Defining the Mechanical Characteristics of Porcine Brain Tissue Subject to Cyclic, Compressive Loading

In recent years, repetitive traumatic brain injuries have been linked to the progressive neurodegenerative disorder termed chronic traumatic encephalopathy. However, the mechanical characteristics of brain tissue exposed to repetitive loading still lack understanding. This research evaluated the response of porcine brain tissue undergoing cyclic, compressive loading in reference to three impact parameters: cycle number (N₂₅, N₅₀, N₁₀₀, N₁₅₀, and N₂₀₀), strain level (15, 30, and 40%), and strain rate (0.00625, 0.025, 0.10, and 1.0s^-1). Following mechanical testing, tissue samples were processed for hematoxylin and eosin (H&E) staining. Stress values, hysteresis energy, and decreases in hysteresis energy for all parameters were compared. The data suggest that microstructural brain tissue damage is highly dependent on strain level and cycle number, whereas strain rate did not appear to cause permanent damage in the quasi-static range applied. The onset of permanent microstructural tissue damage may relate to movement of fluid molecules within the tissue.

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Year

Entry

2007

Cheng S, Bilston LE. Unconfined compression of white matter. J Biomech. 2007;40(2):117-124.

2004

Nicolle S, Lounis M, Willinger R. Shear properties of brain tissue over a frequency range relevant for automotive impact situations: new experimental results. Stapp Car Crash J. 2004;48:239-258. SAE 2004-22-0011.

2006

Manoogian S, McNeely D, Duma S, Brolinson G, Greenwald R. Head acceleration is less than 10 percent of helmet acceleration in football impacts. In: Biomedical Sciences Instrumentation. Vol 48. Proceedings of the Rocky Mountain Bioengineering Symposium & International ISA Biomedical Sciences Instrumentation Symposium; April 7-9, 2006; Terre Haute, IN.383-388.

1997

Peters GWM, Meulman JH, Sauren AAHJ. The applicability of the time/temperature superposition principle to brain tissue. Biorheology. March–April 1997;34(2):127-138.

2005

Miller K. Method of testing very soft biological tissues in compression. J Biomech. January 2005;38(1):153-158.