Decoding expectation and surprise in dementia: the paradigm of music.

Elia Benhamou,Chris J D Hardy,Jeremy C S Johnson,Jennifer M Nicholas,Caroline V Greaves,Rebecca L Bond,Janneke E P Van Leeuwen,Maï-Carmen Requena-Komuro,Sijia Zhao,Harri Sivasathiaseelan,Jason D Warren,Annabel Nelson,Lucy L Russell,Jonathan D Rohrer

doi:10.1093/braincomms/fcab173

Abstract

Making predictions about the world and responding appropriately to unexpected events are essential functions of the healthy brain. In neurodegenerative disorders, such as frontotemporal dementia and Alzheimer’s disease, impaired processing of ‘surprise’ may underpin a diverse array of symptoms, particularly abnormalities of social and emotional behaviour, but is challenging to characterize. Here, we addressed this issue using a novel paradigm: music. We studied 62 patients (24 female; aged 53–88) representing major syndromes of frontotemporal dementia (behavioural variant, semantic variant primary progressive aphasia, non-fluent-agrammatic variant primary progressive aphasia) and typical amnestic Alzheimer’s disease, in relation to 33 healthy controls (18 female; aged 54–78). Participants heard famous melodies containing no deviants or one of three types of deviant note—acoustic (white-noise burst), syntactic (key-violating pitch change) or semantic (key-preserving pitch change). Using a regression model that took elementary perceptual, executive and musical competence into account, we assessed accuracy detecting melodic deviants and simultaneously recorded pupillary responses and related these to deviant surprise value (information-content) and carrier melody predictability (entropy), calculated using an unsupervised machine learning model of music. Neuroanatomical associations of deviant detection accuracy and coupling of detection to deviant surprise value were assessed using voxel-based morphometry of patients’ brain MRI. Whereas Alzheimer’s disease was associated with normal deviant detection accuracy, behavioural and semantic variant frontotemporal dementia syndromes were associated with strikingly similar profiles of impaired syntactic and semantic deviant detection accuracy and impaired behavioural and autonomic sensitivity to deviant information-content (all P < 0.05). On the other hand, non-fluent-agrammatic primary progressive aphasia was associated with generalized impairment of deviant discriminability (P < 0.05) due to excessive false-alarms, despite retained behavioural and autonomic sensitivity to deviant information-content and melody predictability. Across the patient cohort, grey matter correlates of acoustic deviant detection accuracy were identified in precuneus, mid and mesial temporal regions; correlates of syntactic deviant detection accuracy and information-content processing, in inferior frontal and anterior temporal cortices, putamen and nucleus accumbens; and a common correlate of musical salience coding in supplementary motor area (all P < 0.05, corrected for multiple comparisons in pre-specified regions of interest). Our findings suggest that major dementias have distinct profiles of sensory ‘surprise’ processing, as instantiated in music. Music may be a useful and informative paradigm for probing the predictive decoding of complex sensory environments in neurodegenerative proteinopathies, with implications for understanding and measuring the core pathophysiology of these diseases.

Highlights

Predicting the future based on past experience and responding appropriately to unexpected, ‘surprising’ events are fundamental functions of the healthy brain
We found that for low ENT melodies, IC was significantly positively correlated with deviant detection accuracy in the healthy control group, whereas IC was significantly negatively correlated with deviant detection accuracy in the semantic variant primary progressive aphasia (svPPA) group, driven by a very low falsealarm rate in the no-deviant condition
Consistent with previous evidence,[60,93,94,95] healthy older controls here showed a graded response profile with more accurate detection of ‘surprising’ deviations in fundamental acoustic structure and generic syntactic musical rules than deviations in the semantic structure of specific musical objects. In healthy controls, both detection accuracy and autonomic reactivity correlated with the information-theoretic quantity of surprise (IC) in deviant musical events but were differentially modulated by the predictability (ENT) of the musical environment

Summary

Introduction

Predicting the future based on past experience and responding appropriately to unexpected, ‘surprising’ events are fundamental functions of the healthy brain. A plausible unifying mechanism for this diverse phenotypic spectrum is impaired integration of expectation (established by environmental context) with surprise (unexpected events) This mechanism has a neurophysiological signal in altered mismatch negativity[21,22,23,24,25,26,27] and a neuroanatomical signature in dysfunctional frontotemporal neural circuitry.[21,22,28,29,30,31,32] Impaired deviance detection may develop early in the course of neurodegeneration and indexes a core mechanism of the culprit proteinopathy in animal models.[33,34,35] Taken together, this evidence suggests that neural processes establishing expectations and decoding ‘surprise’ may underpin diverse pathophysiological and clinical effects of dementias, such as FTD and Alzheimer’s disease. These processes remain poorly characterized and difficult to quantify, in the setting of neurodegenerative disease

Methods

Results

Conclusion