2010
DOI: 10.1016/j.cma.2009.09.017
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A nested dynamic multi-scale approach for 3D problems accounting for micro-scale multi-physics

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Cited by 18 publications
(8 citation statements)
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“…For this reason we are working on including the presented simulations within a multiscale approach for alveolar ensemble. 33 This allows us to project the global parenchymal deformation down to the level of a single alveolar ensemble in order to provide realistic boundary conditions. This method has the advantage that we will be able to measure local alveolar strain fields in large geometries, for example living precision cut rat lung slices (PCLS).…”
Section: Discussionmentioning
confidence: 99%
“…For this reason we are working on including the presented simulations within a multiscale approach for alveolar ensemble. 33 This allows us to project the global parenchymal deformation down to the level of a single alveolar ensemble in order to provide realistic boundary conditions. This method has the advantage that we will be able to measure local alveolar strain fields in large geometries, for example living precision cut rat lung slices (PCLS).…”
Section: Discussionmentioning
confidence: 99%
“…Unit cell models have been used to analyze the response of idealized polyhedral cells to mechanical loading (Ko, 1965;Takishima and Mead, 1972;Wilson and Bachofen, 1982). Unit cell models of lung parenchyma have been proposed by Kimmel and co-workers (Kimmel and Budiansky, 1990;Kimmel et al, 1987), who analyzed a pentagonal dodecahedral cell, and by Denny and Schroter (1995, 2000, who analyzed tetrakaidecahedral cells, and more recently by Wiechert and Wall (2010), who used micro scale multi-physics approach to analyze tetrakaidecahedral cells. Here we present an analysis of random Voronoi structure that is likely to represent more accurately the human lung in both the healthy and injured states, and compare it with results from hexagonal honeycombs and continuum approximations.…”
Section: Strainmentioning
confidence: 99%
“…As already mentioned before, the algorithms discussed in Sections 2 and 3 are by no means restricted to any specific discretization scheme or solution technique. Furthermore, arbitrary constitutive laws including poroelastic models (cf., for instance, ) and multi‐scale approaches (see, e.g., ) may be utilized to describe the behavior of the tissue under consideration as accurately as possible.…”
Section: Discussionmentioning
confidence: 99%