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Literature DB >> 33249377

Increased intrinsic excitability and decreased synaptic inhibition in aged somatosensory cortex pyramidal neurons.

Ion R Popescu¹, Kathy Q Le², Alexis L Ducote³, Jennifer E Li², Alexandria E Leland², Ricardo Mostany³.

Abstract

Sensorimotor performance declines during advanced age, partially due to deficits in somatosensory acuity. Cortical receptive field expansion contributes to somatosensory deficits, suggesting increased excitability or decreased inhibition in primary somatosensory cortex (S1) pyramidal neurons. To ascertain changes in excitability and inhibition, we measured both properties in neurons from vibrissal S1 in brain slices from young and aged mice. Because adapting and non-adapting neurons-the principal pyramidal types in layer 5 (L5)-differ in intrinsic properties and inhibitory inputs, we determined age-dependent changes according to neuron type. We found an age-dependent increase in intrinsic excitability in adapting neurons, caused by a decrease in action potential threshold. Surprisingly, in non-adapting neurons we found both an increase in excitability caused by increased input resistance, and a decrease in synaptic inhibition. Spike frequency adaptation, already small in non-adapting neurons, was further reduced by aging, whereas sag, a manifestation of Ih, was increased. Therefore, aging caused both decreased inhibition and increased intrinsic excitability, but these effects were specific to pyramidal neuron type.

Entities: Chemical

Keywords: Action potential threshold; Aging; Barrel cortex; Critical frequency; GABA; Hyperexcitability; Inhibition; Input resistance; Intrinsic excitability; Layer 5; Somatosensory cortex; Spike frequency adaptation; sag

Mesh：

Year: 2020 PMID： 33249377 PMCID： PMC8436770 DOI： 10.1016/j.neurobiolaging.2020.10.007

Source DB: PubMed Journal: Neurobiol Aging ISSN： 0197-4580 Impact factor: 4.673

106 in total

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