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Learning from Nature: An investigation of an impact-resistant system on the woodpecker head as a non-traumatic brain injury animal model

Abstract

Impact resistant structures and materials have been evolved in nature during millions of years of evolution. Some examples of energy absorbent biological materials have been recently reported; however, a better comprehensive understanding of impact-resistant biological materials is still required to compare their unique features: a degree of mineralization, specific mechanical behavior and/or loading condition of tissue/animal, and intentional (active) or indirect (passive) modification of the innate structure/material. The woodpecker head was chosen as a representative impact-resistant material/structure found in nature because woodpeckers avoid brain injury while they peck at trees up to 20 Hz with speeds up to 7 m/s, undergoing decelerations up to 1,200 g.

The brain is one of the most important and complicated organs, but it is delicate and therefore needs to be protected from external forces. This makes the pecking behavior of the woodpecker so impressive, as they are not known to sustain any brain injury due to their anatomical adaptations (e.g., a specialized beak, skull bone, and hyoid bone). However, the relationship between the morphology of the woodpecker head and its mechanical function against damage from daily pecking habits remain an open question. The shape of the hyoid apparatus is unusual in woodpeckers and its structure and mechanical properties have not been reported in detail. Moreover, the shape and mechanical properties of the skull bone of woodpeckers is different from other non-pecking birds. Therefore, the research works throughout this dissertation aim to examine the anatomical structure, composition, and mechanical properties of the hyoid bone and the skull bone, and to find an interspecies variation of the skull bone morphology in woodpeckers eventually in order to determine its potential role in energy absorption and dissipation as an efficient protection of the brain. Aided by recent technical advancements, such as multiscale imaging tools (micro-computed tomography, optical and scanning electron microscopy), 3D printing, high-precision, miniaturized sensors, and computational simulation, these questions can be explored by applying new materials science concepts of bioinspiration and bioexploration to identify adapted structures/materials in a design that results from millions of years of evolution.

The hyoid apparatus has four distinct bone sections, with three joints between these sections. Nanoindentation results on cross-sectional regions of each bone reveal a previously unreported structure consisting of a stiff core and outer, more compliant shell with moduli of up to 27.4 GPa and 8.5 GPa, respectively. The bending resistance is low at the posterior section of the hyoid bones, indicating that this region has a high degree of flexibility to absorb impact. In the skull bone of woodpeckers compared to the chicken skull, two different strategies are found: the skull bone of the woodpecker shows a relatively small but uniform level of closed porosity, a higher degree of mineralization, and a higher cortical to skull bone ratio. From the 3D printing and computational simulation approach, two main features, including the beam-like bar structure of the jugal bone acting as the main stress deflector and the high natural frequency of the skull bone of woodpeckers can teach two lessons for potential materials development as well as engineering applications: 1) protection of a delicate internal organ occurs by redirection of the main stress pathway and 2) a large mismatch of the natural frequencies between the skull and brain avoids resonance and reduces the overall load experienced by the brain.

Lastly, bioinspired designs and engineering applications will be discussed using some case studies in biological materials for the development of protective devices or robots. This novel approach will provide a new insight to many researchers and engineers in materials science and mechanical engineering disciplines to teach how the natural materials have evolved to adapt its impact-resistant ability against different environments.

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