Выходит 4 номеров в год
ISSN Печать: 1050-6934
ISSN Онлайн: 1940-4379
Indexed in
Bioactive Glass Three Decades On
Краткое описание
Bioglasses were first introduced in the early 1970s and since have found wide use in dentistry. The original 45S5 bioglass, as described by Hench, is a silica-based melt-derived glass characterized by a Si02 content of less than 60%, a high Na2O and CaO content, and a high CaO:P2O5 ratio. Bioactivity has been defined as the ability of an implant to form a bond with living tissue. These glasses exhibit bone bonding, a phenomenon also observed with other bioactive ceramics. This process is a result of the surface reactive silica, calcium, and phosphate groups that are characteristic of these materials. Silica is believed to play a critical role in bioactivity. Bioactive glass is a very biocompatible material. There is a good deal of experimental data supporting its use in a variety of clinical applications, including ridge preservation, sinus augmentation, and the repair of periodontal bone defects. There are limitations inherent in the bioglass products that are currently available. They are granular in nature and cannot be depended upon to serve reliably as space-making devices. Although they are quite biocompatible and exhibit bone bonding, bioglasses are not osteoinductive and are not capable of forming bone in ectopic sites (although they can be used to deliver osteopromotive growth factors). The range of applications for these products could be extended if the material could be made in various space-making forms. Incorporation or coating with osteogenic agents such as growth factors might be worthwhile. The full potential of bioactive glasses has yet to be fully realized.
-
Ramaswamy Yogambha, Wu Chengtie, Zreiqat Hala, Orthopedic coating materials: considerations and applications, Expert Review of Medical Devices, 6, 4, 2009. Crossref
-
Niemiec Brook A., Furman Robert, Osseous Surgery and Guided Tissue Regeneration, in Veterinary Periodontology, 2013. Crossref
-
Alno Nora, Jegoux Franck, Pellen-Mussi Pascal, Tricot-Doleux Sylvie, Oudadesse Hassane, Cathelineau Guy, De Mello Gilbert, Development of a three-dimensional model for rapid evaluation of bone substitutes in vitro: Effect of the 45S5 bioglass, Journal of Biomedical Materials Research Part A, 95A, 1, 2010. Crossref
-
Murphy Matthew, Suzuki Richard, Sand Theodore, Chaput Christopher, Gregory Carl, Short Term Culture of Human Mesenchymal Stem Cells with Commercial Osteoconductive Carriers Provides Unique Insights into Biocompatibility, Journal of Clinical Medicine, 2, 3, 2013. Crossref
-
Golovchak R., Thapar P., Ingram A., Savytskii D., Jain H., Influence of phase separation on the devitrification of 45S5 bioglass, Acta Biomaterialia, 10, 11, 2014. Crossref
-
La Noce Marcella, Paino Francesca, Spina Anna, Naddeo Pasqualina, Montella Roberta, Desiderio Vincenzo, De Rosa Alfredo, Papaccio Gianpaolo, Tirino Virginia, Laino Luigi, Dental pulp stem cells: State of the art and suggestions for a true translation of research into therapy, Journal of Dentistry, 42, 7, 2014. Crossref
-
Henstock J.R., Canham L.T., Anderson S.I., Silicon: The evolution of its use in biomaterials, Acta Biomaterialia, 11, 2015. Crossref
-
Bossini Paulo Sérgio, Muniz Rennó Ana Claudia, Ribeiro Daniel Araki, Fangel Renan, Peitl Oscar, Zanotto Edgar Dutra, Parizotto Nivaldo Antonio, Biosilicate® and low-level laser therapy improve bone repair in osteoporotic rats, Journal of Tissue Engineering and Regenerative Medicine, 5, 3, 2011. Crossref
-
Green David, Lai Wing-Fu, Jung Han-Sung, Evolving Marine Biomimetics for Regenerative Dentistry, Marine Drugs, 12, 5, 2014. Crossref
-
Alno Nora, Jegoux Franck, Pellen-Mussi Pascal, Tricot-Doleux Sylvie, Cathelineau Guy, De Mello Gilbert, Mise au point d’un modèle tridimensionnel pour l’évaluation des biosubstituts osseuxin vitro, Médecine Buccale Chirurgie Buccale, 16, 4, 2010. Crossref
-
Xu Sanzhong, Yang Xianyan, Chen Xiaoyi, Shao Huifeng, He Yong, Zhang Lei, Yang Guojing, Gou Zhongru, Effect of borosilicate glass on the mechanical and biodegradation properties of 45S5-derived bioactive glass-ceramics, Journal of Non-Crystalline Solids, 405, 2014. Crossref
-
Ainslie Kristy M., Tao Sarah L., Popat Ketul C., Daniels Hugh, Hardev Veeral, Grimes Craig A., Desai Tejal A., In vitroinflammatory response of nanostructured titania, silicon oxide, and polycaprolactone, Journal of Biomedical Materials Research Part A, 91A, 3, 2009. Crossref
-
Galindo-Moreno Pablo, Ávila Gustavo, Fernández-Barbero Juan Emilio, Mesa Francisco, O'Valle-Ravassa Francisco, Wang Hom-Lay, Clinical and histologic comparison of two different composite grafts for sinus augmentation: a pilot clinical trial, Clinical Oral Implants Research, 19, 8, 2008. Crossref
-
Chen Fa-Ming, Jin Yan, Periodontal Tissue Engineering and Regeneration: Current Approaches and Expanding Opportunities, Tissue Engineering Part B: Reviews, 16, 2, 2010. Crossref
-
Granito Renata N., Ribeiro Daniel Araki, Rennó Ana Claudia M., Ravagnani Christian, Bossini Paulo S., Peitl-Filho Oscar, Zanotto Edgar D., Parizotto Nivaldo A., Oishi Jorge, Effects of biosilicate and bioglass 45S5 on tibial bone consolidation on rats: a biomechanical and a histological study, Journal of Materials Science: Materials in Medicine, 20, 12, 2009. Crossref
-
Portela Ana, Vasconcelos Mário, Branco Rogério, Gartner Fátima, Faria Miguel, Cavalheiro José, An in vitro and in vivo investigation of the biological behavior of a ferrimagnetic cement for highly focalized thermotherapy, Journal of Materials Science: Materials in Medicine, 21, 8, 2010. Crossref
-
Stiehler Maik, Bünger Cody, Baatrup Anette, Lind Martin, Kassem Moustapha, Mygind Tina, Effect of dynamic 3-D culture on proliferation, distribution, and osteogenic differentiation of human mesenchymal stem cells, Journal of Biomedical Materials Research Part A, 2008. Crossref
-
Ainslie Kristy M., Desai Tejal A., Microfabricated implants for applications in therapeutic delivery, tissue engineering, and biosensing, Lab on a Chip, 8, 11, 2008. Crossref
-
Duarte Ana Rita C., Caridade Sofia G., Mano João F., Reis Rui L., Processing of novel bioactive polymeric matrixes for tissue engineering using supercritical fluid technology, Materials Science and Engineering: C, 29, 7, 2009. Crossref
-
Habraken W.J.E.M., Wolke J.G.C., Jansen J.A., Ceramic composites as matrices and scaffolds for drug delivery in tissue engineering, Advanced Drug Delivery Reviews, 59, 4-5, 2007. Crossref
-
van Houdt Claire I A, Tim Carla R, Crovace Murilo C, Zanotto Edgar D, Peitl Oscar, Ulrich Dietmar J O, Jansen John A, Parizotto Nivaldo A, Renno Ana C, van den Beucken Jeroen J J P, Bone regeneration and gene expression in bone defects under healthy and osteoporotic bone conditions using two commercially available bone graft substitutes, Biomedical Materials, 10, 3, 2015. Crossref
-
Suzuki Kevin R., Misch Carl E., Arana Gabriel, Rams Thomas E., Suzuki Jon B., Long-Term Histopathologic Evaluation of Bioactive Glass and Human-Derived Graft Materials in Macaca fascicularis Mandibular Ridge Reconstruction, Implant Dentistry, 20, 4, 2011. Crossref
-
Sohrabi Keyvan, Saraiya Veeral, Laage Thomas A., Harris Maureen, Blieden Marissa, Karimbux Nadeem, An Evaluation of Bioactive Glass in the Treatment of Periodontal Defects: A Meta-Analysis of Randomized Controlled Clinical Trials, Journal of Periodontology, 83, 4, 2012. Crossref
-
Tiwana Paul S., Kushner George M., Haug Richard H., Maxillary Sinus Augmentation, Dental Clinics of North America, 50, 3, 2006. Crossref
-
Kwak Sanghwa, Haider Adnan, Gupta Kailash Chandra, Kim Sukyoung, Kang Inn-Kyu, Micro/Nano Multilayered Scaffolds of PLGA and Collagen by Alternately Electrospinning for Bone Tissue Engineering, Nanoscale Research Letters, 11, 1, 2016. Crossref
-
Zizzari Vincenzo Luca, Zara Susi, Tetè Giulia, Vinci Raffaele, Gherlone Enrico, Cataldi Amelia, Biologic and clinical aspects of integration of different bone substitutes in oral surgery: a literature review, Oral Surgery, Oral Medicine, Oral Pathology and Oral Radiology, 122, 4, 2016. Crossref
-
Snyder Katherine L., Holmes Hallie R., McCarthy Connor, Rajachar Rupak M., Bioactive vapor deposited calcium-phosphate silica sol-gel particles for directing osteoblast behavior, Journal of Biomedical Materials Research Part A, 104, 9, 2016. Crossref
-
Qian Zichen, Radke Daniel, Jia Wenkai, Tahtinen Mitch, Wang Guifang, Zhao Feng, Bioengineering Scaffolds for Regenerative Engineering, in Encyclopedia of Biomedical Engineering, 2019. Crossref
-
Kowal Tia J., Golovchak Roman, Chokshi Tanuj, Harms Joseph, Thamma Ukrit, Jain Himanshu, Falk Matthias M., Role of phase separation on the biological performance of 45S5 Bioglass®, Journal of Materials Science: Materials in Medicine, 28, 10, 2017. Crossref
-
Ana Ika D., Engineering of Bioceramics‐Based Scaffold and Its Clinical Applications in Dentistry, in Bioceramics and Biocomposites, 2019. Crossref
-
Ainslie Kristy M., Desai Tejal A., Microtechnologies for Drug Delivery, in Long Acting Injections and Implants, 2012. Crossref
-
Li Haiyan, Wu Zhi, Zhou YanLing, Chang Jiang, Bioglass for skin regeneration, in Biomaterials for Skin Repair and Regeneration, 2019. Crossref
-
Alno Nora, Jegoux Franck, Pellen-Mussi Pascal, Tricot-Doleux Sylvie, Cathelineau Guy, De Mello Gilbert, Mise au point d’un modèle tridimensionnel pour l’évaluation des biosubstituts osseuxin vitro, Médecine Buccale Chirurgie Buccale, 17, 1, 2011. Crossref
-
Ilharreborde Brice, Fitoussi Franck, Morel Etienne, Bensahel Henri, Penneçot Georges-François, Mazda Keyvan, Jackson's intrasacral fixation in the management of high-grade isthmic spondylolisthesis, Journal of Pediatric Orthopaedics B, 16, 1, 2007. Crossref
-
Mannel H., Zukowski D., Sewing A., Alt V., Surface Activation of Implants, in Bioceramics and Alternative Bearings in Joint Arthroplasty, 2006. Crossref
-
Zhang Hao, Yang Li, Yang Xiong‐gang, Wang Feng, Feng Jiang‐tao, Hua Kun‐chi, Li Qi, Hu Yong‐cheng, Demineralized Bone Matrix Carriers and their Clinical Applications: An Overview, Orthopaedic Surgery, 11, 5, 2019. Crossref
-
Ehrlich Hermann, Biomaterials and Biological Materials, in Marine Biological Materials of Invertebrate Origin, 13, 2019. Crossref
-
Hsu Shu-Min, Alsafadi Muhammad, Vasconez Christina, Fares Chaker, Craciun Valentin, O’Neill Edgar, Ren Fan, Clark Arthur, Esquivel-Upshaw Josephine, Qualitative Analysis of Remineralization Capabilities of Bioactive Glass (NovaMin) and Fluoride on Hydroxyapatite (HA) Discs: An In Vitro Study, Materials, 14, 14, 2021. Crossref
-
Ehrlich Hermann, Demadis Konstantinos D., Pokrovsky Oleg S., Koutsoukos Petros G., Modern Views on Desilicification: Biosilica and Abiotic Silica Dissolution in Natural and Artificial Environments, Chemical Reviews, 110, 8, 2010. Crossref
-
Deng Yan, Li Xiaoke, Li Qiang, Effect of Pore Size on the Growth of Hydroxyapatite from Mesoporous CaO−SiO2 Substrate, Industrial & Engineering Chemistry Research, 48, 19, 2009. Crossref
-
Shabbir Juzer, Najmi Naheed, Zehra Tazeen, Ali Saqib, Khurshid Zohaib, Zafar Muhammad Sohail, Palma Paulo Jorge, Intracanal medicaments, in Biomaterials in Endodontics, 2022. Crossref
-
Demir-Oğuz Öznur, Boccaccini Aldo R., Loca Dagnija, Injectable bone cements: What benefits the combination of calcium phosphates and bioactive glasses could bring?, Bioactive Materials, 19, 2023. Crossref
-
Khan Rizwan Ullah, Wang Li, Yu Haojie, Zain-ul-Abdin , Akram Muhammad, Wu Jialiang, Haroon Muhammad, Ullah Raja Summe, Deng Zheng, Xia Xia, Poly(organo)phosphazenes: recent progress in the synthesis and applications in tissue engineering and drug delivery, Russian Chemical Reviews, 87, 2, 2018. Crossref
-
Singh Shruti, Patil Amit, Mali Sheetal, Jaiswal Himmat, Bioglass: A New Era in Modern Dentistry, European Journal of General Dentistry, 11, 01, 2022. Crossref