Influence of poly lactic-co-glycolic acid scaffold with concentrated growth factor on human osteoblast cells
Article Sidebar
Main Article Content
Abstract
The innovation of grafting materials facilitates an improved patients’ care and treatment outcomes in promoting bone regeneration. A recent paradigm shift towards poly lactic-co-glycolic acid (PLGA) as an excellent scaffold for tissue engineering and autologous nature of concentrated growth factor (CGF) is starting to be in the highlight of treatment. However, the role of both materials as substitutes for bone grafting material remains unclear. In this study, we aimed to investigate the influence of both materials on the biological behavior of human osteoblast cells (HOBs). PLGA microspheres prepared using double solvent evaporation method were observed under scanning electron microscope. Blood was collected from a rabbit and centrifuged to obtain CGF. HOBs were incubated with CGF, PLGA microspheres, and CGF+PLGA for 24, 48, and 72 h. Their proliferation was assessed. Microscopic image revealed a spherical shape with interconnected pores as an architecture for cellular ingrowth. Significant differences observed in the mean proliferation of HOBs between control and CGF+PLGA group. Similar observations were observed between control and PLGA, and between CGF and PLGA, indicating the role of PLGA and CGF for bone regeneration. This result further indicated that both PLGA scaffold with CGF has the potential as alternative materials in promoting bone regeneration.
Downloads
Article Details
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
References
Abbasi, N., Hamlet, S., Love, R. M., and Nguyen, N.-T. (2020). Porous scaffolds for bone regeneration. Journal of Science: Advanced Materials and Devices, 5(1), 1-9.
Araujo-Pires, A. C., Mendes, V. C., Ferreira-Junior, O., Carvalho, P. S. P., Guan, L., and Davies, J. E. (2016). Investigation of a novel PLGA/CaP scaffold in the healing of tooth extraction sockets to alveolar bone preservation in humans. Clinical Implant Dentistry and Related Research, 18(3), 559-570.
Avgoustakis, K. (2005). Polylactic-co-glycolic acid (PLGA). In Encyclopedia of Biomaterials and Biomedical Engineering (Wnek, G. E., and Bowlin, G. L, eds.), 2nd , Boca Raton, FL: CRC Press.
Borsani, E., Bonazza, V., Buffoli, B., Cocchi, M. A., Castrezzati, S., Scarì, G., Baldi, F., Pandini, S., Licenziati, S., Parolini, S., Rezzani, R., and Rodella, L. F. (2015). Biological characterization and in vitro effects of human concentrated growth factor preparation: an innovative approach to tissue regeneration. Biology and Medicine, 7(5), 1000256.
Brown, A., Zaky, S., Ray, H., and Sfeir, C. (2015). Porous magnesium/PLGA composite scaffolds for enhanced bone regeneration following tooth extraction. Acta Biomaterialia, 11, 543-553.
Cai, Q., Qiao, C., Ning, J., Ding, X., Wang, H., and Zhou, Y. (2019). A polysaccharide-based hydrogel and PLGA microspheres for sustained P24 peptide delivery: an in vitro and in vivo study based on osteogenic capability. Chemical Research in Chinese Universities, 35, 908-915.
Cai, Y., Chen, Y., Hong, X., Liu, Z., and Yuan, W. (2013). Porous microsphere and its applications. International Journal of Nanomedicine, 8, 1111-1120.
Chen, J., and Jiang, H. (2020). A comprehensive review of concentrated growth factors and their novel applications in facial reconstructive and regenerative medicine. Aesthetic Plastic Surgery, 44, 1047-1057.
Chen, X., Chen, Y., Hou, Y., Song, P., Zhou, M., Nie, M., and Liu, X. (2019). Modulation of proliferation and differentiation of gingiva‑derived mesenchymal stem cells by concentrated growth factors: Potential implications in tissue engineering for dental regeneration and repair. International Journal of Molecular Medicine, 44, 37-46.
Ebrahimi, M. (2017). Bone grafting substitutes in dentistry : general criteria for proper selection and successful application. Journal of Dental and Medical Sciences, 16(4), 75-79.
Fang, D., Long, Z., and Hou, J. (2020). Clinical Application of concentrated growth factor fibrin combined with bone repair materials in jaw defects. Journal of Oral Maxillofacial Surgery, 78(6), 882-892.
Han, F. Y., Thurecht, K. J., Whittaker, A. K., and Smith, M. T. (2016). Bioerodable PLGA-based microparticles for producing sustained-release drug formulations and strategies for improving drug loading. Frontiers in Pharmacology, 7, 185.
Hoda, N., Saifi, A. M., and Giraddi, G. B. (2016). Clinical use of the resorbable bioscaffold poly lactic co-glycolic acid (PLGA) in post-extraction socket for maintaining the alveolar height: A prospective study. Journal of Oral Biology and Craniofacial Research, 6(3), 173-178.
Hosseinpour, S., Ahsaie, M. G., Rad, M. R., Baghani, M. T., Motamedian, S. R., and Khojasteh, A. (2017). Application of selected scaffolds for bone tissue engineering: a systematic review. Oral and Maxillofacial Surgery, 21(2), 109-129.
Iqbal, M., Zafar, N., Fessi, H., and Elaissari, A. (2015). Double emulsion solvent evaporation techniques used for drug encapsulation. International Journal of Pharmaceutics, 496(2), 173-190.
Jamjoom, A., and Cohen, R. E. (2015). Grafts for ridge preservation. Journal of Functional Biomaterials, 6(3), 833-848.
Kim, T. H., Kim, S. H., Sádor, G. K., and Kim, Y. D. (2014). Comparison of platelet-rich plasma (PRP), platelet-rich fibrin (PRF), and concentrated growth factor (CGF) in rabbit-skull defect healing. Archives of Oral Biology, 59(5), 550-558.
Kirby, G. T. S., White, L. J., Steck, R., Berner, A., Bogoevski, K., Qutachi, O., Jones, B., Saifzadeh, S., Hutmacher, D. W., Shakesheff, K. M., and Woodruff, M. A. (2016). Microparticles for sustained growth factor delivery in the regeneration of critically-sized segmental tibial bone defects. Materials, 9(4), 259-278.
Kowalczewski, C. J., and Saul, J. M. (2018). Biomaterials for the delivery of growth factors and other therapeutic agents in tissue engineering approaches to bone regeneration. Frontiers in Pharmacology, 9, 513.
Kumar, P., Fathima, G., and Vinitha, B. (2013). Bone grafts in dentistry. Journal of Pharmacy and Bioallied Sciences, 5(5), 125-127.
La, W. G., and Yang, H. S. (2015). Heparin-conjugated poly (lactic-co-glycolic acid) nanospheres enhance large-wound healing by delivering growth factors in platelet-rich plasma. Artificial Organs, 39(4), 388-394.
Laurencin, C., Kan, Y., and El-Amin, S. (2006). Bone graft subtistutes. Expert Review of Medical Devices, 3(1), 49-57.
Lee, J. H., Nam, J., Kim, H. J., and Yoo, J. J. (2015). Comparison of three different methods for effective introduction of platelet-rich plasma on PLGA woven mesh. Biomedical Materials, 10(2), 025002.
Lemperlee, G., Morhenn, V. B., Pestojamasp, V., and Gallo, R. L. (2004). Experimental migration studies and histology of injectable microspheres of different sizes in mice. Plastic and Reconsructive Surgery, 113(5), 1380-1390.
Liu, F., Guo, R., Shen, M., Cao, X., Mo, X., Wang, S., and Shi, X. (2010). Effect of the porous microstructures of poly (lactic-co-glycolic acid)/ carbon nanotube composites on the growth of fibroblast cells. Soft Materials, 3, 239-253.
Makadia, H. K., and Siegel, S. J. (2011). Poly lactic-co-glycolic acid (PLGA) as biodegradable controlled drug delivery carrier. Polymers, 3(3), 1377-1397.
Martins, C., Sousa, F., Araújo, F., and Sarmento, B. (2018). Functionalizing PLGA and PLGA derivatives for drug delivery and tissue regeneration applications. Advanced Healthcare Materials, 7(1), 1701035.
Masuki, H., Okudera, T., Watanebe, T., Suzuki, M., Nishiyama, K., Okudera, H., Nakata, K., Uematsu, K., Su, C. Y., and Kawase, T. (2016). Growth factor and pro-inflammatory cytokine contents in platelet-rich plasma (PRP), plasma rich in growth factors (PRGF), advanced platelet-rich fibrin (A-PRF), and concentrated growth factors (CGF). International Journal of Implant Dentistry, 2(1), 19.
Mir, M., Ahmed, N., and Rehman, A. (2017). Recent applications of PLGA based nanostructures in drug delivery. Colloids and Surfaces B: Biointerfaces, 159, 217-231.
Qi, F., Wu, J., Li, H., and Ma, G. (2019). Recent research and development of PLGA/PLA microspheres/nanoparticles : A review in scientific and industrial aspects. Frontiers of Chemical Science and Engineering, 13(1), 14-27.
Qiao, J., Duan, J., Zhang, Y., Chu, Y., and Sun, C. (2016). The effect of concentrated growth factors in the treatment of periodontal intrabony defects. Future Science OA, 2(4), FS136.
Qutachi, O., Shakesheff, K. M., and Buttery, L. D. K. (2013). Delivery of definable number of drug or growth factor loaded poly(dl-lactic acid-co-glycolic acid) microparticles within human embryonic stem cell derived aggregates. Journal of Controlled Release, 168(1), 18-27.
Raja, S., Byakod, G., and Pudakalkatti, P. (2009). Growth factors in periodontal regeneration. International Journal of Dental Hygiene, 7(2), 82-89.
Reynolds, M. A., Aichelmann-Reidy, M. E., and Branch-Mays, G. (2010). Regeneration of periodontal tissue: bone replacement grafts. Dental Clinics of North America, 54(1), 55-71.
Rodella, L. F., Favero, G., Boninsegna, R., Buffoli, B., Labanca, M., Scarì, G., Sacco, L., Batani, T., and Rezzani, R. (2011). Growth factors, CD34 positive cells, and fibrin network analysis in concentrated growth factors fraction. Microscopy Research and Technique, 74(8), 772-777.
Sahin, O., Gokmenoglu, C., and Kara, C. (2018). Effect of concentrated growth factor on osteoblast cell response. Journal of Stomatology Oral & Maxillofacial Surgery, 119(6), 477-481.
Sangeetha, S., and Jain, A. R. (2018). Current bone substitutes for implant dentistry. Journal of Pharmacy Research, 10(8), 1583-1589.
Shimono, K., Oshima, M., Arakawa, H., Kimura, A., Nawachi, K., and Kuboki, T. (2010). The effect of growth factors for bone augmentation to enable dental implant placement: A systematic review. Japanese Dental Science Review, 46(1), 43-53.
Sicchieri, L. G., Crippa, G. E., de Oliveira, P. T., Beloti, M. M., and Rosa, A. L. (2012). Pore size regulates cell and tissue interactions with PLGA – CaP scaffolds used for bone engineering. Journal of Tissue Engineering and Regenerative Medicine, 6(2), 155-162.
Takeda, Y., Katsutoshi, K., Matsuzaka, K., and Inoue, T. (2015). The effect of concentrated growth factor on rat bone marrow cells in vitro and on calvarial bone healing in vivo. The International Journal of Oral & Maxillofacial Implants, 30(5), 1187-1196.
Toffler, M., Toscano, N., Holtzclaw, D., Corso, M. D., and David, D. E. (2009). Introducing Choukroun’s platelet rich fibrin (PRF) to the reconstructive surgery milieu. Journal of Implant & Advanced Clinical Dentistry, 1(6), 21-31.
Vyslouzil, J., Dolezel, P., Kejdusova, M., Kostal, V., Benes, L., and Dvorackova, K. (2016). Long-term controlled release of PLGA microparticles containing antidepressant mirtazapine. Pharmacetutical Development and Technology, 21(2), 214-221.
Xu, Y., Kim, C., Saylor, D. M., and Koo, D. (2016). Polymer degradation and drug delivery in PLGA-based drug – polymer applications: A review of experiments and theories. Journal of Biomedical Materials Research - Part B, 105(6), 1692-1716.
Yoshimoto, I., Sasaki, J. I., Tsuboi, R., Yamaguchi, S., Kitagawa, H., and Imazato, S. (2018). Development of layered PLGA membranes for periodontal tissue regeneration. Dental Materials, 34(3), 538-550.
Yu, M., Wang, X., Liu, Y., and Qiao, J. (2019). Cytokine release kinetics of concentrated growth factors in different scaffolds. Clinical Oral Investigations, 23(4), 1663-1671.
Zhang, L., and Ai, H. (2019). Concentrated growth factor promotes proliferation, osteogenic differentiation, and angiogenic potential of rabbit periosteum-derived cells in vitro. Journal of Orthopaedic Surgery and Research, 14(1), 146.
Zhang, Y., Sun, T., and Jiang, C. (2018). Biomacromolecules as carriers in drug delivery and tissue engineering. Acta Pharmaceutica Sinica B, 8(1), 34-50.
Zhang, Z., Li, X., Zhao, J., Jia, W., and Wang, Z. (2019). The effect of autogenous growth factors released from platelet concentrates on the osteogenic differentiation of periodontal ligament fibroblast: a comparative study. PeerJ, 7, e7984.
Zhao, D., Zhu, T., Li, J., Cui, L., Zhang, Z., Zhuang, X., and Ding, J. (2021). Poly (lactic-co-glycolic acid)-based composite bone-substitute materials. Bioactive Materials, 6(2): 346-360.
Zhao, X., Tay, F. R., Fang, Y., and Meng, L. (2019). Topical application of phenytoin or nifedipine-loaded PLGA microspheres promotes periodontal regeneration in vivo. Archives of Oral Biology, 97, 42-51.