes in orthopaedic trauma surgery: a critical analysis //JBJS. – 2007. – Т. 89. – №. 3. – С. 649-658.

Yang Z. et al. Epidemiological Investigation of 387 Individuals Over 65 Years Old With Osteoporotic Fractures //Alternative Therapies in Health & Medicine. – 2023. – Т. 29. – №. 3.

Published

2024-10-28