Unique Response Properties and GABA_A Receptor Function in Medial Geniculate Body Neurons of Young and Aged Fischer Brown Norway Rats

Richardson, Ben David

01 December 2012

The auditory thalamus or medial geniculate body (MGB) is the final brain structure for acoustic information processing prior to, and functioning in reciprocity with, auditory cortex. MGB neurons process and gate aspects of acoustic stimuli, functions which depend partly on GABAergic inhibition. To characterize these properties, the inhibitory neurotransmitters involved and how they may be altered in the aged MGB, specific aims sought to: 1) determine the presence of functional high affinity GABAA receptors (GABAARs) in the MGB, 2) determine whether GABAAR function is altered with age and 3) determine to what degree MGB neurons of awake young and aged rats display stimulus-specific adaptation (SSA). Inhibitory neurotransmission is essential for accurate coding of acoustic information in the central auditory system, but appears disrupted in the aged. The present study required the development of a slice preparation that permitted whole cell recordings from juvenile, young adult and aged rat MGB neurons. The presence of high affinity GABAARs and the impact of aging on synaptic and high affinity GABAAR function were examined. Low concentrations of gaboxadol (GABAAR agonist) activated a gabazine-sensitive (GABAAR antagonist) tonic current, providing support for the expression of functional high affinity GABAARs in the MGB. Activation of high affinity GABAARs expressed by MGB neurons decreased input resistance, hyperpolarized resting membrane potential, reduced evoked firing rates and induced a transition from tonic to burst firing mode. In aged MGB neurons there was a significant 50.4% reduction in GABAAR-mediated tonic Cl- current. Synaptic GABAAR inhibition appeared differentially affected by age in lemniscal and non-lemniscal auditory thalamus although gramicidin perforated patch-clamp recordings indicated neuronal Cl- homeostasis was unaltered with age. Anesthetized rodent MGB single units show SSA, during which the firing rate in response to repetitive stimuli decreases/adapts over time but low probability stimuli (i.e. novel) continue to elicit robust responses. To examine the presence of SSA in the MGB of awake rats, a multichannel single unit recording preparation was implemented. This approach involved implanting young and aged rats with an array of four individually-advanceable tetrodes in order to evaluate SSA by recording responses to a frequency oddball paradigm and a random/non-random frequency range paradigm. Single units in the MGB of awake FBN rats were found to display SSA, which was stronger in the non-lemniscal than lemniscal regions of the MGB. SSA was most dramatic at lower intensities where 27 of 57 (47%) young adult single units and 28 of 54 (52%) aged single units displayed SSA. However, there were no significant age-related differences in average magnitude or time course of SSA of MGB single units studied. Data from aims 1 and 2 provide the initial description of functional high affinity GABAARs in the rodent MGB and the plasticity of these receptors with age. These data suggest that GABAAR subtype-selective agonists or modulators could be used to augment MGB inhibitory neurotransmission, possibly improving speech understanding for a subset of elderly individuals. Findings from aim 3 were the first to show that SSA by MGB neurons is not dependent on arousal level nor on the anesthetized state, but is a common response in the MGB of awake rats. SSA did not appear to be overtly altered in the aged auditory thalamus of awake rats.

aging

Auditory

GABAA Receptor

medial geniculate

stimulus-specific adaptation

thalamus

DEVELOPMENT OF THE AUDITORY THALAMUS IN THE FERRET

HOWARD, JENNIFER DIXON

24 September 2002

No description available.

Biology, Anatomy

medial geniculate body

ferret

auditory

thalamus

MGB

Chemogenetic Inhibition Of The Inferior Colliculus: Effects On Electrophysiology And Behavior

Nanami L. Miyazaki (5930753)

03 January 2019

Age-related hearing loss (ARHL) or presbycusis has grown to be a prevalent problem among the increasing aging population over the past century. Efficacy of hearing aids, cochlear implants or auditory brainstem implants have been shown, but with variable performance among patients, a fuller understanding of the complex circuitry of the auditory system would be beneficial for improving upon current technology as well as developing alternative treatments. In the current study, chemogenetics or DREADDs was utilized to inhibit the neuronal activity of the pathway between the medial geniculate body and the inferior colliculus. Subsequent effects of chemogenetic inhibition was assessed with electrophysiological measures– including auditory evoked potential recordings and single-unit recordings–as well as behavioral measures using the acoustic startle response and prepulse inhibition paradigm.

Neuroscience

auditory neuroscience

auditory

DREADDs

inhibition

inferior colliculuc

medial geniculate body

Cholinergic circuitry in auditory brainstem

Motts, Susan D.

22 November 2010

No description available.

Neurosciences

pedunculopontine tegmental nucleus

laterodorsal tegmental nucleus

acetylcholine

auditory

inferior colliculus

medial geniculate body

sensory gating

Perineuronal nets and the inhibitory circuitry of the auditory midbrain: evidence for subtypes of GABAergic neurons

Beebe, Nichole L.

26 July 2016

No description available.

Neurosciences

perineuronal nets

GABA

auditory

inferior colliculus

medial geniculate body

VGLUT2

hearing

Cholinergic Projections to the Inferior Colliculus

Noftz, William Andrew

31 August 2020

No description available.

Neurosciences

Biology

Biomedical Research

acetylcholine

inferior colliculus

auditory

choline acetyltransferase

ChAT

midbrain

viral tracing

hearing

neuromodulation

arousal

cochlear nucleus

medial geniculate body

NBIC

intercollicular tegmentum

VAChT