Rats use their whiskers in a way that is closely related to the human sense of touch: just as humans move their fingertips across a surface to perceive shapes and textures, rats twitch their whiskers to achieve the same goal. Now, in a finding that could help further understanding of perception across species, neuroscientists from Massachusetts Institute of Technology (MIT) have used high-speed video to reveal rat whiskers in action and show the tiny movements that underlie the rat’s perception of its tactile environment.
Rats rely on whiskers to find their way in the dark, and they devote large areas of their brains to decoding the incoming signals, explains Christopher Moore, a member of the McGovern Institute for Brain Research at MIT and senior author of a study in the February 28th issue of Neuron. Neuroscientists interested in perception have studied the whisker system intensively, but the information conveyed to the brain by whisker motions has remained a mystery-until now.
“Now that we can see what the rat’s whiskers are telling the brain, we can start to understand better how this amazing perceptual system works,” says Moore, who is also an assistant professor in MIT’s Department of Brain and Cognitive Sciences. “This understanding is relevant not only to the human sense of touch, but to all forms of perception, because every sensory organ is an interface between the mind and the external world.”
What might a whisker-based sensation feel like? Imagine sweeping a stick across a picket fence. The frequency of vibrations depends on the spacing between the pickets, but the sensation in the hand is also affected by the length and flexibility of the stick and the speed of its movement.
Likewise, Moore reasoned, the whiskers’ movements and mechanical properties must influence the information that they relay to the brain. The whiskers are arranged in a pattern on the snout, with the shortest ones at the front. Experiments with isolated whiskers had demonstrated that, like harp strings, shorter whiskers are “tuned” to resonate at higher frequencies, creating a map of frequency information within the brain. But until now, no one had managed to see the detailed pattern of whisker movements in freely behaving animals.
Like the famous images MIT’s Harold “Doc” Edgerton made of bullets going through apples, the slow-motion version of these new movies provides the first glimpse of the micromotions that the whiskers transmit to the rat brain.
“We knew from watching rats’ behaviour that there must be whisker micromotions that were too rapid to measure using available recording techniques,” explains Jason Ritt, a postdoctoral scientist in Moore’s lab and first author of the study. Ritt therefore spent several years developing a video system that captures whisker movements at a rate of 3 200 frames per second – 100 times faster than typical home videos – and an automatic tracking system to analyse the resulting deluge of video data, about 1 gigabyte per second.
For the experiments, the researchers trained rats to choose either a smooth or a rough surface using their whiskers. Correct choices were rewarded with chocolate milk, and the whisker movements were captured on video. Analysis of the video revealed an unexpectedly complex pattern of movements, including periodic “waves” of motion when the rat touched a smooth surface, and irregular, large and high-velocity movements when contacting a rough surface.
“These patterns are larger and more complex than anything previously observed in anesthetised animals or plucked whiskers, but they are the key to a rat’s perceptions and behaviour,” comments Moore.
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