The Effect of Mechanical Constraints on Gelatin Samples under Pulsatile Flux

Eugenia Blangino; Martín A. Cagnoli; Ramiro M. Irastorza; Fernando Vericat

doi:10.4028/www.scientific.net/MSF.706-709.449

Paper Titles

Effects of Microstructures on Fatigue Behavior of an Al-Mg-Sc Alloy at an Elevated Temperature
p.426

Investigation of Quench Sensitivity of an Al-7.5Zn-1.7Mg-1.4Cu-0.12Zr Alloy
p.431

Deformability of Eutectic Al-Si Alloys Produced by Semi-Continuously DC Casting during Hot-Rolling
p.436

Coatings of Ti and TiO₂ with Defined Roughness for Implants by Gas Flow Sputtering
p.443

The Effect of Mechanical Constraints on Gelatin Samples under Pulsatile Flux
p.449

Mechanical Properties of Thermomechanically-Processed Metastable Beta Ti-Nb-Zr Alloys for Biomedical Applications
p.455

Development of a Collagen/Clay Nanocomposite Biomaterial
p.461

Applications of Ceramic Nanoparticles in Nanomedicine
p.467

Dynamic Recrystallization of Biomedical Co-Cr-W-Ni (L-605) Alloy
p.472

HomeMaterials Science ForumMaterials Science Forum Vols. 706-709The Effect of Mechanical Constraints on Gelatin...

The Effect of Mechanical Constraints on Gelatin Samples under Pulsatile Flux

Abstract:

It is of great interest in tissue engineering the role of collagen gel-based structures (scaffolds, grafts and-by cell seeded and maturation-tissue equivalents (TEs) for several purposes). It is expected the appropriate biological compatibility when the extracellular matrix (ECM) is collagen-based. Regarding the mechanical properties (MP), great efforts in tissue engineering are focused in tailoring TE properties by controlling ECM composition and organization. When cells are seeded, the collagen network is remodeled by cell-driven compaction and consolidation, produced mainly through the mechanical stimuli that can be directed selecting the geometry and the surfaces exposed to the cells. Collagen gels have different (chemical and mechanical) properties depending on their origin and preparation conditions. The MP of the collagen network are derived from the degree of cross-linking (CLD) which can be modified by different treatments. One of the techniques to evaluate MP in the network is by ultrasound (US). In this work we analyse the effect of several mechanical constraints (similar to that imposed to promote cell growth on certain sample surfaces, when seeded) on samples of gelatin with a specific geometry (thick walls cylinders) under loading conditions of pulsatile flow. We checked US parameters and estimates evolution of the network structure for different restrictions in the sample mobility. It was implemented by adapting devices specially built to measure elastic properties of biological tissues by US. The material (origin and purity) and the preparation conditions for the gelatin were selected in order to compare the results with those of literature.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Materials Science Forum (Volumes 706-709)

Pages:

449-454

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.706-709.449

Citation:

Cite this paper

Online since:

January 2012

Authors:

Eugenia Blangino, Martín A. Cagnoli, Ramiro M. Irastorza, Fernando Vericat

Keywords:

Gelatin Tubes, Mobility Constraints, Pulsatile Flow, Ultrasound Measurements

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Bigi, A., Panzavolta, S., Rubini, K., Relationship between triple-helix content and mechanical properties of gelatin films, Biomaterials 25 (2004) 5675-5680.

DOI: 10.1016/j.biomaterials.2004.01.033

Google Scholar

[2] Binsi,P., Shamasundar, B., Dileep, A., Badii, F., Howel, N., Rehological and functional properties of gelatin from skin of Bigeye snapper fish: Influence of gelatin on the gel forming ability of fish mince, Food Hydrocolloids 23 (2009) 132-145.

DOI: 10.1016/j.foodhyd.2007.12.004

Google Scholar

[3] Pryse, K., Nekouzadeh, A., Genin, G., Elson, E., Zahalak, G., Incremental Mechanics of Collagen Gels: New experiments and a New Viscoelastic Model, Annals of Biomechanical Engineering, Vol. 31 (2003) 1287-1298.

DOI: 10.1114/1.1615571

Google Scholar

[4] Madsen, E., Frank,G., Krouskop, T., Varghese, T., Kallel, F., Ophir, J., Tissue-mimicking Oil-in-Gelatin Dispersions for use in Heterogeneous Elastography Phantoms, Ultrasonic Imaging 25 (2003) 17-38.

DOI: 10.1177/016173460302500102

Google Scholar

[5] Hall, T., Bilgen, M., Insana, M., Krouskop, T., Phantom Materials for Elastography, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, Vol. 44, No. 6 (1997) 1355-1365.

DOI: 10.1109/58.656639

Google Scholar

[6] Insana, M., Hall, T., Chaturverdi, P., Kargel, C., Ultrasonic Properties of Random Media under Uniaxial Loading, J. Acoustic Soc. Am. 110 (6) (2001) 3243-3251.

DOI: 10.1121/1.1414703

Google Scholar

[7] Sionkowska, A., Kaminska, A., Thermal helix-coil transition in UV irradiated collagen from rat tail tendon, International Journal of Biological Macromolecules 24 (1999) 337-340.

DOI: 10.1016/s0141-8130(99)00047-1

Google Scholar

[8] Sanders,E., Baroccas, V., Biomimetic Collagen Tissues: Collagenous Tissue Engineering and Other Applications, ch 17 in Collagen Structures and Mechanics, P. Fraztl Editor, Springer Verlag, eISBN 978-0-387-73906-9. (2008).

Google Scholar

[9] Chandran, P., Barocas, V., Microstructural Mechanics of Collagen Gels in Confined Compression: Poroelasticity, Viscoelasticity and Collapse, Trnasactions of the ASME, Vol. 126 (2004) 152-166.

DOI: 10.1115/1.1688774

Google Scholar