DISSIPATION ENERGY AS A STIMULUS FOR CORTICAL BONE ADAPTATION

Tipo de material: Texto

TextoSeries ; Journal of Mechanics of Materials and Structures, 6, p.303-319, 2011Trabajos contenidos:

Natarajan Chennimalai Kumar
Iwona Jasiuk And Jonathan Dantzig

Recursos en línea:

Para ver el documento ingresa a Google con tu cuenta: @cicy.edu.mx

Resumen: We present a finite element study of a poroelastic rectangular beam subjected to oscillatory bending loads. This geometric model is chosen for simplicity, as an idealized representation of cortical bone. We then propose the use of the dissipation energy of the poroelastic flow as a mechanical stimulus for bone adaptation, and show that it can predict the effect of frequency of the applied load. Surface adaptation in the model depends on the weighted average of the mechanical stimulus in a "zone of influence" near each surface point, in order to incorporate the non-locality in the mechanotransduction of osteocytes present in the lacunae. We show that the dissipation energy stimulus and the resulting increase in second moment of inertia of the cross section increase linearly with frequency in the low frequency range (less than 10 Hz)and saturate at the higher frequency range (greater than 10 Hz). Similar non-linear adaptation frequency response also has been observed in numerous experiments. Our framework is readily extended to the modeling of cortical bone using actual bone geometries.

Tags from this library: No tags from this library for this title. Log in to add tags.

Average rating: 0.0 (0 votes)

Holdings
Item type	Current library	Collection	Call number	Status	Date due	Barcode
Documentos solicitados	CICY Documento préstamo interbibliotecario	Ref1	B-13502 (Browse shelf(Opens below))	Available

Browsing CICY shelves, Shelving location: Documento préstamo interbibliotecario, Collection: Ref1 Close shelf browser (Hides shelf browser)

Previous	No cover image available	No cover image available	No cover image available	No cover image available	No cover image available	No cover image available	No cover image available	Next
Previous	B-1350 Collagen Polypeptides and Reactive Butadiene and Acrylic Co-Polymers in a Disperse System- A Composite Material for Filling and Strengthening Loose Grain Leathers	B-13500 Modeling of cortical bone adaptation in a rat ulna: Effect of frequency	B-13501 Recent advances on the measurement and calculation of the elastic moduli of cortical and trabecular bone: a review	B-13502 DISSIPATION ENERGY AS A STIMULUS FOR CORTICAL BONE ADAPTATION	B-13503 Characterisation of microstructure and mechanical properties of cermets at micro- and nanoscales	B-13504 Multi-scale characterization of swine femoral cortical bone	B-13505 Pore size of microporous polymer membranes	Next

We present a finite element study of a poroelastic rectangular beam subjected to oscillatory bending loads. This geometric model is chosen for simplicity, as an idealized representation of cortical bone. We then propose the use of the dissipation energy of the poroelastic flow as a mechanical stimulus for bone adaptation, and show that it can predict the effect of frequency of the applied load. Surface adaptation in the model depends on the weighted average of the mechanical stimulus in a "zone of influence" near each surface point, in order to incorporate the non-locality in the mechanotransduction of osteocytes present in the lacunae. We show that the dissipation energy stimulus and the resulting increase in second moment of inertia of the cross section increase linearly with frequency in the low frequency range (less than 10 Hz)and saturate at the higher frequency range (greater than 10 Hz). Similar non-linear adaptation frequency response also has been observed in numerous experiments. Our framework is readily extended to the modeling of cortical bone using actual bone geometries.

There are no comments on this title.

to post a comment.