Sound below 16 Hz, commonly referred to as infrasound, has no tonality and is often regarded as inaudible despite being clearly perceivable at sufficient intensity. Perception mechanisms have remained elusive. One factor decreasing hearing sensitivity towards the lowest sound frequencies is the velocity-coupled sound input to inner hair cells (IHCs), which convert cochlear mechanical vibrations into neural signals. We used non-invasive methods in humans to show that in the infrasound range, the velocity of the mechanical stimulus is reduced to such an extent that displacement-coupled outer hair cells (OHCs) start to be involved in the neural excitation, without mechanical activation of IHCs. A proposed model illustrates how OHC-generated electrical potentials act on the IHC cell membrane and so plausibly cause synaptic release that leads to auditory sensation. This mechanism explains perceptual characteristics specific to infrasound, such as the shallow slope of sensation threshold curves below 16 Hz and the abnormal growth of loudness with only small increases in sound pressure. This new physiological insight might help to understand globally spread complaints about very low-frequency environmental sounds.
Jurado et al. (Fri,) studied this question.