Mechanical properties of the human scalp in tension

Falland-Cheung, L.; Scholze, M.; Lozano, P. F.; Ondruschka, B.; Tong, D. C.; Brunton, P. A.; Waddell, J. N.; Hammer, N.

doi:10.1016/j.jmbbm.2018.05.024

Mechanical properties of the human scalp in tension (bibtex)

by L. Falland-Cheung, M. Scholze, P. F. Lozano, B. Ondruschka, D. C. Tong, P. A. Brunton, J. N. Waddell, N. Hammer

Abstract:

Mechanical properties of the human scalp have not been investigated to a great extent with limited information available. The purpose of this study was to provide new baseline material data for human scalp tissue of various ages, which can be applied to experimental and constitutive models, such as in the area of impact biomechanics. This study used specimens from the left and right temporal, fronto-parietal and occipital regions of the human scalp. It investigated the tensile behavior of scalp tissue using tissues harvested from unfixed, fresh cadavers. These samples were subjected to an osmotic stress analysis and upon testing, cyclic loading followed by stretching until failure in a universal testing machine. Strain evaluation was conducted using digital image correlation in a highly standardized approach. Elastic modulus, tensile strength, strain at maximum load and strain to failure were evaluated computationally. No significant differences were observed comparing the tensile strength between males and females. In contrast to that, a sex-dependent difference was found for the elastic modulus of the occipital scalp region and for the elongation properties. Additionally, regional differences within the male group, as well as an age dependent correlation for females were found in the elastic modulus and tensile strength. Scanning electron microscope analyses have shown the ultrastructural failure patterns, indicated by damaged keratin plates, as well as partially disrupted and retraced collagens at the failure site. The novel data obtained in this study could add valuable information to be used for modeling purposes, as well as provide baseline data for simulant materials and comparisons of tissue properties following head injury or forensic investigations.

Reference:

Falland-Cheung, L., Scholze, M., Lozano, P. F., Ondruschka, B., Tong, D. C., Brunton, P. A., Waddell, J. N., Hammer, N.: Mechanical properties of the human scalp in tension, Journal of the Mechanical Behavior of Biomedical Materials 84, 188-197, 2018.

Bibtex Entry:

@Article{Falland-Cheung2018a,
author = {Falland-Cheung, L. and Scholze, M. and Lozano, P. F. and Ondruschka, B. and Tong, D. C. and Brunton, P. A. and Waddell, J. N. and Hammer, N.},
title = {Mechanical properties of the human scalp in tension},
journal = {Journal of the Mechanical Behavior of Biomedical Materials},
year = {2018},
volume = {84},
pages = {188--197},
month = {aug},
abstract = {Mechanical properties of the human scalp have not been investigated to a great extent with limited information available. The purpose of this study was to provide new baseline material data for human scalp tissue of various ages, which can be applied to experimental and constitutive models, such as in the area of impact biomechanics. This study used specimens from the left and right temporal, fronto-parietal and occipital regions of the human scalp. It investigated the tensile behavior of scalp tissue using tissues harvested from unfixed, fresh cadavers. These samples were subjected to an osmotic stress analysis and upon testing, cyclic loading followed by stretching until failure in a universal testing machine. Strain evaluation was conducted using digital image correlation in a highly standardized approach. Elastic modulus, tensile strength, strain at maximum load and strain to failure were evaluated computationally. No significant differences were observed comparing the tensile strength between males and females. In contrast to that, a sex-dependent difference was found for the elastic modulus of the occipital scalp region and for the elongation properties. Additionally, regional differences within the male group, as well as an age dependent correlation for females were found in the elastic modulus and tensile strength. Scanning electron microscope analyses have shown the ultrastructural failure patterns, indicated by damaged keratin plates, as well as partially disrupted and retraced collagens at the failure site. The novel data obtained in this study could add valuable information to be used for modeling purposes, as well as provide baseline data for simulant materials and comparisons of tissue properties following head injury or forensic investigations.},
doi = {10.1016/j.jmbbm.2018.05.024},
publisher = {Elsevier {BV}},
}