Literature DB >> 22402029

A comparison of low- and high-impact forced exercise: effects of training paradigm on learning and memory.

John A Kennard1, Diana S Woodruff-Pak.   

Abstract

In this study we compared two types of forced exercise-a low impact paradigm to minimize stress, which included speeds up to 10 m/min and a stressful high impact paradigm, with speeds up to 21 m/min. 150 male C57BL/6J mice were randomly assigned to the low impact, high impact, or sedentary control conditions and were tested on the rotorod and Morris water maze (MWM) as indices of motor learning and spatial memory. We found that 5 weeks of stressful high speed forced exercise led to significant improvement in rotorod performance, as high impact runners outperformed both low impact runners and controls at 15 and 25 rpm speeds. These differences were the result of improved physical fitness due to exercise and likely do not reflect enhanced learning in these mice. In the MWM, 5 weeks of stressful high impact exercise led to significant impairment in spatial memory acquisition compared to low impact runners and controls. Low impact exercise for 10 weeks significantly improved retention of spatial memory compared to high impact exercise. Results suggested that these two paradigms produced different effects of forced exercise on learning and memory. The low impact paradigm led to some improvements, whereas the stressful high impact program caused significant impairment. Comparison of these two paradigms begins to address the window between the beneficial and detrimental effects of forced exercise, and have suggested a boundary of exercise intensity that leads to impairment in learning.
Copyright © 2012. Published by Elsevier Inc.

Entities:  

Mesh:

Year:  2012        PMID: 22402029      PMCID: PMC3349001          DOI: 10.1016/j.physbeh.2012.02.023

Source DB:  PubMed          Journal:  Physiol Behav        ISSN: 0031-9384


  39 in total

1.  Ageing, fitness and neurocognitive function.

Authors:  A F Kramer; S Hahn; N J Cohen; M T Banich; E McAuley; C R Harrison; J Chason; E Vakil; L Bardell; R A Boileau; A Colcombe
Journal:  Nature       Date:  1999-07-29       Impact factor: 49.962

2.  Exercise influences spatial learning in the radial arm maze.

Authors:  B J Anderson; D N Rapp; D H Baek; D P McCloskey; P S Coburn-Litvak; J K Robinson
Journal:  Physiol Behav       Date:  2000-09-15

3.  Angiogenesis but not neurogenesis is critical for normal learning and memory acquisition.

Authors:  A L Kerr; E L Steuer; V Pochtarev; R A Swain
Journal:  Neuroscience       Date:  2010-09-08       Impact factor: 3.590

4.  Exercise enhances learning and hippocampal neurogenesis in aged mice.

Authors:  Henriette van Praag; Tiffany Shubert; Chunmei Zhao; Fred H Gage
Journal:  J Neurosci       Date:  2005-09-21       Impact factor: 6.167

Review 5.  The influence of stress hormones on fear circuitry.

Authors:  Sarina M Rodrigues; Joseph E LeDoux; Robert M Sapolsky
Journal:  Annu Rev Neurosci       Date:  2009       Impact factor: 12.449

6.  Stress and hippocampal plasticity: implications for the pathophysiology of affective disorders.

Authors:  Bruce S. McEwen; Ana Maria Magarinos
Journal:  Hum Psychopharmacol       Date:  2001-01       Impact factor: 1.672

7.  Compulsive exercise acutely upregulates rat hippocampal brain-derived neurotrophic factor.

Authors:  A M Huang; C J Jen; H F Chen; L Yu; Y M Kuo; H I Chen
Journal:  J Neural Transm (Vienna)       Date:  2005-10-27       Impact factor: 3.575

8.  Physical activity and public health: updated recommendation for adults from the American College of Sports Medicine and the American Heart Association.

Authors:  William L Haskell; I-Min Lee; Russell R Pate; Kenneth E Powell; Steven N Blair; Barry A Franklin; Caroline A Macera; Gregory W Heath; Paul D Thompson; Adrian Bauman
Journal:  Med Sci Sports Exerc       Date:  2007-08       Impact factor: 5.411

9.  Differential effects of treadmill running and wheel running on spatial or aversive learning and memory: roles of amygdalar brain-derived neurotrophic factor and synaptotagmin I.

Authors:  Yu-Fan Liu; Hsiun-ing Chen; Chao-Liang Wu; Yu-Min Kuo; Lung Yu; A-Min Huang; Fong-Sen Wu; Jih-Ing Chuang; Chauying J Jen
Journal:  J Physiol       Date:  2009-05-18       Impact factor: 5.182

10.  Stress-induced atrophy of apical dendrites of hippocampal CA3c neurons: involvement of glucocorticoid secretion and excitatory amino acid receptors.

Authors:  A M Magariños; B S McEwen
Journal:  Neuroscience       Date:  1995-11       Impact factor: 3.590
View more
  18 in total

Review 1.  Exercise as a Positive Modulator of Brain Function.

Authors:  Karim A Alkadhi
Journal:  Mol Neurobiol       Date:  2017-05-02       Impact factor: 5.590

2.  Impact of different intensities of forced exercise on deficits of spatial and aversive memory, anxiety-like behavior, and hippocampal BDNF during morphine abstinence period in male rats.

Authors:  Azadeh Shahroodi; Fatemeh Mohammadi; Abbas Ali Vafaei; Hossein Miladi-Gorji; Ahmad Reza Bandegi; Ali Rashidy-Pour
Journal:  Metab Brain Dis       Date:  2019-11-26       Impact factor: 3.584

3.  The effects of moderate exercise and overtraining on learning and memory, hippocampal inflammatory cytokine levels, and brain oxidative stress markers in rats.

Authors:  Zahra Jahangiri; Zahra Gholamnezhad; Mahmoud Hosseini; Farimah Beheshti; Narges Kasraie
Journal:  J Physiol Sci       Date:  2019-10-22       Impact factor: 2.781

Review 4.  Training your brain: Do mental and physical (MAP) training enhance cognition through the process of neurogenesis in the hippocampus?

Authors:  D M Curlik; T J Shors
Journal:  Neuropharmacology       Date:  2012-08-05       Impact factor: 5.250

5.  Remembering how to run: A descriptive wheel run analysis in CF1 male and female mice.

Authors:  M Jimena Santos; Soledad Picco; Rodrigo Fernández; M Eugenia Pedreira; Mariano Boccia; Martin Klappenbach; Maria C Krawczyk
Journal:  IBRO Neurosci Rep       Date:  2022-04-21

6.  Effects of Exercise Intensity on Acute Circulating Molecular Responses Poststroke.

Authors:  Pierce Boyne; Colleen Meyrose; Jennifer Westover; Dustyn Whitesel; Kristal Hatter; Darcy S Reisman; Daniel Carl; Jane C Khoury; Myron Gerson; Brett Kissela; Kari Dunning
Journal:  Neurorehabil Neural Repair       Date:  2020-01-24       Impact factor: 3.919

7.  A forced running wheel system with a microcontroller that provides high-intensity exercise training in an animal ischemic stroke model.

Authors:  C C Chen; M W Chang; C P Chang; S C Chan; W Y Chang; C L Yang; M T Lin
Journal:  Braz J Med Biol Res       Date:  2014-08-15       Impact factor: 2.590

8.  Improved infrared-sensing running wheel systems with an effective exercise activity indicator.

Authors:  Chi-Chun Chen; Ming-Wen Chang; Ching-Ping Chang; Wen-Ying Chang; Shin-Chieh Chang; Mao-Tsun Lin; Chin-Lung Yang
Journal:  PLoS One       Date:  2015-04-13       Impact factor: 3.240

9.  Modulation of Irisin and Physical Activity on Executive Functions in Obesity and Morbid obesity.

Authors:  A B Fagundo; S Jiménez-Murcia; C Giner-Bartolomé; Z Agüera; S Sauchelli; M Pardo; A B Crujeiras; R Granero; R Baños; C Botella; R de la Torre; J M Fernández-Real; J C Fernández-García; G Frühbeck; A Rodríguez; N Mallorquí-Bagué; S Tárrega; F J Tinahones; R Rodriguez; F Ortega; J M Menchón; F F Casanueva; F Fernández-Aranda
Journal:  Sci Rep       Date:  2016-08-01       Impact factor: 4.379

10.  A Handful of Details to Ensure the Experimental Reproducibility on the FORCED Running Wheel in Rodents: A Systematic Review.

Authors:  Daniel Garrigos; Marta Martínez-Morga; Angel Toval; Yevheniy Kutsenko; Alberto Barreda; Bruno Ribeiro Do Couto; Fernando Navarro-Mateu; José Luis Ferran
Journal:  Front Endocrinol (Lausanne)       Date:  2021-05-10       Impact factor: 5.555
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.