PEDRO MIRANDA GONZÁLEZ

Literals

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  • 1345231
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  • A0500-CATEDRÁTICO DE UNIVERSIDAD
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  • TIEMPO COMPLETO
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  • PEDRO
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  • 32
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  • MIRANDA GONZÁLEZ
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  • PEDRO MIRANDA GONZÁLEZ
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  • 000000034348110X
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  • 7103332543

Typed Literals

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Relations

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  • BIOMATERIALES
  • COMPORTAMIENTO MECÁNICO DE LOS MATERIALES
  • REUTILIZACIÓN, RECUPERACIÓN Y RECICLADO DE MATERIALES
  • BIOMATERIALES
  • BIOMATERIALES
  • BIOMATERIALES
  • COMPORTAMIENTO MECÁNICO DE LOS MATERIALES
  • COMPORTAMIENTO MECÁNICO DE LOS MATERIALES
  • FUNDAMENTOS DE CIENCIA DE MATERIALES
  • FUNDAMENTOS DE CIENCIA DE MATERIALES
  • FUNDAMENTOS DE CIENCIA DE MATERIALES
  • FUNDAMENTOS DE CIENCIA DE MATERIALES
  • INGENIERÍA DE MATERIALES
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• ou:tienePublicacion
  • A simple graphite-based support material for robocasting of ceramic parts
  • A simple recipe for direct writing complex 45S5 Bioglass^® 3D scaffolds
  • An improved correlation between impression and uniaxial creep
  • Applicability of near-field electrospinning for the development of TCP-based thin fibres and scaffold 3D printing
  • Application of hertzian tests to measure stress-strain characteristics of ceramics at elevated temperatures
  • Bioceramic scaffolds fabrication: Indirect 3D printing combined with ice-templating vs. robocasting
  • Bioinspired channeled, rhBMP-2-coated β-TCP scaffolds with embedded autologous vascular bundles for increased vascularization and osteogenesis of prefabricated tissue-engineered bone
  • Bioinspired composite segmented armour: Numerical simulations
  • Biological properties of solid free form designed ceramic scaffolds with bmp-2: In vitro and in vivo evaluation
  • Biphasic calcium phosphate scaffolds fabricated by direct write assembly: Mechanical, anti-microbial and osteoblastic properties
  • Case study: Reinforcement of 45S5 bioglass robocast scaffolds by HA/PCL nanocomposite coatings
  • Clarifying the effect of sintering conditions on the microstructure and mechanical properties of β-tricalcium phosphate
  • Co-continuous calcium phosphate/polycaprolactone composite bone scaffolds fabricated by digital light processing and polymer melt suction
  • Combined empirical-analytical method for determining contact radius and indenter displacement during Hertzian indentation on coating/substrate systems
  • Contact fracture of brittle bilayer coatings on soft substrates
  • Contact properties of yttria partially stabilized zirconia up to 1000°C
  • Controlled preparation and characterization of multilayer sol-gel zirconia dip-coatings
  • Cracking in ceramic/metal/polymer trilayer systems
  • Designing damage-resistant brittle-coating structures: I. Bilayers
  • Designing damage-resistant brittle-coating structures: II. Trilayers
  • Development by robocasting and mechanical characterization of hybrid HA/PCL coaxial scaffolds for biomedical applications
  • Effect of Flaw State on the Strength of Brittle Coatings on Soft Substrates
  • Effect of an adhesive interlayer on the fracture of a brittle coating on a supporting substrate
  • Effect of microstructure on the mechanical properties of liquid-phase-sintered silicon carbide at pre-creep temperatures
  • Effect of milling media on processing and performance of 13-93 bioactive glass scaffolds fabricated by robocasting
  • Effect of polymer infiltration on the flexural behavior of β-tricalcium phosphate robocast scaffolds
  • Effect of sol-gel thin coatings on the fracture strength of glass
  • Effect of temperature on the pre-creep mechanical properties of silicon nitride
  • Effect of the drying process on the compressive strength and cell proliferation of hydroxyapatite-derived scaffolds
  • Elastic Modulus of Woven Bone: Correlation with Evolution of Porosity and X-ray Greyscale
  • Elucidating the role of 45S5 bioglass content in the density and flexural strength of robocast β-TCP/45S5 composites
  • Enhancing the mechanical and in vitro performance of robocast bioglass scaffolds by polymeric coatings: Effect of polymer composition
  • Evaluating the suitability of fast sintering techniques for the consolidation of calcium phosphate scaffolds produced by DLP
  • Evaluation of direct light processing for the fabrication of bioactive ceramic scaffolds: Effect of pore/strut size on manufacturability and mechanical performance
  • Fabricating geometrically-complex B<inf>4</inf>C ceramic components by robocasting and pressureless spark plasma sintering
  • Fabrication and Characterization of 3D-printed Antibacterial Bioactive Glass /Polycaprolactone Nanocomposite Scaffolds
  • Fabrication of porous hydroxyapatite scaffolds
  • Finite element modeling as a tool for predicting the fracture behavior of robocast scaffolds
  • Fracture modes under uniaxial compression in hydroxyapatite scaffolds fabricated by robocasting
  • Fracture of ceramic/ceramic/polymer trilayers for biomechanical applications
  • Hertzian indentation of a ZrB<inf>2</inf>-30% SiC ultra-high-temperature ceramic up to 800°C in air
  • Impact of residual carbon after DLP and SPS-Sintering on compressive strength and in-VITRO bioactivity of calcium phosphate scaffolds
  • Impregnation of β-tricalcium phosphate robocast scaffolds by in situ polymerization
  • Improving mechanical properties of 13-93 bioactive glass robocast scaffold by poly (lactic acid) and poly (ε-caprolactone) melt infiltration
  • Improving the compressive strength of bioceramic robocast scaffolds by polymer infiltration
  • Improving the strength of β-TCP scaffolds produced by Digital Light Processing using two-step sintering
  • Influence of sintering temperature on the mechanical properties of ε-PCL-impregnated 45S5 bioglass-derived scaffolds fabricated by robocasting
  • Influence of zirconia sol-gel coatings on the fracture strength of brittle materials
  • Label-free magnetic resonance imaging to locate live cells in three-dimensional porous scaffolds
  • Master curves for Hertzian indentation on coating/substrate systems
  • Mechanical behaviour under uniaxial compression of robocast calcium phosphate scaffolds
  • Mechanical characterization of materials for dental applications
  • Mechanical characterization via nanoindentation of the woven bone developed during bone transport
  • Mechanical properties of calcium phosphate scaffolds fabricated by robocasting
  • Modeling of contact-induced radial cracking in ceramic bilayer coatings on compliant substrates
  • Novel bioinspired composites fabricated by robocasting for dental applications
  • Novel strategy for toughening robocast bioceramic scaffolds using polymeric cores
  • Overview: Damage in brittle layer structures from concentrated loads
  • Poly-(lactic acid) infiltration of 45S5 Bioglass® robocast scaffolds: Chemical interaction and its deleterious effect in mechanical enhancement
  • Prefabricated 3D-Printed Tissue-Engineered Bone for Mandibular Reconstruction: A Preclinical Translational Study in Primate
  • Preparation of porous hydroxyapatite scaffolds
  • Rate effects in critical loads for radial cracking in ceramic coatings
  • Reinforcement with reduced graphene oxide of bioactive glass scaffolds fabricated by robocasting
  • Reinforcing 13–93 bioglass scaffolds fabricated by robocasting and pressureless spark plasma sintering with graphene oxide.
  • Reinforcing bioceramic scaffolds with in situ synthesized ε-polycaprolactone coatings
  • Robocast 45S5 bioglass scaffolds: in vitro behavior
  • Robocasting of 45S5 bioactive glass scaffolds for bone tissue engineering
  • Role of flaw statistics in contact fracture of brittle coatings
  • Sintering and robocasting of β-tricalcium phosphate scaffolds for orthopaedic applications
  • Temperature dependence of mechanical properties of alumina up to the onset of creep
  • Two different techniques used in the production of foam structures: 3D printing and glass foaming
  • Understanding the role of dip-coating process parameters in the mechanical performance of polymer-coated bioglass robocast scaffolds
  • Using ductile cores for enhancing the mechanical performance of hollow strut β-TCP scaffolds fabricated by digital light processing
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• ou:perteneceAGrupoInvestigacion
  • Grupo Especializado de Materiales
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  • CIENCIAS DE MATERIALES E INGENIERÍA METALÚRGICA
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  • Escuela De Ingenierías Industriales
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  • INGENIERÍA MECÁNICA, ENERGÉTICA Y DE LOS MATERIALES

Inverse Relations

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  • Diseño De Materiales Multicapa Resistentes Al Daño Por Contacto
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  • Desarrollo Y Optimización Mecánica De Andamiajes Híbridos Coaxiales Cerámico/Polímero Para Aplicaciones Biomédicas
  • Desarrollo Y Optimización Microestructural Y Mecánica De Andamiajes Biocerámicos Para Ingeniería De Tejido Óseo Fabricados Mediante Moldeo Robotizado
  • Diseño Y Fabricación Mediante Moldeo Robotizado De Materiales Compuestos Cerámico/Polímero Bioactivos Para Aplicaciones En Implantes Óseos
  • Efecto De Parámetros Geométricos En Las Prestaciones Mecánicas De Estructuras Porosas Cerámicas Y Estructuras Híbridas Interpenetradas Cerámico/Polímero Fabricadas Mediante Moldeo Robotizado.
  • Efecto Del Recubrimiento En El Comportamiento Mecánico Y La Bioactividad De Andamiajes Biocerámicos Fabricados Mediante Modelo Robotizado
  • Fabricación Mediante Moldeo Robotizado Y Optimización Mecánica De Andamiajes Vitrocerámicos Bioactivos Para Ingeniería De Tejidos.
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• Has related: ou:inventor
  • ANDAMIAJE HÍBRIDO BIOACTIVO, MÉTODO DE FABRICACIÓN Y USO PARA INGENIERÍA DE TEJIDO ÓSEO

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