LEADER 06166nam  2201189z- 450 
001 9910557314603321
005 20220111
035   $a(CKB)5400000000042709
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/77117
035   $a(oapen)doab77117
035   $a(EXLCZ)995400000000042709
100   $a20202201d2021      |y         0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 00$aNumerical Simulation in Biomechanics and Biomedical Engineering
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2021
215   $a1 online resource (300 p.)
311 08$a3-0365-2211-5 
311 08$a3-0365-2212-3 
330   $aIn the first contribution, Morbiducci and co-workers discuss the theoretical and methodological bases supporting the Lagrangian- and Euler-based methods, highlighting their application to cardiovascular flows. The second contribution, by the Anso?n and van Lenthe groups, proposes an automated virtual bench test for evaluating the stability of custom shoulder implants without the necessity of mechanical testing. Urdeitx and Doweidar, in the third paper, also adopt the finite element method for developing a computational model aim to study cardiac cell behavior under mechano-electric stimulation. In the fourth contribution, Ayensa-Jime?nez et al. develop a methodology to approximate the multidimensional probability density function of the parametric analysis obtained developing a mathematical model of the cancer evolution. The fifth paper is oriented to the topological data analysis; the group of Cueto and Chinesta designs a predictive model capable of estimating the state of drivers using the data collected from motion sensors. In the sixth contribution, the Ohayon and Finet group uses wall shear stress-derived descriptors to study the role of recirculation in the arterial restenosis due to different malapposed and overlapping stent conditions. In the seventh contribution, the research group of Anto?n demonstrates that the simulation time can be reduced for cardiovascular numerical analysis considering an adequate geometry-reduction strategy applicable to truncated patient specific artery. In the eighth paper, Grasa and Calvo present a numerical model based on the finite element method for simulating extraocular muscle dynamics. The ninth paper, authored by Kahla et al., presents a mathematical mechano-pharmaco-biological model for bone remodeling. Marti?nez, Pen?a, and co-workers propose in the tenth paper a methodology to calibrate the dissection properties of aorta layer, with the aim of providing useful information for reliable numerical tools. In the eleventh contribution, Marti?nez-Bocanegra et al. present the structural behavior of a foot model using a detailed finite element model. The twelfth contribution is centered on the methodology to perform a finite, element-based, numerical model of a hydroxyapatite 3D printed bone scaffold. In the thirteenth paper, Talygin and Gorodkov present analytical expressions describing swirling jets for cardiovascular applications. In the fourteenth contribution, Schenkel and Halliday propose a novel non-Newtonian particle transport model for red blood cells. Finally, Zurita et al. propose a parametric numerical tool for analyzing a silicone customized 3D printable trachea-bronchial prosthesis.
606   $aTechnology: general issues$2bicssc
610   $a3D model
610   $a3D printing
610   $a3D scaffold
610   $aadditive manufacturing
610   $aaortic dissection
610   $abiomechanics
610   $ablood flow modelling
610   $abone disorders
610   $abone physiology
610   $abone tissue engineering
610   $acardiac cell
610   $acardiac muscle tissue
610   $acardiomyocyte
610   $acell dynamics
610   $acohesive zone model
610   $acomputational cost analysis
610   $acomputational fluid dynamics
610   $acopulas
610   $acustomized prosthesis
610   $adelamination tests
610   $adesign of experiments
610   $adivergence
610   $aelectrical stimulation
610   $aexplicit FEM
610   $afinite element analysis
610   $afinite element method
610   $afinite element modelling
610   $afixed points
610   $afoot and ankle model
610   $afoot finite element method
610   $aglioblastoma multiforme
610   $ahaemorheology
610   $ahemodynamics
610   $ahepatic artery
610   $aimplant design
610   $aimplicit FEM
610   $ain-silico
610   $aliver cancer
610   $amachine learning
610   $amalapposition
610   $amanifolds
610   $amathematical model
610   $amathematical modelling
610   $amicromotion
610   $aMorse theory
610   $aNavier-Stokes equations
610   $anumerical fluid mechanics
610   $aoverlap
610   $aparametric model
610   $aparticle transport
610   $apatient specific
610   $apersonalized medicine
610   $aplantar pressure
610   $aporcine aorta
610   $apotential swirling flow
610   $aradioembolization
610   $areverse shoulder arthroplasty
610   $aseparated mesh
610   $ashared nodes
610   $ashoulder implant stability
610   $askeletal muscle
610   $asmart driving
610   $astenosis
610   $astent
610   $athrombosis
610   $atime series
610   $atopological data analysis
610   $atornado-like jets
610   $atracheobronchial stent
610   $aunsteady swirling flow
610   $avascular mechanics
615  7$aTechnology: general issues
700   $aMalvè$b Mauro$4edt$01289210
702   $aMalvè$b Mauro$4oth
906   $aBOOK
912   $a9910557314603321
996   $aNumerical Simulation in Biomechanics and Biomedical Engineering$93021089
997   $aUNINA