Dual Coding of Frequency Modulation in the Ventral Cochlear Nucleus.

Frequency modulation (FM) is a common acoustic feature of natural sounds and is known to play a role in robust sound source recognition. Auditory neurons show precise stimulus-synchronized discharge patterns that may be used for the representation of low-rate FM. However, it remains unclear whether this representation is based on synchronization to slow temporal envelope (ENV) cues resulting from cochlear filtering or phase locking to faster temporal fine structure (TFS) cues. To investigate the plausibility of those encoding schemes, single units of the ventral cochlear nucleus of guinea pigs of either sex were recorded in response to sine FM tones centered at the unit's best frequency (BF). The results show that, in contrast to high-BF units, for modulation depths within the receptive field, low-BF units (<4 kHz) demonstrate good phase locking to TFS. For modulation depths extending beyond the receptive field, the discharge patterns follow the ENV and fluctuate at the modulation rate. The receptive field proved to be a good predictor of the ENV responses for most primary-like and chopper units. The current in vivo data also reveal a high level of diversity in responses across unit types. TFS cues are mainly conveyed by low-frequency and primary-like units and ENV cues by chopper and onset units. The diversity of responses exhibited by cochlear nucleus neurons provides a neural basis for a dual-coding scheme of FM in the brainstem based on both ENV and TFS cues.SIGNIFICANCE STATEMENT Natural sounds, including speech, convey informative temporal modulations in frequency. Understanding how the auditory system represents those frequency modulations (FM) has important implications as robust sound source recognition depends crucially on the reception of low-rate FM cues. Here, we recorded 115 single-unit responses from the ventral cochlear nucleus in response to FM and provide the first physiological evidence of a dual-coding mechanism of FM via synchronization to temporal envelope cues and phase locking to temporal fine structure cues. We also demonstrate a diversity of neural responses with different coding specializations. These results support the dual-coding scheme proposed by psychophysicists to account for FM sensitivity in humans and provide new insights on how this might be implemented in the early stages of the auditory pathway

Codage de la modulation de fréquence dans le système auditif

Cette recherche visait à clarifier les mécanismes de bas niveau impliqués dans la détection de la modulation de fréquence (FM). Les sons naturels véhiculent des modulations d’amplitude et de fréquence saillantes essentielles à la communication. L’analyse des réponses de neurones auditifs du noyau cochléaire montre que les propriétés spectro-temporelles des stimuli de FM de basse cadence sont représentées par deux mécanismes distincts basés sur le verrouillage en phase à l’enveloppe temporelle (ENV) et à la structure temporelle fine (TFS). La contribution relative de chaque mécanisme s’avère très dépendante des paramètres de stimulation (fréquence porteuse, cadence de modulation et profondeur de modulation) mais aussi du type de neurones, chacun étant spécialisé pour un type de représentation ou l'autre. L’existence de ces deux mécanismes de codage neuronal a été confirmée chez les auditeurs humains en utilisant deux paradigmes psychophysiques. Les résultats de ces études démontrent également que le mécanisme de codage de TFS est efficace dans des conditions d'écoute défavorables (e.g. en présence de modulations interférentes). Cependant, le mécanisme de codage de TFS est susceptible de se dégrader avec l'âge et plus encore avec la perte auditive, alors que le mécanisme de codage d’ENV semble relativement épargné. Deux modèles computationnels ont été développés afin d’expliquer les contributions des indices d’ENV et de TFS dans le système auditif normal et malentendant.This research aimed at clarifying the low-level mechanisms involved in frequency-modulation (FM) detection. Natural sounds convey salient amplitude- and frequency-modulation patterns crucial for communication. Results from single auditory neurons in the cochlear nucleus show that the spectro-temporal properties of low-rate FM stimuli are accurately represented by two distinct mechanisms based on neural phase-locking to temporal envelope (ENV) and temporal fine structure (TFS) cues. The relative contribution of each mechanism was found to be highly dependent on stimulus parameters (carrier frequency, modulation rate and modulation depth) and also on the type of neuron, with clear specializations for one type of representation or the other. The validity of those two neural encoding mechanisms was confirmed for human listeners using two psychophysical paradigms. Results from those studies also demonstrate that the TFS coding mechanism is efficient in adverse listening conditions, like in the presence of interfering modulations. However, the TFS coding mechanism is prone to decline with age and even more with hearing loss, while the ENV coding mechanism seems relatively spared. Two computational models were developed to fully explain the contributions of ENV and TFS cues in the normal and impaired auditory system

Using individual differences to assess modulation-processing mechanisms and age effects

International audienc

Interactions between amplitude modulation and frequency modulation processing: Effects of age and hearing loss

International audienc

Sensory cortex plasticity supports auditory social learning

Abstract Social learning (SL) through experience with conspecifics can facilitate the acquisition of many behaviors. Thus, when Mongolian gerbils are exposed to a demonstrator performing an auditory discrimination task, their subsequent task acquisition is facilitated, even in the absence of visual cues. Here, we show that transient inactivation of auditory cortex (AC) during exposure caused a significant delay in task acquisition during the subsequent practice phase, suggesting that AC activity is necessary for SL. Moreover, social exposure induced an improvement in AC neuron sensitivity to auditory task cues. The magnitude of neural change during exposure correlated with task acquisition during practice. In contrast, exposure to only auditory task cues led to poorer neurometric and behavioral outcomes. Finally, social information during exposure was encoded in the AC of observer animals. Together, our results suggest that auditory SL is supported by AC neuron plasticity occurring during social exposure and prior to behavioral performance