Data from: Structural and mechanical properties facilitate shock wave damping by helmet-like orbital hoods in snapping shrimp
Data files
Nov 26, 2025 version files 19.50 KB
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README.md
2.19 KB
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SLS_optimize_fixedTau_fun.m
802 B
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TEM_Data_for_Kazel_et_al.xlsx
15.27 KB
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viscoelastic_fitting_submission.m
1.24 KB
Abstract
Snapping shrimp damp the shock waves they produce and use as weapons with a helmet-like structure termed the orbital hood. Here, we ask how structural and material properties contribute to shock wave damping by orbital hoods in Alpheus heterochaelis. Using tensile mechanical testing, we find orbital hoods are approximately half as stiff as the carapace and have twice the capacity for viscous energy dissipation. Microstructural features likely contribute to tissue-specific mechanical properties: the endocuticles of orbital hoods have almost twice as many lamellae as those of carapaces, despite being half as thick, suggesting a mechanism for enhanced material mobility underlying viscous behavior. Using material properties from mechanical testing and geometric data from microCT, we developed finite element simulations of interactions between shock waves and orbital hoods. These simulations predict orbital hoods reduce shock wave-induced strain and stress in the neural tissues of shrimp by 28% and 22%, respectively. Orbital hoods appear optimized for shock wave damping: simulated increases or decreases in their material properties reduce their protective capabilities. We conclude that structural and viscoelastic properties contribute to shock wave damping by orbital hoods, a promising step towards bio-inspired improvements to contemporary armor systems that currently underperform in preventing blast-induced neurotrauma in humans.
Dataset DOI: 10.5061/dryad.2v6wwq02w
Description of the data and file structure
The orbital hoods of snapping shrimp are the first biological armor system shown to protect an animal from blast-induced neurotrauma by damping shock waves, a discovery that prompts questions about their mechanism of function. Here, we ask how the structural and material properties of orbital hoods contribute to shock wave damping in A. heterochaelis.
Files and variables
File: SLS_optimize_fixedTau_fun.m
Description: MATLAB code for fitting the linear elastic model to the experimental data we collected for snapping shrimp exoskeleton samples
File: viscoelastic_fitting_submission.m
Description: MATLAB code for fitting the linear elastic model to the experimental data we collected for snapping shrimp exoskeleton samples
File: TEM_Data_for_Kazel_et_al.xlsx
Description: Measurements from TEM images of sectioned samples of snapping shrimp orbital hoods and carapaces (Epicuticle width, Exocuticle width, Endocuticle width, Total width, and Lamellae) with their respective average measurement. All values for widths are in microns.
Specimens are labeled numerically (1, 2, 3, etc). Separate samples from the same individual are labeled by letter. Values for lamellae are counts. The epicuticle in the Hood tends to be thicker than in the Carapace, with a large effect size, but the difference does not reach statistical significance (p = 0.095) due to small sample size.
Code/software
The code included here is for MATLAB R2022b (MathWorks Inc., Natick, MA)
Access information
Other publicly accessible locations of the data:
- All other relevant data can be found within the article.
- For finite element analysis, we used LS-DYNA software, which is available here: https://lsdyna.ansys.com/
Data was derived from the following sources:
- The Data included here is from TEM images of sectioned exoskeleton samples from snapping shrimp.