The scans are providing detailed three-dimensional replicas of a whale's hearing anatomy using a breakthrough method developed by marine biologist, Dr. Ted Cranford. Using a simulated model of a male beaked whale's head, Cranford's team at San Diego State University and the University of California at San Diego (UCSD) has unveiled data that suggests mid-frequency active sonar sounds are largely filtered, or "muffled," before reaching the animal's ears. The findings also suggest that higher frequencies used by whales to hunt prey are heard at amplified levels without any dampening.

This simulated bottom view of the head of Cuvier's Beaked Whale is pointing to generalised pathways or "rivers" of sound passing in front, underneath the jaws (magenta), through the fat body (yellow), and to the ears (red). The simulated model, developed by Dr. Ted Cranford's team at San Diego State University and the University of California at San Diego, suggests that mid-frequency active sonar sounds are largely filtered before reaching the animal's ears.

The innovative approach integrates advanced computing, outsized X-ray CT scanners, and modern computational methods (developed by Dr. Petr Krysl at UCSD) to generate the reproductions in minute detail. The simulation, also referred to as a "finite element model" or FEM, accurately describes the interactions of sound with the whale's hearing anatomy. In addition, it forecasts and analyses incoming sound received at the ear and provides a description of how different characteristics combine to create movement throughout the ear.

In October, Cranford earned top honors for a presentation entitled, "Knocking on The Inner Ear in Cuvier's Beaked Whale" at the 18th Biennial Biology of Marine Mammals Conference in Quebec, Canada. The development is gaining widespread attention throughout the scientific community as a credible and highly useful tool.

image credit (c) Dr Ted Cranford