Literature DB >> 26611563

Single pellet grasping following cervical spinal cord injury in adult rat using an automated full-time training robot.

Keith K Fenrich1, Zacincte May2, Abel Torres-Espín2, Juan Forero2, David J Bennett2, Karim Fouad2.   

Abstract

Task specific motor training is a common form of rehabilitation therapy in individuals with spinal cord injury (SCI). The single pellet grasping (SPG) task is a skilled forelimb motor task used to evaluate recovery of forelimb function in rodent models of SCI. The task requires animals to obtain food pellets located on a shelf beyond a slit at the front of an enclosure. Manually training and testing rats in the SPG task requires extensive time and often yields results with high outcome variability and small therapeutic windows (i.e., the difference between pre- and post-SCI success rates). Recent advances in automated SPG training using automated pellet presentation (APP) systems allow rats to train ad libitum 24h a day, 7 days a week. APP trained rats have improved success rates, require less researcher time, and have lower outcome variability compared to manually trained rats. However, it is unclear whether APP trained rats can perform the SPG task using the APP system after SCI. Here we show that rats with cervical SCI can successfully perform the SPG task using the APP system. We found that SCI rats with APP training performed significantly more attempts, had slightly lower and less variable final score success rates, and larger therapeutic windows than SCI rats with manual training. These results demonstrate that APP training has clear advantages over manual training for evaluating reaching performance of SCI rats and represents a new tool for investigating rehabilitative motor training following CNS injury.
Copyright © 2015 Elsevier B.V. All rights reserved.

Entities:  

Keywords:  Automated animal training; Grasping; Motor behavior; Reaching; Rehabilitation; Single pellet grasping; Skilled motor task; Spinal cord injury

Mesh:

Year:  2015        PMID: 26611563      PMCID: PMC5155446          DOI: 10.1016/j.bbr.2015.11.020

Source DB:  PubMed          Journal:  Behav Brain Res        ISSN: 0166-4328            Impact factor:   3.332


  33 in total

1.  Delayed Intervention with Intermittent Hypoxia and Task Training Improves Forelimb Function in a Rat Model of Cervical Spinal Injury.

Authors:  Erin J Prosser-Loose; Atiq Hassan; Gordon S Mitchell; Gillian D Muir
Journal:  J Neurotrauma       Date:  2015-05-07       Impact factor: 5.269

2.  Compensation aids skilled reaching in aging and in recovery from forelimb motor cortex stroke in the rat.

Authors:  M Alaverdashvili; I Q Whishaw
Journal:  Neuroscience       Date:  2010-02-08       Impact factor: 3.590

3.  Skilled reaching impairments follow intrastriatal hemorrhagic stroke in rats.

Authors:  Crystal L MacLellan; Selina Gyawali; Frederick Colbourne
Journal:  Behav Brain Res       Date:  2006-09-07       Impact factor: 3.332

4.  Hindlimb immobilization in a wheelchair alters functional recovery following contusive spinal cord injury in the adult rat.

Authors:  Krista L Caudle; Edward H Brown; Alice Shum-Siu; Darlene A Burke; Trystan S G Magnuson; Michael J Voor; David S K Magnuson
Journal:  Neurorehabil Neural Repair       Date:  2011-06-22       Impact factor: 3.919

5.  Functional switch between motor tracts in the presence of the mAb IN-1 in the adult rat.

Authors:  O Raineteau; K Fouad; P Noth; M Thallmair; M E Schwab
Journal:  Proc Natl Acad Sci U S A       Date:  2001-05-29       Impact factor: 11.205

6.  The impairments in reaching and the movements of compensation in rats with motor cortex lesions: an endpoint, videorecording, and movement notation analysis.

Authors:  I Q Whishaw; S M Pellis; B P Gorny; V C Pellis
Journal:  Behav Brain Res       Date:  1991-01-31       Impact factor: 3.332

7.  The contributions of motor cortex, nigrostriatal dopamine and caudate-putamen to skilled forelimb use in the rat.

Authors:  I Q Whishaw; W T O'Connor; S B Dunnett
Journal:  Brain       Date:  1986-10       Impact factor: 13.501

8.  Undesired effects of a combinatorial treatment for spinal cord injury--transplantation of olfactory ensheathing cells and BDNF infusion to the red nucleus.

Authors:  Frederic Bretzner; Jie Liu; Erin Currie; A Jane Roskams; Wolfram Tetzlaff
Journal:  Eur J Neurosci       Date:  2008-11       Impact factor: 3.386

9.  Synergistic effects of BDNF and rehabilitative training on recovery after cervical spinal cord injury.

Authors:  N Weishaupt; S Li; A Di Pardo; S Sipione; K Fouad
Journal:  Behav Brain Res       Date:  2012-11-03       Impact factor: 3.332

10.  Ketogenic diet improves forelimb motor function after spinal cord injury in rodents.

Authors:  Femke Streijger; Ward T Plunet; Jae H T Lee; Jie Liu; Clarrie K Lam; Soeyun Park; Brett J Hilton; Bas L Fransen; Keely A J Matheson; Peggy Assinck; Brian K Kwon; Wolfram Tetzlaff
Journal:  PLoS One       Date:  2013-11-04       Impact factor: 3.240
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  9 in total

1.  Subcutaneous priming of protein-functionalized chitosan scaffolds improves function following spinal cord injury.

Authors:  Trevor R Ham; Dipak D Pukale; Mohammad Hamrangsekachaee; Nic D Leipzig
Journal:  Mater Sci Eng C Mater Biol Appl       Date:  2020-01-10       Impact factor: 7.328

Review 2.  Animal models of spinal cord injury: a systematic review.

Authors:  M Sharif-Alhoseini; M Khormali; M Rezaei; M Safdarian; A Hajighadery; M M Khalatbari; M Safdarian; S Meknatkhah; M Rezvan; M Chalangari; P Derakhshan; V Rahimi-Movaghar
Journal:  Spinal Cord       Date:  2017-01-24       Impact factor: 2.772

3.  Eliciting inflammation enables successful rehabilitative training in chronic spinal cord injury.

Authors:  Abel Torres-Espín; Juan Forero; Keith K Fenrich; Ana M Lucas-Osma; Aleksandra Krajacic; Emma Schmidt; Romana Vavrek; Pamela Raposo; David J Bennett; Phillip G Popovich; Karim Fouad
Journal:  Brain       Date:  2018-07-01       Impact factor: 13.501

Review 4.  Behavioral testing in animal models of spinal cord injury.

Authors:  K Fouad; C Ng; D M Basso
Journal:  Exp Neurol       Date:  2020-07-28       Impact factor: 5.330

Review 5.  Supraspinal Control Predicts Locomotor Function and Forecasts Responsiveness to Training after Spinal Cord Injury.

Authors:  Edelle C Field-Fote; Jaynie F Yang; D Michele Basso; Monica A Gorassini
Journal:  J Neurotrauma       Date:  2016-12-20       Impact factor: 5.269

Review 6.  Biomaterial strategies for limiting the impact of secondary events following spinal cord injury.

Authors:  Trevor R Ham; Nic D Leipzig
Journal:  Biomed Mater       Date:  2018-02-08       Impact factor: 3.715

7.  An automated homecage system for multiwhisker detection and discrimination learning in mice.

Authors:  Sarah M Bernhard; Jiseok Lee; Mo Zhu; Alex Hsu; Andrew Erskine; Samuel A Hires; Alison L Barth
Journal:  PLoS One       Date:  2020-12-02       Impact factor: 3.240

Review 8.  When Spinal Neuromodulation Meets Sensorimotor Rehabilitation: Lessons Learned From Animal Models to Regain Manual Dexterity After a Spinal Cord Injury.

Authors:  África Flores; Diego López-Santos; Guillermo García-Alías
Journal:  Front Rehabil Sci       Date:  2021-12-07

9.  Skilled reach training enhances robotic gait training to restore overground locomotion following spinal cord injury in rats.

Authors:  Nathan D Neckel; Haining Dai; John Hanckel; Yichien Lee; Christopher Albanese; Olga Rodriguez
Journal:  Behav Brain Res       Date:  2021-08-03       Impact factor: 3.352
  9 in total

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