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[1]
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The Application of Three-Dimensional-Printed Hydrogels in Bone Tissue Engineering
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Tissue Engineering Part …,
2024 |
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[2]
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A comprehensive review to find capabilities of 4D printing in implantable medical devices
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Materialwissenschaft …,
2024 |
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[3]
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Design, Analysis, and Manufacturing of Lightweight Composite Structures
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2024 |
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[4]
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Advances in Bioengineering: Head Bone Replacement in Humans
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MedScien,
2024 |
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[5]
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Natural biopolymer for 3D printing
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Journal of …,
2023 |
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[6]
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Investigating the fatigue behavior of 3D-printed bone scaffolds
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Journal of Materials Science,
2023 |
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[7]
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Preparation and characterization of propolis reinforced eggshell membrane/GelMA composite hydrogel for biomedical applications
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BMC …,
2023 |
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[8]
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Personalized 3D‐Printed Scaffolds with Multiple Bioactivities for Bioroot Regeneration
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Advanced …,
2023 |
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[9]
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An Overview of Collagen-Based Composite Scaffold for Bone Tissue Engineering
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Applied Biochemistry …,
2023 |
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[10]
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Application of fused deposition modeling (FDM) on bone scaffold manufacturing process: A review
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Heliyon,
2022 |
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[11]
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In vitro characterization of a biocompatible composite based on poly (3-hydroxybutyrate)/hydroxyapatite nanoparticles as a potential scaffold for tissue engineering
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Journal of the …,
2022 |
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[12]
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A Comprehensive Review of Biopolymer Fabrication in Additive Manufacturing Processing for 3D-Tissue-Engineering Scaffolds
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Polymers,
2022 |
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[13]
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3D printed bio polymeric materials as a new perspective for wound dressing and skin tissue engineering applications: a review
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Journal of Polymer …,
2022 |
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[14]
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Additive Manufacturing and Removal of Biomaterials
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Ultrafast Imaging and Spectroscopy for Biomedicine,
2022 |
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[15]
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A review of various materials for additive manufacturing: Recent trends and processing issues
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Journal of Materials …,
2022 |
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[16]
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조직공학에서의 3D 바이오프린팅 기술의 잠재력
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Polymer (Korea),
2022 |
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[17]
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Ultrafast Imaging and Spectroscopy for Biomedicine
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2022 |
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[18]
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Potential of 3D bioprinting techniques in tissue engineering
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폴리머,
2022 |
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[19]
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Perspectives of 3D printing technology on polymer composites for biomedical applications
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Materials Development and Processing for …,
2022 |
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[20]
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Biodegradable Nanocomposite as Advanced Bone Tissue Scaffold
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Handbook of Biodegradable Materials,
2022 |
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[21]
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BIODEGRADABLE POLY (ETHYLENE GLYCOL) DIACRYLATE FILLED ARAMID NANOFIBER HYDROGEL THREE DIMENSIONAL PRINTED TISSUE …
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2022 |
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[22]
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Trends in 3D and 4D Printing Methods of Polymer Resourcesfor the Applications in Tissue Engineering
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…,
2022 |
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[23]
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Andamios porosos para regeneración de tejido óseo fabricados por manufactura aditiva
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2021 |
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[24]
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Evaluación de Parámetros en Andamios de PLA y PCL a ser Utilizados en Tejidos Cartilaginosos
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Mexican Journal of …,
2021 |
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[25]
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Mesenchymal Stem Cells, Bioactive Factors, and Scaffolds in Bone Repair: From Research Perspectives to Clinical Practice. Cells 2021, 10, 1925
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2021 |
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[26]
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Development of Multifunctional Hybrid Scaffolds for Massive Bone Defects Filling and Regeneration
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2021 |
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[27]
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3D Bioprinting for Tissue Engineering Application
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2021 |
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[28]
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Evaluation of Parameters in PLA and PCL Scaffolds to be Used in Cartilaginous Tissues
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Revista mexicana de …,
2021 |
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[29]
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Influence of the printing parameters on the properties of Poly (lactic acid) scaffolds obtained by fused deposition modeling 3D printing
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Polymers and …,
2021 |
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[30]
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Biomimetic Design of 3D Printed Tissue-Engineered Bone Constructs
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2021 |
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[31]
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A comparison of the degradation behaviour of 3D printed PDLGA scaffolds incorporating bioglass or biosilica
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2021 |
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[32]
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Preparation and biological assessment of a ZrO2-based bone scaffold coated with hydroxyapatite and bioactive glass composite
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2021 |
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[33]
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Fabrication of a bio-instructive scaffold conferred with a favorable microenvironment allowing for superior implant osseointegration and accelerated in situ …
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2021 |
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[34]
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3D Bioprinting for Tissue Engineering Application Review
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2021 |
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[35]
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Osteogenic differentiation of adipose-derived mesenchymal stem cells using 3D-Printed PDLLA/β-TCP nanocomposite scaffolds
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2021 |
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[36]
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Influence of Materials Properties on Bio-Physical Features and Effectiveness of 3D-Scaffolds for Periodontal Regeneration
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2021 |
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[37]
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Mesenchymal Stem Cells, Bioactive Factors, and Scaffolds in Bone Repair: From Research Perspectives to Clinical Practice
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2021 |
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[38]
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A deep insight into the preparation of ceramic bone scaffolds utilizing robocasting technique
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Ceramics …,
2021 |
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[39]
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Caracterização da esponja de água doce (Metania reticulata) para uso como arcabouço de engenharia tecidual
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2020 |
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[40]
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Biopolymeric nanocomposite scaffolds for bone tissue engineering applications–A review
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2020 |
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[41]
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Revisión sistemática de la literatura sobre el uso de la Mimosa tenuiflora en tratamientos para la regeneración celular de tejidos
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Dissertation,
2020 |
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[42]
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Trends in 3D Printing Processes for Biomedical Field: Opportunities and Challenges
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2020 |
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[43]
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4D printing additive manufacturing review; Mechanisim, Chalanges, Applications and Future
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2020 |
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[44]
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An insight into cell-laden 3D-printed constructs for bone tissue engineering
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2020 |
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[45]
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Apatite mineralization process from Silicocarnotite bioceramics: Mechanism of crystal growth and maturation
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2020 |
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[46]
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Design Strategy of Three-dimensional Printed Cages to Reduce Impact-induced Debris along the Load-transferring Path
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2020 |
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[47]
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Review on current limits and potentialities of technologies for biomedical ceramic scaffolds production
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2020 |
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[48]
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In situ mineralization of nano-hydroxyapatite on bifunctional cellulose nanofiber/polyvinyl alcohol/sodium alginate hydrogel using 3D printing
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2020 |
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[49]
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Bone Tissue Engineering via Carbon‐Based Nanomaterials
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2020 |
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[50]
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3D printed tissue and organ using additive manufacturing: An overview
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2019 |
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[51]
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Additive manufacturing of polymer composites: Processing and modeling approaches
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2019 |
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[52]
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Novel design of low modulus high strength zirconia scaffolds for biomedical applications
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2019 |
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[53]
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Engineering human-scale artificial bone grafts for treating critical-size bone defects
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2019 |
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[54]
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3D printing applications in bone tissue engineering
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2019 |
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[55]
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MINISTÉRIO DA DEFESA EXÉRCITO BRASILEIRO DEPARTAMENTO DE CIÊNCIA E TECNOLOGIA INSTITUTO MILITAR DE ENGENHARIA CURSO DE …
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2019 |
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[56]
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Additive manufacturing: fundamentals and advancements
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2019 |
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[57]
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3D Tissue Modelling of Orthopaedic Tissues
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2019 |
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[58]
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3D tissue modelling of skeletal muscle tissue
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2019 |
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[59]
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Scaffold for bone tissue engineering
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Handbook of Tissue …,
2019 |
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[60]
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骨修复材料的研究现状与进展
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Chinese Journal of Reparative and …,
2018 |
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[61]
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Research status and progress of biomaterials for bone repair and reconstruction
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Zhongguo xiu fu Chong Jian wai ke za zhi …,
2018 |
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[62]
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Desarrollo de materiales biocompatibles, biodegradables y bioactivos para su aplicación en impresión FDM (modelado por deposición fundida) de implantes para …
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Dissertation,
2018 |
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[63]
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Bacterial cellulose-based scaffold materials for bone tissue engineering
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Applied Materials Today,
2018 |
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[64]
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New generation of bioreactors that advance extracellular matrix modelling and tissue engineering
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Biotechnology Letters,
2018 |
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[65]
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3D Bioprinting Technologies for Tissue Engineering Applications
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Cutting-Edge Enabling Technologies for Regenerative Medicine,
2018 |
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[66]
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Applied Materials Today
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2018 |
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[67]
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Vascularized 3D printed scaffolds for promoting bone regeneration
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Biomaterials,
2018 |
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[68]
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Polymer Nanocomposites Used as Scaffolds for Bone Tissue Regeneration
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2018 |
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[69]
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Posgrado en Materiales Poliméricos
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2018 |
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[70]
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Estudio de las propiedades mecánicas de un material compuesto laminado a base de aluminio y polipropileno modificado reforzado con fibras de aramida
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2018 |
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[71]
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Fabrication Methodologies of Biomimetic and Bioactive Scaffolds for Tissue Engineering Applications
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Scaffolds In Tissue Engineering Materials Technologies And Clinical Applications,
2017 |
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[72]
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Additive manufacturing: Scientific and technological challenges, market uptake and opportunities
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Materials Today,
2017 |
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[73]
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Porosity distribution affecting mechanical and biological behaviour of hydroxyapatite bioceramic composites
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Ceramics International,
2017 |
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[74]
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Transionospheric Microwave Propagation: Higher-Order Effects up to 100 GHz
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2017 |
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[75]
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Chapter Fabrication Methodologies of Biomimetic and Bioactive Scaffolds for Tissue Engineering Applications
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2017 |
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[76]
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Trabajo Fin de Máster
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2016 |
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[77]
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ESTUDO DE EMPILHAMENTO DE CAMADAS POR IMPRESSÃO 3D DE DEPOSIÇÃO DIRETA E EVAPORAÇÃO DE SOLVENTE
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