Computational modeling of specific biological structures behavior

Milić‐Lemić, Aleksandra; Tihaček-Šojić, Ljiljana; Ilic, Jana; Živković, Rade

doi:10.2298/avb0604367l

Acta vet. (Beogr.)

2006

DOI: 10.2298/avb0604367l

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Computational modeling of specific biological structures behavior

Aleksandra Milić‐Lemić¹,

Ljiljana Tihaček-Šojić²,

Jana Ilic³

et al.

Abstract: Biomechanical experimental studies are often a subject of interest to many researchers. The results of such investigations give a full insight of complex structural behavior under loading, visualize potential material weaknesses and evaluate if mechanical factors play a substantial role in the pathogenesis of the lesions of the investigated biological structure. The use of FEM enables most of the researchers to abandon the experimental animal models and expand the investigation on computational models, analyzi… Show more

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Cited by 2 publications

References 17 publications

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Anatomically based 3D geometric modeling of specific biological structures

Tihaček-Šojić¹,

Aleksandra²,

Živković³

et al. 2007

Acta vet. (Beogr.)

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Mechanical behavior of biological structures is a common subject of scientific research. The results of such investigations offer the precise insight into the biomechanical properties of biological structures and are usefull for predicting their behavior when subjected to loading. Although, such biomechanical investigations were conducted on experimental animals nowadays are very popular investigations concerning mathematical experimental models. The most common is the finite element method analysis. A digital model of a structure of interest has to be created for an investigation with the finite element method. Once the digital model is created with the use of computer technology numerous changes of elements and structures are possible, with different applications of the simulated load. The aim of this paper was to to present the development of our own three-dimensional tooth model created for finite element analyses of intact tooth behavior under functional loading. Also, the idea was to evaluate the possibility for using finite element analysis in veterinary biomechanical research. Our own 3D model was created using computer software according to available literature data, and facts gained from freshly extracted intact teeth and plaster models. It is necessary to emphasize that FEM is an effective tool that has been adapted from the engineering arena to biomechanic research and has the potential to contribute to the growing scientific basis of knowledge in veterinary dentistry

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Anatomically based 3D geometric modeling of specific biological structures

Tihaček-Šojić¹,

Aleksandra²,

Živković³

et al. 2007

Acta vet. (Beogr.)

Self Cite

View full text Add to dashboard Cite

show abstract

Biomechanical aspect of feline dental resorptive lesions formation

Živković¹,

Milić‐Lemić²,

Tihaček-Šojić³

et al. 2010

Acta vet. (Beogr.)

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Feline dental resorptive lesions affect more than one third of all adult domestic cats and continue to be an enigma in the veterinary dental science although different theories about the pathogenesis of these lesions have been proposed. Recently, a hypothesis was introduced that local mechanical trauma could be an important factor in the initiation of feline dental resorptive lesions and that there is a correlation between the occurrence of resorptive lesions and occlusal trauma in cats. The aim of this study was to analyse stress distribution in feline tooth during occlusal loading in order to accept or reject the hypothesis that dental resorptive lesions in cats might be caused by occlusal trauma. A solid model of feline tooth had to be created in order to perform the investigation. The idea was to gain data for tooth displacement (deformation) and stress and strain distribution under loading generally for any feline tooth using the finite element method. The results of the study contribute to the theory that occlusal overload might be one of the causes in multifactorial resorptive lesions in cats. Succession of tensile and compressive stresses and tooth displacement during occlusal loading might be a contributive factor in the pathogenesis of feline resorptive lesions. However, further research is required to confirm this statement

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Computational modeling of specific biological structures behavior

Cited by 2 publications

References 17 publications

Anatomically based 3D geometric modeling of specific biological structures

Anatomically based 3D geometric modeling of specific biological structures

Biomechanical aspect of feline dental resorptive lesions formation

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