Colonic Motility and Jejunal Vagal Afferent Firing Rates Are Decreased in Aged Adult Male Mice and Can Be Restored by an Aminosterol

Overview

Journal Front Neurosci

Date 2019 Sep 26

PMID 31551703

Citations 6

Authors

Christine L West

Jessica Y Amin

Sohana Farhin

Andrew M Stanisz

Yu-Kang Mao

Wolfgang A Kunze

Affiliations

Soon will be listed here.

Abstract

There is a general decline in gastrointestinal function in old age including decreased intestinal motility, sensory signaling, and afferent sensitivity. There is also increased prevalence of significant constipation in aged populations. We hypothesized this may be linked to reduced colonic motility and alterations in vagal-gut-brain sensory signaling. Using preparations from young (3 months) and old (18-24 months) male CD1 mice we report functional age-related differences in colonic motility and jejunal mesenteric afferent firing. Furthermore, we tested the effect of the aminosterol squalamine on colonic motility and jejunal vagal firing rate. Old mice had significantly reduced velocity of colonic migrating motor complexes (MMC) by 27% compared to young mice ( = 0.0161). Intraluminal squalamine increased colonic MMC velocity by 31% in old mice ( = 0.0150), which also had significantly reduced mesenteric afferent single-unit firing rates from the jejunum by 51% ( < 0.0001). The jejunal vagal afferent firing rate was reduced in aged mice by 62% ( = 0.0004). While the time to peak response to squalamine was longer in old mice compared to young mice (18.82 ± 1.37 min vs. 12.95 ± 0.99 min; = 0.0182), it significantly increased vagal afferent firing rate by 36 and 56% in young and old mice, respectively ( = 0.0006, = 0.0013). Our results show for the first time that the jejunal vagal afferent firing rate is reduced in aged-mice. They also suggest that there is translational potential for the therapeutic use of squalamine in the treatment of age-related constipation and dysmotility.

Citing Articles

Squalamine reverses age-associated changes of firing patterns of myenteric sensory neurons and vagal fibres.

McVey Neufeld K, Mao Y, West C, Ahn M, Hameed H, Iwashita E Commun Biol. 2024; 7(1):80.

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Identification of SSRI-evoked antidepressant sensory signals by decoding vagus nerve activity.

West C, McVey Neufeld K, Mao Y, Stanisz A, Forsythe P, Bienenstock J Sci Rep. 2021; 11(1):21130.

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