Suction based mechanical characterization of superficial facial soft tissues

Abstract The present study is aimed at a combined experimental and numerical investigation of the mechanical response of superficial facial tissues. Suction based experiments provide the location, time, and history dependent behavior of skin and SMAS (superficial musculoaponeurotic system) by means...

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Bibliographic Details
Published in:Journal of biomechanics 2015-12, Vol.48 (16), p.4279-4286
Main Authors: Weickenmeier, J, Jabareen, M, Mazza, E
Format: Article
Language:English
Subjects:
Adult
Biological
Biomechanical Phenomena
Biomedical materials
Elasticity
Elasto-viscoplastic model
Experiments
Face - physiology
Facial
Facial Muscles - physiology
Facial skin and SMAS
Fatigue (materials)
Finite Element Analysis
Humans
Inverse finite element analysis
Male
Mathematical models
Measurement techniques
Mechanical analysis
Physical Medicine and Rehabilitation
Physiology
Shape memory alloys
Skin Physiological Phenomena
Studies
Suction measurements
Suctioning
Surgical implants
Tension tests
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Summary:Abstract The present study is aimed at a combined experimental and numerical investigation of the mechanical response of superficial facial tissues. Suction based experiments provide the location, time, and history dependent behavior of skin and SMAS (superficial musculoaponeurotic system) by means of Cutometer and Aspiration measurements. The suction method is particularly suitable for in vivo, multi-axial testing of soft biological tissue including a high repeatability in subsequent tests. The campaign comprises three measurement sites in the face, i.e. jaw, parotid, and forehead, using two different loading profiles (instantaneous loading and a linearly increasing and decreasing loading curve), multiple loading magnitudes, and cyclic loading cases to quantify history dependent behavior. In an inverse finite element analysis based on anatomically detailed models an optimized set of material parameters for the implementation of an elastic-viscoplastic material model was determined, yielding an initial shear modulus of 2.32 kPa for skin and 0.05 kPa for SMAS, respectively. Apex displacements at maximum instantaneous and linear loading showed significant location specificity with variations of up to 18% with respect to the facial average response while observing variations in repeated measurements in the same location of less than 12%. In summary, the proposed parameter sets for skin and SMAS are shown to provide remarkable agreement between the experimentally observed and numerically predicted tissue response under all loading conditions considered in the present study, including cyclic tests.
ISSN:0021-9290
1873-2380
DOI:10.1016/j.jbiomech.2015.10.039