movement of objects in the world is often directly related to survival — whether it's a gazelle detecting the slow creep of a lion or a driver merging across four lanes of traffic.
Motion is so important that the primate brain evolved a dedicated system for processing visual movement, known as the middle temporal cortex, over 50 million years ago. This region of the brain contains neurons specialized for detecting moving objects.
These motion detectors compute the information needed to track objects as they continuously change their location over time, then sends signals about the moving world to other regions of the brain, such as those involved in planning muscle movements.
It's easy to assume that you see and hear motion in a similar way. However, exactly how the brain processes auditory motion has been an open scientific question for at least 30 years.
This debate centers on two ideas: One supports the existence of specialized auditory motion detectors similar to those found in visual motion, and the other suggests that people hear object motion as discrete snapshots.
As computational neuroscientists, we became curious when we noticed a blind woman confidently crossing a busy intersection. Our laboratory has spent the past 20 years examining where auditory motion is represented in the brains of blind individuals.
For sighted people, crossing a busy street based on hearing alone is an impossible task, because their brains are used to relying on vision to understand where things are. As anyone who has tried to find a beeping cellphone that's fallen behind the sofa knows, sighted people have a very limited ability to pinpoint the location or movement of objects based on auditory information.
Yet people who become