Literature DB >> 20813653

Muscle plasticity in rat following spinal transection and chronic intraspinal microstimulation.

Jeremy A Bamford1, Charles T Putman, Vivian K Mushahwar.   

Abstract

Intraspinal microstimulation (ISMS) employs electrical stimulation of the ventral grey matter to reactivate paralyzed skeletal muscle. This work evaluated the transformations in the quadriceps muscle that occurred following complete transection and chronic stimulation with ISMS or a standard nerve cuff (NCS). Stimulation was applied for 30 days, 4 h/day. Both methods induced significant increases in time-to-peak tension (ISMS 35%, NCS 25%) and half rise-time (ISMS 39%, NCS 25%) compared to intact controls (IC). Corresponding increases in type-IIA myosin heavy chain (MHC) and decreases in type-IID MHC were noted compared to IC. These results were unexpected because ISMS recruits motor units in a near-normal physiological order while NCS recruits motor units in a reversed order. Spinal cord transection and 30 days of stimulation did not alter either recruitment profile. The slope of the force recruitment curves obtained through ISMS following transection and 30 days of stimulation was similar to that obtained in intact animals, and 3.4-fold shallower than that obtained through NCS. The transformations observed in the current work are best explained by the near maximal level of motor unit recruitment, the total daily time of activity and the tonic nature of the stimulation paradigm.

Entities:  

Mesh:

Year:  2010        PMID: 20813653      PMCID: PMC3037113          DOI: 10.1109/TNSRE.2010.2052832

Source DB:  PubMed          Journal:  IEEE Trans Neural Syst Rehabil Eng        ISSN: 1534-4320            Impact factor:   3.802


  12 in total

Review 1.  What does chronic electrical stimulation teach us about muscle plasticity?

Authors:  D Pette; G Vrbová
Journal:  Muscle Nerve       Date:  1999-06       Impact factor: 3.217

2.  Muscle recruitment through electrical stimulation of the lumbo-sacral spinal cord.

Authors:  V K Mushahwar; K W Horch
Journal:  IEEE Trans Rehabil Eng       Date:  2000-03

3.  Spinal cord microstimulation generates functional limb movements in chronically implanted cats.

Authors:  V K Mushahwar; D F Collins; A Prochazka
Journal:  Exp Neurol       Date:  2000-06       Impact factor: 5.330

4.  Effects of isoflurane and enflurane on GABAA and glycine receptors contribute equally to depressant actions on spinal ventral horn neurones in rats.

Authors:  C Grasshoff; B Antkowiak
Journal:  Br J Anaesth       Date:  2006-09-13       Impact factor: 9.166

5.  Intraspinal microstimulation preferentially recruits fatigue-resistant muscle fibres and generates gradual force in rat.

Authors:  J A Bamford; C T Putman; V K Mushahwar
Journal:  J Physiol       Date:  2005-10-20       Impact factor: 5.182

6.  Intraspinal microstimulation excites multisegmental sensory afferents at lower stimulus levels than local alpha-motoneuron responses.

Authors:  R A Gaunt; A Prochazka; V K Mushahwar; L Guevremont; P H Ellaway
Journal:  J Neurophysiol       Date:  2006-08-30       Impact factor: 2.714

7.  New functional electrical stimulation approaches to standing and walking.

Authors:  Vivian K Mushahwar; Patrick L Jacobs; Richard A Normann; Ronald J Triolo; Naomi Kleitman
Journal:  J Neural Eng       Date:  2007-08-22       Impact factor: 5.379

8.  Intraspinal microstimulation using cylindrical multielectrodes.

Authors:  Sean Snow; Kenneth W Horch; Vivian K Mushahwar
Journal:  IEEE Trans Biomed Eng       Date:  2006-02       Impact factor: 4.538

9.  Effects of physiological amounts of high- and low-rate chronic stimulation on fast-twitch muscle of the cat hindlimb. I. Speed- and force-related properties.

Authors:  D Kernell; O Eerbeek; B A Verhey; Y Donselaar
Journal:  J Neurophysiol       Date:  1987-09       Impact factor: 2.714

Review 10.  Muscle mechanics: adaptations with exercise-training.

Authors:  R H Fitts; J J Widrick
Journal:  Exerc Sport Sci Rev       Date:  1996       Impact factor: 6.230
View more
  7 in total

1.  Cervical intraspinal microstimulation evokes robust forelimb movements before and after injury.

Authors:  Michael D Sunshine; Frances S Cho; Danielle R Lockwood; Amber S Fechko; Michael R Kasten; Chet T Moritz
Journal:  J Neural Eng       Date:  2013-04-03       Impact factor: 5.379

Review 2.  Enhancing neural activity to drive respiratory plasticity following cervical spinal cord injury.

Authors:  Kristiina M Hormigo; Lyandysha V Zholudeva; Victoria M Spruance; Vitaliy Marchenko; Marie-Pascale Cote; Stephane Vinit; Simon Giszter; Tatiana Bezdudnaya; Michael A Lane
Journal:  Exp Neurol       Date:  2016-08-28       Impact factor: 5.330

Review 3.  Intraspinal microstimulation for the recovery of function following spinal cord injury.

Authors:  Jeremy A Bamford; Vivian K Mushahwar
Journal:  Prog Brain Res       Date:  2011       Impact factor: 2.453

Review 4.  A Review of Different Stimulation Methods for Functional Reconstruction and Comparison of Respiratory Function after Cervical Spinal Cord Injury.

Authors:  Jiaqi Chang; Dongkai Shen; Yixuan Wang; Na Wang; Ya Liang
Journal:  Appl Bionics Biomech       Date:  2020-09-17       Impact factor: 1.781

Review 5.  Spinal primitives and intra-spinal micro-stimulation (ISMS) based prostheses: a neurobiological perspective on the "known unknowns" in ISMS and future prospects.

Authors:  Simon F Giszter
Journal:  Front Neurosci       Date:  2015-03-20       Impact factor: 4.677

6.  A general framework for automatic closed-loop control of bladder voiding induced by intraspinal microstimulation in rats.

Authors:  Abolhasan Yousefpour; Abbas Erfanian
Journal:  Sci Rep       Date:  2021-02-09       Impact factor: 4.379

7.  Influence of spinal cord injury on core regions of motor function.

Authors:  Xiao-Yan Shen; Chun-Ling Tao; Lei Ma; Jia-Huan Shen; Zhi-Ling Li; Zhi-Gong Wang; Xiao-Ying Lü
Journal:  Neural Regen Res       Date:  2021-03       Impact factor: 5.135
  7 in total

北京卡尤迪生物科技股份有限公司 © 2022-2023.