The sensation of a mobile phone vibrating is familiar. The perception of these vibrations derives from specialized receptors that transduce them into neural signals sent to the brain. But how does the brain encode their physical characteristics? To understand this, neuroscientists from the University of Geneva (UNIGE) have observed what happens in the brains of mice whose forepaws perceive vibrations. They discovered that neurons in the somatosensory cortex are activated in a manner similar to those in the sound-reactive auditory cortex. These results, published in the journal Nature, suggest that feeling a phone vibrate or hearing it ring is ultimately based on the same brain codes.
In a glass of water, it’s easy to observe the concentric oscillatory motions created by small movements that occur nearby. These oscillations are caused by vibrations that propagate through the floor, desk, glass and all other solid surfaces. These vibrations are also important sensory stimuli that people use to detect an approaching train, for example, or to identify the steps of a coworker.
“We live surrounded by vibrations that are extremely important in how we perceive the world,” explains Daniel Huber at the Department of Basic Neurosciences at the UNIGE Faculty of Medicine, who led this work. “So we wanted to know how the brain perceives and represents them.”
A combination of frequency and amplitude
Using two-photon microscopy, Daniel Huber’s team visualized the activity of hundreds of neurons in a mouse’s somatosensory cortex as vibrations of different frequencies were delivered to its forepaw. As in the auditory cortex, individual neurons were selectively tuned, strongly responding to some frequencies and less so to others.
“It turns out that these neurons are preferentially tuned to a specific combination of frequency and amplitude, and that this combination corresponds to what the mouse actually perceives. In other words, a mouse is unable to distinguish a high-frequency vibration with a low amplitude from a low-frequency vibration with a higher amplitude,” explains Mario Prsa, a researcher in Dr. Huber’s team and the study’s first author. “It is the same psychoacoustic effect detected in the auditory system, where the perceived pitch of a sound changes with both frequency and loudness.” Thus, although sounds traveling through the air and vibrations transmitted through solid matter are processed by different sensory channels, they are both perceived and encoded similarly in the brain.
Everything goes through Pacinian corpuscles
In a second step, the researchers sought to identify the origin of the somatosensory stimuli involved by performing a detailed histological analysis of Pacinian corpuscles in mouse forelimb. Pacinian corpuscles are known to transduce high-frequency vibrations in mammals and are densely expressed in the dermis of primate fingertips. “Surprisingly, we found that the vibration responses in the mouse brain stem from Pacinian corpuscles located on the forearm bones, whereas they were totally absent in the paw’s skin,” explains Géraldine Cuenu, a student in the UNIGE master’s programme in neurosciences, who took charge of this detailed analysis. Using optogenetics, the scientists confirmed the link between cortical responses and the particular configuration of mechanoreceptors in the forelimbs.
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