Age-Related Vestibular Loss: Current Understanding and Future Research Directions

Allen, Dominic; Ribeiro, Luis; Arshad, Qadeer; Seemungal, Barry M.

doi:10.3389/fneur.2016.00231

Cited by 71 publications

(58 citation statements)

References 71 publications

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“…Age-related degeneration of the vestibular system (i.e., progressive neuronal loss) is a multifactorial process, affecting the peripheral end-organs, the brainstem, the cerebellum and the cerebral cortex (Arshad and Seemungal, 2016). Age-related neuronal loss in the vestibular nucleus has been reported in both humans (Lopez et al, 1997) and mice (Sturrock, 1989).…”

Section: How Does Aging Affect Our Ability To Compute Online Spatimentioning

confidence: 99%

The Aging Navigational System

Lester

Moffat

Wiener

et al. 2017

Neuron

298

280

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Section: How Does Aging Affect Our Ability To Compute Online Spatimentioning

confidence: 99%

The Aging Navigational System

Lester

Moffat

Wiener

et al. 2017

Neuron

298

280

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“…Recent evidence from neuroimaging studies indicates that signatures of grid-cell-like activity in human entorhinal cortex are reduced in old age, and this reduction is associated with larger path integration errors (Stangl et al, 2018). Certain aspects of the vestibular system also deteriorate with age (for a review, see Allen et al, 2016), and vestibular loss affects path integration performance (Glasauer et al, 2002;Xie et al, 2017). These findings support the possibility that an increase in noise on a neuronal level, possibly from a loss of the signal-to-noise ratio from degrading circuitry in the grid cell or the vestibular system may be responsible for deficient computations of pose in old age.…”

Section: Discussionmentioning

confidence: 99%

Sources of path integration error in young and aging humans

Stangl

Kanitscheider²,

Riemer

et al. 2018

Preprint

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Path integration is a vital function in navigation: it enables the continuous tracking of one's position in space by integrating self-motion cues. Path integration abilities vary across individuals but tend to deteriorate in old age. The specific causes of path integration errors, however, remain poorly characterized. Here, we combined tests of path integration performance with a novel analysis based on the Langevin diffusion equation, which allowed us to decompose errors into distinct causes that can corrupt path integration computations. Across age groups, the dominant errors were due to noise and a bias in speed estimation. Noise-driven errors accumulated with travel distance not elapsed time, suggesting that the dominant noise originates in the velocity input rather than within the integrator. Age-related declines were traced primarily to a growth in this unbiased noise. Together, these findings shed light on the contributors to path integration error and the mechanisms underlying age-related navigational deficits.

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“…Also, the number of neurons in the vestibular nuclei undergoes a 3% loss per decade, starting at approximately 40 years of age (Alvarez et al, 2000, Lopez et al, 1996. As a consequence, throughout ageing, fewer primary vestibular afferents reach the brain, in particular the downstream control structures responsible for VOR adaptation, such as the cerebellum (Allen et al, 2017). Thus, ageing gradually hinder the detection and encoding of head displacements (in particular head factors (including increased sensitivity to afferent nerve fibres) may counterbalance agerelated vestibular losses, thus preserving, to a certain extent, VOR in older adults (Jahn et al, 2003, Li et al, 2015, McGarvie et al, 2015.…”

Section: Introductionmentioning

confidence: 99%

Homeostatic cerebellar compensation of age-related changes of vestibulo-ocular reflex adaptation: a computational epidemiology study

Luque

Naveros

Ros

et al. 2020

Preprint

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The vestibulo-ocular reflex (VOR) stabilises vision during head motion. Age-related structural changes predict a linear VOR decay, whereas epidemiological data show a non-linear temporal profile. Here, we model cerebellar-dependent VOR adaptation to link structural and functional changes throughout ageing. We posit that three neurosynaptic factors codetermine VOR ageing patterns: electrical coupling between inferior olive neurons, intrinsic plasticity at Purkinje cell synapses, and long-term spike timing dependent plasticity at parallel fibre - Purkinje cell synapses as well as mossy fibre - medial vestibular nuclei synapses. Our cross-sectional simulations show that long-term plasticity acts as a global homeostatic mechanism mediating the non-linear temporal profile of VOR. Our results also suggest that intrinsic plasticity at Purkinje cells acts as a local homeostatic mechanism sustaining VOR at old ages. Importantly, longitudinal simulations show that residual fibres coding for the peak and trough of the VOR cycle constitute a predictive hallmark of VOR ageing trajectories.

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Age-Related Vestibular Loss: Current Understanding and Future Research Directions

Cited by 71 publications

References 71 publications

The Aging Navigational System

The Aging Navigational System

Sources of path integration error in young and aging humans

Homeostatic cerebellar compensation of age-related changes of vestibulo-ocular reflex adaptation: a computational epidemiology study

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