about
Micro-CT vs. Whole Body Multirow Detector CT for Analysing Bone Regeneration in an Animal Model.Micro-computed tomography: a method for the non-destructive evaluation of the three-dimensional structure of biological specimens.Time-lapsed investigation of three-dimensional failure and damage accumulation in trabecular bone using synchrotron light.Volumetric spatial decomposition of trabecular bone into rods and plates--a new method for local bone morphometry.A multiscale imaging and modelling dataset of the human inner earEffects of μCT radiation on tissue engineered bone-like constructs.Vertebral body bone strength: the contribution of individual trabecular element morphology.Patient-specific estimation of detailed cochlear shape from clinical CT images.A finite element beam-model for efficient simulation of large-scale porous structures.A sensitivity analysis of the volumetric spatial decomposition algorithm.Automatic registration of 2D histological sections to 3D microCT volumes: Trabecular bone.Automated 3D-2D registration of X-ray microcomputed tomography with histological sections for dental implants in bone using chamfer matching and simulated annealing.Fast estimation of Colles' fracture load of the distal section of the radius by homogenized finite element analysis based on HR-pQCT.Ultrastructural properties in cortical bone vary greatly in two inbred strains of mice as assessed by synchrotron light based micro- and nano-CT.Specimen-specific beam models for fast and accurate prediction of human trabecular bone mechanical properties.Importance of individual rods and plates in the assessment of bone quality and their contribution to bone stiffness.Improved anchorage in osteoporotic vertebrae with new implant designs.Regional, age and gender differences in architectural measures of bone quality and their correlation to bone mechanical competence in the human radius of an elderly population.The interaction of microstructure and volume fraction in predicting failure in cancellous bone.Image interpolation allows accurate quantitative bone morphometry in registered micro-computed tomography scansSoil and macro-pores under uniaxial compression. I. Mechanical stability of repacked soil and deformation of different types of macro-poresFunctional microimaging: an integrated approach for advanced bone biomechanics and failure analysisChanges in the macro-pore structure of restored soil caused by compaction beneath heavy agricultural machinery: a morphometric studyFunctional Micro-imaging at the Interface of Bone Mechanics and BiologyMicromechanical evaluation of bone microstructures under loadTelomere length, telomerase activity and osteogenic differentiation are maintained in adipose-derived stromal cells from senile osteoporotic SAMP6 mice.Microstructural volumetric analysis of lateral ridge augmentation using differently conditioned tooth rootsCorrigendum to “A new method for preparing tannin-based foams” [Ind. Crops Prod. 54, 40–53]Latest progresses in the preparation of tannin-based cellular solidsA new method for preparing tannin-based foamsCarbon meringues derived from flavonoid tanninsTime-lapsed assessment of microcrack initiation and propagation in murine cortical bone at submicrometer resolutionThe importance of murine cortical bone microstructure for microcrack initiation and propagationLimitations of global morphometry in predicting trabecular bone failureThree-dimensional assessment of crestal bone levels at titanium implants with different abutment microstructures and insertion depths using micro-computed tomography
P50
Q36202461-68A53BDE-3A80-4E30-A790-3F279491B165Q37157296-5F9E9A56-324A-43FB-BEC2-8F94EDB31F0FQ40342646-E7CCD895-897D-498A-9CFF-4A47D5613E5EQ40366731-C045670A-15ED-47CF-8CB2-D8283F9ACF47Q41678426-CA8C8C66-AD80-4851-9BC5-E233B452025EQ42825448-95C96E7D-4A92-4EE7-876F-AA4BD79C25BEQ44442393-A246C95D-1D2B-4D6A-B963-FA53F36A5F77Q47197444-479B4D88-A770-4F37-803B-E7AB312BFE22Q47203428-3F18BA1D-1242-49D0-B045-92F63B569D82Q47434846-F257A2AA-8949-467B-8087-FD197DB5CB33Q47702287-D7DA487C-FA25-42B8-84D5-425F7905C911Q50906429-451E6FFF-BDC3-42B4-A766-3311007F35F6Q50961097-879B5D60-4FEB-44CC-B5F9-C3EFB9BB2864Q50963649-802FC199-48AE-4017-8942-3F5E7554EFF5Q51137904-89EA2E44-570D-4679-9A01-E4AE277F2BFDQ51232522-61048087-4924-458A-B0D3-1375825BC24CQ51235427-37E1A96F-906A-4954-82C2-D7E1D5FB1755Q53343610-45B569F8-657B-4006-9975-2DB4590B3563Q53523830-C2927DD9-89BB-4C1C-825D-D48A11AA41A6Q53527964-8DBD0C7F-85C6-4ABA-A8F4-67054A27F3B0Q53528246-2D832BCF-B497-4571-A565-78861796E2C8Q53528253-17F54028-89E1-41B9-BCB4-EAADC7D58E65Q53528267-EEC9A8FC-BFD8-41F4-AE29-6C4577648A52Q53528349-0D6826F0-3FDC-49F5-9D1E-76BEE7D3C27DQ53528450-CDCA4E44-0147-483A-B30E-092CF56918C7Q54578480-1B5EE7A4-DD06-4C3A-BE31-C57836E16994Q58562888-FCDDBC7C-ABA7-462B-873B-7186F32E28F2Q60157513-2ACA941D-1C14-4B38-AEAC-1334A2288FF1Q60157589-B9AF35D8-D5BC-4B27-921F-6E94613CA08CQ60157610-E07130A2-7E23-4F92-8C74-001EB19751FBQ60157685-2FE5D2DD-454B-4979-AA44-BF8A5A60839AQ83761362-5036C050-0475-4A89-BD38-F266DBB9BCAEQ84872589-B8FDAE79-AE5E-4C29-B980-F99262B30466Q86942300-E0218AA6-1B58-478C-8CD5-57FC6D7C89ABQ87907054-1B36B5DF-21BA-405A-B34B-12E7B0468A1B
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Martin Stauber
@ast
Martin Stauber
@en
Martin Stauber
@es
Martin Stauber
@nl
Martin Stauber
@sl
type
label
Martin Stauber
@ast
Martin Stauber
@en
Martin Stauber
@es
Martin Stauber
@nl
Martin Stauber
@sl
prefLabel
Martin Stauber
@ast
Martin Stauber
@en
Martin Stauber
@es
Martin Stauber
@nl
Martin Stauber
@sl
P106
P1153
8226493800
P31
P496
0000-0003-4285-4146