1

ANDAMIAJES MAGNÉTICOS DE QUITOSANO Y/O HIDROXIAPATITA PARA LA REGENERACIÓN DEL TEJIDO ÓSEO: UNA REVISIÓN DE LA LITERATURA

Autores/as

Danyelle Garcia Guedes https://orcid.org/0000-0003-1391-7443
Maria Eduarda Cunha https://orcid.org/0000-0001-7811-7290
Renally Gomes Araújo https://orcid.org/0000-0003-3226-4249
Adriano Lima da Silva https://orcid.org/0000-0003-3841-2839
Marcelino Guedes de Lima https://orcid.org/0000-0002-7488-0165
Fabio Gondim Nepomuceno https://orcid.org/0000-0001-7577-8894
Ana Cristina Figueiredo de Melo Costa https://orcid.org/0000-0002-8585-0009

DOI:

https://doi.org/10.47820/recima21.v4i3.2936

Palabras clave:

Andamios magnéticos. Quitosano. Hidroxiapatita. Regeneración ósea.

Resumen

La incorporación y exploración de partículas con propiedades magnéticas como potenciador de los procesos de regeneración ósea a través de andamios tridimensionales ha sido una estrategia en la ingeniería de tejido óseo, que permite obtener estructuras con capacidad de respuesta a estímulos externos, inteligentes y bioactivas. En este sentido, este artículo propone una revisión sistemática basada en artículos de investigación primarios centrados en los andamios magnéticos de quitosano y/o hidroxiapatita en la regeneración de tejido óseo. Para ello, se realizó una búsqueda en las plataformas Science Direct, Pubmed y Web of Science en el periodo comprendido entre 2020 y 2022 y la revisión se realizó mediante el software Start. Se utilizaron criterios de inclusión para seleccionar las revistas más relevantes y se observó que entre las estrategias reportadas de quitosano magnético y/o andamiaje de hidroxiapatita, las más significativas involucraron la inducción de la osteogénesis endocondral, el aumento de las vías de formación de vasos sanguíneos en el tejido óseo lesionado, el sistema de administración de fármacos , suministro de factores de crecimiento y combate de células tumorales. Los resultados mostraron que estos sistemas tienen un potencial prometedor para su aplicación en la regeneración ósea.

Descargas

Los datos de descargas todavía no están disponibles.

Biografía del autor/a

Danyelle Garcia Guedes

UFCG - Universidade Federal de Campina Grande.

Maria Eduarda Cunha

UFCG - Universidade Federal de Campina Grande.

Renally Gomes Araújo

UFCG - Universidade Federal de Campina Grande.

Adriano Lima da Silva

UFCG - Universidade Federal de Campina Grande.

Marcelino Guedes de Lima

UEPB - Universidade Estadual da Paraiba.

Fabio Gondim Nepomuceno

UFCG - Universidade Federal de Campina Grande

Ana Cristina Figueiredo de Melo Costa

UFCG - Universidade Federal de Campina Grande.

Citas

Aghajanian, A. H., Bigham, A., Sanati, A., Kefayat, A., Salamat, M. R., Sattary, M., & Rafienia, M. (2022). A 3D macroporous and magnetic Mg2SiO4-CuFe2O4 scaffold for bone tissue regeneration: Surface modification, in vitro and in vivo studies. Biomaterials Advances, 137, 212809.

Bakhtiary, N., Pezeshki-Modaress, M., & Najmoddin, N. (2022). Wet-electrospinning of nanofibrous magnetic composite 3-D scaffolds for enhanced stem cells neural differentiation. Chemical Engineering Science, 264, 118144.

Bakshi, P. S., Selvakumar, D., Kadirvelu, K., & Kumar, N. S. (2020). Chitosan as an environment friendly biomaterial – a review on recent modifications and applications. International Journal of Biological Macromolecules, 150, 1072-1083.

Brahimi, S., Ressler, A., Boumchedda, K., Hamidouche, M., Kenzour, A., Djafar, R., . . . Ivanković, H. (2022). Preparation and characterization of biocomposites based on chitosan and biomimetic hydroxyapatite derived from natural phosphate rocks. Materials Chemistry and Physics, 276, 125421.

Cai, B., Zou, Q., Zuo, Y., Li, L., Yang, B., & Li, Y. (2016). Fabrication and cell viability of injectable n-HA/chitosan composite microspheres for bone tissue engineering. RSC Advances, 6(89), 85735-85744.

Chaves, A. V., Freire, R. M., Feitosa, V. P., Ricardo, N. M., Denardin, J. C., Andrade Neto, D. M., & Fechine, P. B. (2021). Hydroxyapatite-Based Magnetic Bionanocomposite as Pharmaceuticals Carriers in Chitosan Scaffolds. Journal of Composites Science, 5(2).

Chen, M., Tan, H., Xu, W., Wang, Z., Zhang, J., Li, S., . . . Niu, X. (2022). A self-healing, magnetic and injectable biopolymer hydrogel generated by dual cross-linking for drug delivery and bone repair. Acta Biomaterialia, 153, 159-177.

Cojocaru, F. D., Balan, V., Tanase, C.-E., Popa, I. M., Butnaru, M., Bredetean, O., . . . Verestiuc, L. (2021). Development and characterisation of microporous biomimetic scaffolds loaded with magnetic nanoparticles as bone repairing material. Ceramics International, 47(8), 11209-11219.

Dasari, A., Xue, J., & Deb, S. (2022). Magnetic Nanoparticles in Bone Tissue Engineering. Nanomaterials, 12(5).

De Witte, T. M., Fratila-Apachitei, L. E., Zadpoor, A. A., & Peppas, N. A. (2018). Bone tissue engineering via growth factor delivery: from scaffolds to complex matrices. Regenerative Biomaterials, 5(4), 197-211.

Fan, T., Chen, J., Pan, P., Zhang, Y., Hu, Y., Liu, X., . . . Zhang, Q. (2016). Bioinspired double polysaccharides-based nanohybrid scaffold for bone tissue engineering. Colloids and Surfaces B: Biointerfaces, 147, 217-223.

Ge, Y.-W., Chu, M., Zhu, Z.-Y., Ke, Q.-F., Guo, Y.-P., Zhang, C.-Q., & Jia, W.-T. (2022). Nacre-inspired magnetically oriented micro-cellulose fibres/nano-hydroxyapatite/chitosan layered scaffold enhances pro-osteogenesis and angiogenesis. Materials Today Bio, 16, 100439.

Gelmi, A., & Schutt, C. E. (2021). Stimuli-Responsive Biomaterials: Scaffolds for Stem Cell Control. Advanced Healthcare Materials, 10(1), 2001125.

Hu, Y., Cao, S., Chen, J., Zhao, Y., He, F., Li, Q., . . . Shi, C. (2020). Biomimetic fabrication of icariin loaded nano hydroxyapatite reinforced bioactive porous scaffolds for bone regeneration. Chemical Engineering Journal, 394, 124895.

Jasemi, A., Kamyab Moghadas, B., Khandan, A., & Saber-Samandari, S. (2022). A porous calcium-zirconia scaffolds composed of magnetic nanoparticles for bone cancer treatment: Fabrication, characterization and FEM analysis. Ceramics International, 48(1), 1314-1325.

Li, K., Zhang, Y., Xu, J., Wang, J., Gu, X., Li, P., & Fan, Y. (2021). Three-dimensional magnetic fibrous scaffold with icariin expanded by supercritical CO2 for bone tissue engineering under static magnetic field. Composites Part B: Engineering, 226, 109304.

Li, S., Dong, C., & Lv, Y. (2022). Magnetic liquid metal scaffold with dynamically tunable stiffness for bone tissue engineering. Biomaterials Advances, 139, 212975.

Lin, H.-Y., Huang, H.-Y., Shiue, S.-J., & Cheng, J.-K. (2020). Osteogenic effects of inductive coupling magnetism from magnetic 3D printed hydrogel scaffold. Journal of Magnetism and Magnetic Materials, 504, 166680.

Liu, X., Li, Y., Sun, Y., Chen, B., Du, W., Li, Y., & Gu, N. (2022). Construction of functional magnetic scaffold with temperature control switch for long-distance vascular injury. Biomaterials, 290, 121862.

Liu, X., Wu, Y., Zhao, X., & Wang, Z. (2021). Fabrication and applications of bioactive chitosan-based organic-inorganic hybrid materials: A review. Carbohydrate Polymers, 267, 118179.

Maia, F. R., Bastos, A. R., Oliveira, J. M., Correlo, V. M., & Reis, R. L. (2022). Recent approaches towards bone tissue engineering. Bone, 154, 116256.

Mayerhoff, D. V. L. Z. (2009). Uma Análise sobre os Estudos de Prospecção Tecnológica. Cadernos de Prospecção, 1(1), 7-9.

Meshkini, A., Sistanipour, E., & Izadi, A. (2022). Mg.ATP-decorated ultrafine magnetic nanofibers: A bone scaffold with high osteogenic and antibacterial properties in the presence of an electromagnetic field. Colloids and Surfaces B: Biointerfaces, 210, 112256.

Naghdi, M., Ghovvati, M., Rabiee, N., Ahmadi, S., Abbariki, N., Sojdeh, S., . . . Zarrabi, A. (2022). Magnetic nanocomposites for biomedical applications. Advances in Colloid and Interface Science, 308, 102771.

Nazeer, M. A., Yilgör, E., & Yilgör, I. (2017). Intercalated chitosan/hydroxyapatite nanocomposites: Promising materials for bone tissue engineering applications. Carbohydrate Polymers, 175, 38-46.

Shao, H., Wu, J., Wang, S., Duan, J., Zhang, Y., Peng, J., & Lin, T. (2022). 3D gel-printing of porous MgFe2O4 magnetic scaffolds for bone tissue engineering. Ceramics International, 48(5), 7183-7191.

Sheikh, Z., Najeeb, S., Khurshid, Z., Verma, V., Rashid, H., & Glogauer, M. (2015). Biodegradable Materials for Bone Repair and Tissue Engineering Applications. Materials (Basel), 8(9), 5744-5794.

Shuai, C., Yang, W., He, C., Peng, S., Gao, C., Yang, Y., . . . Feng, P. (2020). A magnetic micro-environment in scaffolds for stimulating bone regeneration. Materials & Design, 185, 108275.

Tang, Y.-Q., Wang, Q.-Y., Ke, Q.-F., Zhang, C.-Q., Guan, J.-J., & Guo, Y.-P. (2020). Mineralization of ytterbium-doped hydroxyapatite nanorod arrays in magnetic chitosan scaffolds improves osteogenic and angiogenic abilities for bone defect healing. Chemical Engineering Journal, 387, 124166.

Xia, Y., Sun, J., Zhao, L., Zhang, F., Liang, X.-J., Guo, Y., . . . Xu, H. H. K. (2018). Magnetic field and nano-scaffolds with stem cells to enhance bone regeneration. Biomaterials, 183, 151-170.

Xing, F., Chi, Z., Yang, R., Xu, D., Cui, J., Huang, Y., . . . Liu, C. (2021). Chitin-hydroxyapatite-collagen composite scaffolds for bone regeneration. International Journal of Biological Macromolecules, 184, 170-180.

Xu, X.-L., Shu, G.-F., Wang, X.-J., Qi, J., Jin, F.-Y., Shen, Q.-Y., . . . Du, Y.-Z. (2020). Sialic acid-modified chitosan oligosaccharide-based biphasic calcium phosphate promote synergetic bone formation in rheumatoid arthritis therapy. Journal of Controlled Release, 323, 578-590.

Zafeiris, K., Brasinika, D., Karatza, A., Koumoulos, E., Karoussis, I. K., Kyriakidou, K., & Charitidis, C. A. (2021). Additive manufacturing of hydroxyapatite–chitosan–genipin composite scaffolds for bone tissue engineering applications. Materials Science and Engineering: C, 119, 111639.

Zhang, L., Yang, G., Johnson, B. N., & Jia, X. (2019). Three-dimensional (3D) printed scaffold and material selection for bone repair. Acta Biomaterialia, 84, 16-33.

Zhang, Y., Li, J., & Habibovic, P. (2022). Magnetically responsive nanofibrous ceramic scaffolds for on-demand motion and drug delivery. Bioactive Materials, 15, 372-381.

Zhao, P.-P., Ge, Y.-W., Liu, X.-L., Ke, Q.-F., Zhang, J.-W., Zhu, Z.-A., & Guo, Y.-P. (2020). Ordered arrangement of hydrated GdPO4 nanorods in magnetic chitosan matrix promotes tumor photothermal therapy and bone regeneration against breast cancer bone metastases. Chemical Engineering Journal, 381, 122694.

Zhou, Y., Liu, X., She, H., Wang, R., Bai, F., & Xiang, B. (2022). A silk fibroin/chitosan/nanohydroxyapatite biomimetic bone scaffold combined with autologous concentrated growth factor promotes the proliferation and osteogenic differentiation of BMSCs and repair of critical bone defects. Regenerative Therapy, 21, 307-321.

Descargas

PDF (Português (Brasil))

Publicado

21/03/2023

Cómo citar

Garcia Guedes, D., Cunha, M. E., Gomes Araújo, R., Silva , A. L. da, Guedes de Lima, M., Gondim Nepomuceno, F., & Figueiredo de Melo Costa, A. C. (2023). ANDAMIAJES MAGNÉTICOS DE QUITOSANO Y/O HIDROXIAPATITA PARA LA REGENERACIÓN DEL TEJIDO ÓSEO: UNA REVISIÓN DE LA LITERATURA. RECIMA21 - Revista Científica Multidisciplinar - ISSN 2675-6218, 4(3), e432936. https://doi.org/10.47820/recima21.v4i3.2936

Descargar cita

Número

Vol. 4 Núm. 3 (2023): EDITORIAL - HAGA CLIC AQUÍ PARA ACCEDER A LOS ARTÍCULOS

Sección

ARTIGOS

Categorías

Artigos

Licencia

Derechos de autor 2023 RECIMA21 - Revista Científica Multidisciplinar - ISSN 2675-6218

Creative Commons License

Esta obra está bajo una licencia internacional Creative Commons Atribución 4.0.

Os direitos autorais dos artigos/resenhas/TCCs publicados pertecem à revista RECIMA21, e seguem o padrão Creative Commons (CC BY 4.0), permitindo a cópia ou reprodução, desde que cite a fonte e respeite os direitos dos autores e contenham menção aos mesmos nos créditos. Toda e qualquer obra publicada na revista, seu conteúdo é de responsabilidade dos autores, cabendo a RECIMA21 apenas ser o veículo de divulgação, seguindo os padrões nacionais e internacionais de publicação.