Search results for "1502 Bioengineering"

showing 2 items of 2 documents

Angular Trapping of Anisometric Nano-Objects in a Fluid

2012

We demonstrate the ability to trap, levitate, and orient single anisometric nanoscale objects with high angular precision in a fluid. An electrostatic fluidic trap confines a spherical object at a spatial location defined by the minimum of the electrostatic system free energy. For an anisometric object and a potential well lacking angular symmetry, the system free energy can further strongly depend on the object's orientation in the trap. Engineering the morphology of the trap thus enables precise spatial and angular confinement of a single levitating nano-object, and the process can be massively parallelized. Since the physics of the trap depends strongly on the surface charge of the objec…

10120 Department of ChemistryOptics and Photonics3104 Condensed Matter PhysicsSilverMaterials scienceMacromolecular SubstancesSurface PropertiesStatic Electricity2210 Mechanical EngineeringMetal Nanoparticles1600 General ChemistryBioengineeringTrap (computing)OpticsOrientation (geometry)540 ChemistryNano-ElectrochemistryNanotechnologyScattering RadiationGeneral Materials ScienceFluidicsSurface chargeParticle Size1502 Bioengineeringbusiness.industryPhysicsMechanical EngineeringElectrostatic unitsDNAGeneral ChemistryCondensed Matter Physics2500 General Materials ScienceSymmetry (physics)KineticsHydrodynamicsLevitationAnisotropybusinessNano Letters
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Histological and histomorphometrical analysis of a silica matrix embedded nanocrystalline hydroxyapatite bone substitute using the subcutaneous impla…

2010

The clinical suitability of a bone substitute material is determined by the ability to induce a tissue reaction specific to its composition. The aim of this in vivo study was to analyze the tissue reaction to a silica matrix-embedded, nanocrystalline hydroxyapatite bone substitute. The subcutaneous implantation model in Wistar rats was chosen to assess the effect of silica degradation on the vascularization of the biomaterial and its biodegradation within a time period of 6 months. Already at day 10 after implantation, histomorphometrical analysis showed that the vascularization of the implantation bed reached its peak value compared to all other time points. Both vessel density and vascula…

Materials scienceBone substituteBiomedical Engineering2204 Biomedical EngineeringBioengineering610 Medicine & healthBiomaterialsSubcutaneous TissueIn vivoAbsorbable ImplantsMaterials TestingAnimalsRats WistarBone regeneration11077 Center for Applied Biotechnology and Molecular Medicine1502 Bioengineering2502 BiomaterialsBiomaterialSilicon DioxideNanocrystalline materialRatsDrug CombinationsDurapatiteGiant cellSilica matrixBone SubstitutesSubcutaneous implantationNanoparticlesFemaleBiomedical engineeringBiomedical materials (Bristol, England)
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