data/index3.txt

Visceromotor responses (VMR) to colorectal distension in mice with silenced or activated enterochromaffin cells
Contributors: 
James Bayrer
,
Kristina Braverman
,
Holly Ingraham
,
Stuart Brierley
,
David Julius
Description: Visceromotor responses (VMR) to colorectal distension (CRD) measured by EMG recordings from electrodes implanted in the abdominal musculature.
Viewing version: 1.0
DOI: 10.26275/zsop-bygv
April 11, 2023
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April 11, 2023
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Primary Publication(s):
Bayrer, J., Castro, J., Venkataraman, A., Touhara, K., Rossen, N., Morrie, R., Hendry, A., Madden, J., Braverman, K., Schober, G., Brizuela, M., Silva, C., Ingraham, H., Brierley, S., and Julius, D. (2022) Gut Enterochromaffin Cells are Critical Drivers of Visceral Pain and Anxiety. http://dx.doi.org/10.1101/2022.04.04.486775
Usage Rights: CC-BY-4.0

Abstract
Study Purpose: Determine the impact of enterochromaffin (EC) cell activity on visceral nociception. Intersectional genetic approach using dual recombination (Pet-flp, Tac1-Cre) to target PFtox or hM3Dq expression selectively in EC cells.

Data Collection: Spike2 files containing EMG recordings from abdominal muscle and pressure traces during colorectal distension.

Primary Conclusion: Enterochromaffin (EC) cells activation hypersensitizes the visceromotor response (VMR) to colorectal distension (CRD) in a sex-dependent manner.

Curator's Notes

Experimental Design: Abdominal EMG was used to monitor the visceromotor response (VMR) to colorectal distension (CRD) in fully awake animals. The bare endings of two Teflon-coated stainless steel wires (Advent Research Materials Ltd, Oxford, UK) were surgically sutured into the right abdominal muscle and tunneled subcutaneously to be exteriorized at the base of the subject's neck for future access. Animals were allowed to recover for at least seven days before baseline VMR. During experiments, the EMG electrodes were relayed to a data acquisition system. Distensions were applied at 20-40-50-60-70-80mmHg (20 s duration each) at 2 min intervals so that the last distension was performed ~20 min after intracolonic treatment with either vehicle, isovalerate, or ~40 min of deschloroclozapine (DCZ) administration. The signal was recorded (NL100AK headstage), amplified (NL104), filtered (NL 125/126, Neurolog, Digitimer Ltd, bandpass 50–5000 Hz), and digitized (CED 1401, Cambridge Electronic Design (CED), Cambridge, UK) or for EChM3Dq experiments through the Ponemah Software System (Data Sciences International) for off-line analysis using Spike2 Software (CED). The analog EMG signal was rectified and integrated. To quantify the magnitude of the VMR at each distension pressure, the area under the curve (AUC) during the distension (20 s) was corrected for baseline activity (AUC pre-distension, 20 s). We also calculated the total AUC, the summation of data points across all distension pressures for each animal.

Completeness: This dataset is a part of the larger study: Mouse genetic models to manipulate enterochromaffin cell activity.

Subjects & Samples: Female (n=29) and male (n=49) adult transgenic mice were used in this study.

Primary vs derivative data: Primary data is organized by subject ID. Each folder contains raw recordings from multiple performances detailed in the performances.xlsx file and comprises Spike2 data files with EMG and pressure recordings. There is no derivative data folder.

Metadata
Experimental Design:

Protocol Links:
https://doi.org/10.17504/protocols.io.n92ldp347l5b/v1
Experimental Approach: Electrophysiology, Physiology
Subject Information:

Anatomical structure: Colon
Species: Mouse
Sex: Female, Male
Age range: Adult
Number of samples: n/a

Keywords: Serotonin, Visceromotor response, Visceral pain, Enterochromaffin cell

About
Title: Visceromotor responses (VMR) to colorectal distension in mice with silenced or activated enterochromaffin cells
First Published: April 11, 2023
Last Published: April 11, 2023
Contact Author:
James Bayrer
james.bayrer@ucsf.edu
Award(s): NIH U01NS113869
Funding Program(s): SPARC
Associated project(s): Mapping gut-spinal cord connections in visceral pain
Institution(s): University of California, San Francisco
About this version
Version 1 Revision 0: Publication date: April 11, 2023 (Last updated: April 11, 2023)
Dataset DOI: https://doi.org/10.26275/zsop-bygv