Predictive coding and stochastic resonance as fundamental principles of auditory phantom perception

Mechanistic insight is achieved only when experiments are employed to test formal or computational models. Furthermore, in analogy to lesion studies, phantom perception may serve as a vehicle to understand the fundamental processing principles underlying healthy auditory perception. With a special focus on tinnitus-as the prime example of auditory phantom perception-we review recent work at the intersection of artificial intelligence, psychology and neuroscience. In particular, we discuss why everyone with tinnitus suffers from (at least hidden) hearing loss, but not everyone with hearing loss suffers from tinnitus.We argue that intrinsic neural noise is generated and amplified along the auditory pathway as a compensatory mechanism to restore normal hearing based on adaptive stochastic resonance. The neural noise increase can then be misinterpreted as auditory input and perceived as tinnitus. This mechanism can be formalized in the Bayesian brain framework, where the percept (posterior) assimilates a prior prediction (brain's expectations) and likelihood (bottom-up neural signal). A higher mean and lower variance (i.e. enhanced precision) of the likelihood shifts the posterior, evincing a misinterpretation of sensory evidence, which may be further confounded by plastic changes in the brain that underwrite prior predictions. Hence, two fundamental processing principles provide the most explanatory power for the emergence of auditory phantom perceptions: predictive coding as a top-down and adaptive stochastic resonance as a complementary bottom-up mechanism.We conclude that both principles also play a crucial role in healthy auditory perception. Finally, in the context of neuroscience-inspired artificial intelligence, both processing principles may serve to improve contemporary machine learning techniques. How is information processed in the brain during auditory phantom perception? Schilling et al. review recent work at the intersection of artificial intelligence, psychology and neuroscience and bring together disparate frameworks-stochastic resonance and predictive coding-to offer an explanation for the emergence of tinnitus.

Automated summary

This article reviews recent work at the intersection of artificial intelligence, psychology, and neuroscience, using tinnitus as an example of auditory phantom perception. The authors discuss the reasons behind the emergence of auditory phantom perceptions and their crucial role in healthy auditory perception. They propose that neural noise along the auditory pathway is generated as a compensatory mechanism and can be misinterpreted as auditory input, leading to tinnitus. The principles of predictive coding and adaptive stochastic resonance are identified as the most explanatory factors for phantom perceptions and may also improve machine learning techniques.