Biodegradable and bioactive porous polymer/inorganic composite scaffolds for bone tissue engineering
TL;DR: Challenges in scaffold fabrication for tissue engineering such as biomolecules incorporation, surface functionalization and 3D scaffold characterization are discussed, giving possible solution strategies.
About: This article is published in Biomaterials.The article was published on 2006-06-01. It has received 3505 citations till now. The article focuses on the topics: Tissue engineering.
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TL;DR: This review comprehensively covers literature reports which have investigated specifically the effect of dissolution products of silicate bioactive glasses and glass-ceramics in relation to osteogenesis and angiogenesis and focuses on the ion release kinetics of the materials and the specific effect of the released ionic dissolution products on human cell behaviour.
2,056 citations
TL;DR: The paper takes the reader from Hench's Bioglass 45S5 to new hybrid materials that have tailorable mechanical properties and degradation rates, covering the importance of control of hierarchical structure, synthesis, processing and cellular response in the quest for new regenerative synthetic bone grafts.
1,836 citations
TL;DR: The fundamentals of bone tissue engineering are discussed, highlighting the current state of this field, and the recent advances of biomaterial and cell-based research, as well as approaches used to enhance bone regeneration.
Abstract: The worldwide incidence of bone disorders and conditions has trended steeply upward and is expected to double by 2020, especially in populations where aging is coupled with increased obesity and poor physical activity. Engineered bone tissue has been viewed as a potential alternative to the conventional use of bone grafts, due to their limitless supply and no disease transmission. However, bone tissue engineering practices have not proceeded to clinical practice due to several limitations or challenges. Bone tissue engineering aims to induce new functional bone regeneration via the synergistic combination of biomaterials, cells, and factor therapy. In this review, we discuss the fundamentals of bone tissue engineering, highlighting the current state of this field. Further, we review the recent advances of biomaterial and cell-based research, as well as approaches used to enhance bone regeneration. Specifically, we discuss widely investigated biomaterial scaffolds, micro- and nano-structural properties of these scaffolds, and the incorporation of biomimetic properties and/or growth factors. In addition, we examine various cellular approaches, including the use of mesenchymal stem cells (MSCs), embryonic stem cells (ESCs), adult stem cells, induced pluripotent stem cells (iPSCs), and platelet-rich plasma (PRP), and their clinical application strengths and limitations. We conclude by overviewing the challenges that face the bone tissue engineering field, such as the lack of sufficient vascularization at the defect site, and the research aimed at functional bone tissue engineering. These challenges will drive future research in the field.
1,742 citations
TL;DR: In this review, recent advances in bone scaffolds are highlighted and aspects that still need to be improved are discussed.
1,737 citations
TL;DR: Additive manufacturing (AM) technology has been researched and developed for more than 20 years as mentioned in this paper, and significant progress has been made in the development and commercialization of new and innovative AM processes, as well as numerous practical applications in aerospace, automotive, biomedical, energy and other fields.
Abstract: Additive manufacturing (AM) technology has been researched and developed for more than 20 years. Rather than removing materials, AM processes make three-dimensional parts directly from CAD models by adding materials layer by layer, offering the beneficial ability to build parts with geometric and material complexities that could not be produced by subtractive manufacturing processes. Through intensive research over the past two decades, significant progress has been made in the development and commercialization of new and innovative AM processes, as well as numerous practical applications in aerospace, automotive, biomedical, energy and other fields. This paper reviews the main processes, materials and applications of the current AM technology and presents future research needs for this technology.
1,502 citations
References
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TL;DR: New fabrication techniques, such as solid-free form fabrication, can potentially be used to generate scaffolds with morphological and mechanical properties more selectively designed to meet the specificity of bone-repair needs.
5,470 citations
TL;DR: Research on the tissue engineering of bone and cartilage from the polymeric scaffold point of view is reviews from a biodegradable and bioresorbable perspective.
4,914 citations
"Biodegradable and bioactive porous ..." refers methods in this paper
...Using digital data produced by an imaging source such as computer tomography or magnetic resonance imaging enables accurate design of the scaffold structure [169]....
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...SFFT, such as fused deposition modeling, have been employed to fabricate highly reproducible scaffolds with fully interconnected porous networks [147,169] as shown in Fig....
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TL;DR: The mechanisms of tissue bonding to bioactive ceramics are beginning to be understood, which can result in the molecular design of bioceramics for interfacial bonding with hard and soft tissues.
Abstract: Ceramics used for the repair and reconstruction of diseased or damaged parts of the musculo-skeletal system, termed bioceramics, may be bioinert (alumina, zirconia), resorbable (tricalcium phosphate), bioactive (hydroxyapatite, bioactive glasses, and glass-ceramics), or porous for tissue ingrowth (hydroxyapatite-coated metals, alumina). Applications include replacements for hips, knees, teeth, tendons, and ligaments and repair for periodontal disease, maxillofacial reconstruction, augmentation and stabilization of the jaw bone, spinal fusion, and bone fillers after tumor surgery. Carbon coatings are thromboresistant and are used for prosthetic heart valves. The mechanisms of tissue bonding to bioactive ceramics are beginning to be understood, which can result in the molecular design of bioceramics for interfacial bonding with hard and soft tissues. Composites are being developed with high toughness and elastic modulus match with bone. Therapeutic treatment of cancer has been achieved by localized delivery of radioactive isotopes via glass beads. Development of standard test methods for prediction of long-term (20-year) mechanical reliability under load is still needed.
4,292 citations
"Biodegradable and bioactive porous ..." refers background in this paper
...Hench and coworkers have systematically studied a series of glasses in the four-component systems with a constant 6wt% P2O5 content, as summarized in Refs....
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...The stages that are involved in forming the bone bond of bioactive glasses and bioactive glass-ceramics were summarized by Hench [13,67]....
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...The HCA phase that forms on bioactive implants is chemically and structurally equivalent to the mineral phase in bone, providing interfacial bonding [13,67]....
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...[67,81] and they divided the compositions into three regions according to their bioactivity....
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...In 1969, Hench et al. discovered that certain glass compositions had excellent biocompatibility as well as the ability of bone bonding [77]....
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Journal Article•
TL;DR: The mechanisms of tissue bonding to bioactive ceramics are beginning to be understood, which can result in the molecular design of bioceramics for interfacial bonding with hard and soft tissues.
Abstract: Ceramics used for the repair and reconstruction of diseased or damaged parts of the musculo-skeletal system, termed bioceramics, may be bioinert (alumina, zirconia), resorbable (tricalcium phosphate), bioactive (hydroxyapatite, bioactive glasses, and glass-ceramics), or porous for tissue ingrowth (hydroxyapatite-coated metals, alumina). Applications include replacements for hips, knees, teeth, tendons, and ligaments and repair for periodontal disease, maxillofacial reconstruction, augmentation and stabilization of the jaw bone, spinal fusion, and bone fillers after tumor surgery. Carbon coatings are thromboresistant and are used for prosthetic heart valves. The mechanisms of tissue bonding to bioactive ceramics are beginning to be understood, which can result in the molecular design of bioceramics for interfacial bonding with hard and soft tissues. Composites are being developed with high toughness and elastic modulus match with bone. Therapeutic treatment of cancer has been achieved by localized delivery of radioactive isotopes via glass beads. Development of standard test methods for prediction of long-term (20-year) mechanical reliability under load is still needed.
4,213 citations
Book•
11 Oct 1996
TL;DR: A. Ratner, Biomaterials Science: An Interdisciplinary Endeavor, Materials Science and Engineering--Properties of Materials: J.E. Schoen, and R.J.Ratner, Surface Properties of Materials, and Application of Materials in Medicine and Dentistry.
Abstract: B.D. Ratner, Biomaterials Science: An Interdisciplinary Endeavor. Materials Science and Engineering--Properties of Materials: J.E. Lemons, Introduction. F.W. Cooke, Bulk Properties of Materials. B.D. Ratner, Surface Properties of Materials. Classes of Materials Used in Medicine: A.S. Hoffman, Introduction. J.B. Brunski, Metals. S.A. Visser, R.W. Hergenrother, and S.L. Cooper, Polymers. N.A. Peppas, Hydrogels. J. Kohnand R. Langer, Bioresorbable and Bioerodible Materials. L.L. Hench, Ceramics, Glasses, and Glass Ceramics. I.V. Yannas, Natural Materials. H. Alexander, Composites. B.D. Ratner and A.S. Hoffman, Thin Films, Grafts, and Coatings. S.W. Shalaby, Fabrics. A.S. Hoffman, Biologically Functional Materials. Biology, Biochemistry, and Medicine--Some Background Concepts: B.D. Ratner, Introduction. T.A. Horbett, Proteins: Structure, Properties, and Adsorption to Surfaces. J.M. Schakenraad, Cells: Their Surfaces and Interactions with Materials. F.J. Schoen, Tissues. Host Reactions to Biomaterials and Their Evaluations: F.J. Schoen, Introduction. J.M. Anderson, Inflammation, Wound Healing, and the Foreign Body Response. R.J. Johnson, Immunology and the Complement System. K. Merritt, Systemic Toxicity and Hypersensitivity. S.R. Hanson and L.A. Harker, Blood Coagulation and Blood-Materials Interaction. F.J.Schoen, Tumorigenesis and Biomaterials. A.G. Gristina and P.T. Naylor, Implant-Associated Infection. Testing Biomaterials: B.D. Ratner, Introduction. S.J. Northup, In Vitro Assessment of Tissue Compatibility. M. Spector and P.A. Lalor, In Vivo Assessment of Tissue Compatibility. S. Hanson and B.D. Ratner, Testing of Blood-Material Interactions. B.H. Vale, J.E. Willson, and S.M. Niemi, Animal Models. Degradation of Materials in the Biological Environment: B.D. Ratner, Introduction. A.J. Coury, Chemical and Biochemical Degradation of Polymers. D.F. Williams and R.L. Williams, Degradative Effects of the Biological Environment on Metals and Ceramics. C.R. McMillin, Mechanical Breakdown in the Biological Environment. Y. Pathak, F.J. Schoen, and R.J. Levy, Pathologic Calcification of Biomaterials. Application of Materials in Medicine and Dentistry: J.E. Lemons, Introduction. D. Didisheim and J.T. Watson, Cardiovascular Applications. S.W. Kim, Nonthrombogenic Treatments and Strategies. J.E. Lemons, Dental Implants. D.C. Smith, Adhesives and Sealants. M.F. Refojo, Ophthalmologic Applications. J.L. Katz, Orthopedic Applications. J. Heller, Drug Delivery Systems. D. Goupil, Sutures. J.B. Kane, R.G. Tompkins, M.L. Yarmush, and J.F. Burke, Burn Dressings. L.S. Robblee and J.D. Sweeney, Bioelectrodes. P. Yager, Biomedical Sensors and Biosensors. Artificial Organs: F.J. Schoen, Introduction. K.D. Murray and D.B. Olsen, Implantable Pneumatic Artificial Hearts. P. Malchesky, Extracorporeal Artificial Organs. Practical Aspects of Biomaterials--Implants and Devices: F.J. Schoen, Introduction. J.B. Kowalski and R.F. Morrissey, Sterilization of Implants. L.M. Graham, D. Whittlesey, and B. Bevacqua, Cardiovascular Implantation. A.N. Cranin, M. Klein, and A. Sirakian, Dental Implantation. S.A. Obstbaum, Ophthalmic Implantation. A.E. Hoffman, Implant and Device Failure. B.D. Ratner, Correlations of Material Surface Properties with Biological Responses. J.M. Anderson, Implant Retrieval and Evaluation. New Products and Standards: J.E. Lemons, Introduction. S.A. Brown, Voluntary Consensus Standards. N.B. Mateo, Product Development and Regulation. B. Ratner, Perspectives and Possibilities in Biomaterials Science. Appendix: S. Slack, Properties of Biological Fluids. Subject Index.
4,194 citations