Literature DB >> 16634064

Predictive model of muscle fatigue after spinal cord injury in humans.

Richard K Shields1, Ya-Ju Chang, Shauna Dudley-Javoroski, Cheng-Hsiang Lin.   

Abstract

The fatigability of paralyzed muscle limits its ability to deliver physiological loads to paralyzed extremities during repetitive electrical stimulation. The purposes of this study were to determine the reliability of measuring paralyzed muscle fatigue and to develop a model to predict the temporal changes in muscle fatigue that occur after spinal cord injury (SCI). Thirty-four subjects underwent soleus fatigue testing with a modified Burke electrical stimulation fatigue protocol. The between-day reliability of this protocol was high (intraclass correlation, 0.96). We fit the fatigue index (FI) data to a quadratic-linear segmental polynomial model. FI declined rapidly (0.3854 per year) for the first 1.7 years, and more slowly (0.01 per year) thereafter. The rapid decline of FI immediately after SCI implies that a "window of opportunity" exists for the clinician if the goal is to prevent these changes. Understanding the timing of change in muscle endurance properties (and, therefore, load-generating capacity) after SCI may assist clinicians when developing therapeutic interventions to maintain musculoskeletal integrity.

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Year:  2006        PMID: 16634064      PMCID: PMC3272267          DOI: 10.1002/mus.20564

Source DB:  PubMed          Journal:  Muscle Nerve        ISSN: 0148-639X            Impact factor:   3.217


  34 in total

1.  Effects of electrically induced fatigue on the twitch and tetanus of paralyzed soleus muscle in humans.

Authors:  R K Shields; L F Law; B Reiling; K Sass; J Wilwert
Journal:  J Appl Physiol (1985)       Date:  1997-05

2.  The effects of fatigue on the torque-frequency curve of the human paralysed soleus muscle.

Authors:  R K Shields; Y J Chang
Journal:  J Electromyogr Kinesiol       Date:  1997-03       Impact factor: 2.368

3.  Increased bone mineral density after prolonged electrically induced cycle training of paralyzed limbs in spinal cord injured man.

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Journal:  Calcif Tissue Int       Date:  1997-07       Impact factor: 4.333

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Journal:  Dev Med Child Neurol       Date:  1986-08       Impact factor: 5.449

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Journal:  Exp Neurol       Date:  1986-03       Impact factor: 5.330

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Authors:  E González; O Delbono
Journal:  Mech Ageing Dev       Date:  2001-07-31       Impact factor: 5.432

7.  Influence of different stimulation frequencies on power output and fatigue during FES-cycling in recently injured SCI people.

Authors:  Prisca C Eser; Nick de N Donaldson; Hans Knecht; Edgar Stüssi
Journal:  IEEE Trans Neural Syst Rehabil Eng       Date:  2003-09       Impact factor: 3.802

8.  Effects of functional electrical stimulation-induced lower extremity cycling on bone density of spinal cord-injured patients.

Authors:  K K BeDell; A M Scremin; K L Perell; C F Kunkel
Journal:  Am J Phys Med Rehabil       Date:  1996 Jan-Feb       Impact factor: 2.159

9.  Bone mass and endocrine adaptations to training in spinal cord injured individuals.

Authors:  S A Bloomfield; W J Mysiw; R D Jackson
Journal:  Bone       Date:  1996-07       Impact factor: 4.398

10.  Influence of electrical stimulation on the morphological and metabolic properties of paralyzed muscle.

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Journal:  J Appl Physiol (1985)       Date:  1992-04
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  9 in total

1.  Hybrid stimulation enhances torque as a function of muscle fusion in human paralyzed and non-paralyzed skeletal muscle.

Authors:  Keith R Cole; Shauna Dudley-Javoroski; Richard K Shields
Journal:  J Spinal Cord Med       Date:  2018-06-20       Impact factor: 1.985

2.  Altered mRNA expression after long-term soleus electrical stimulation training in humans with paralysis.

Authors:  Christopher M Adams; Manish Suneja; Shauna Dudley-Javoroski; Richard K Shields
Journal:  Muscle Nerve       Date:  2011-01       Impact factor: 3.217

3.  Mathematical models of human paralyzed muscle after long-term training.

Authors:  L A Frey Law; R K Shields
Journal:  J Biomech       Date:  2007-02-20       Impact factor: 2.712

Review 4.  Muscle and bone plasticity after spinal cord injury: review of adaptations to disuse and to electrical muscle stimulation.

Authors:  Shauna Dudley-Javoroski; Richard K Shields
Journal:  J Rehabil Res Dev       Date:  2008

5.  Impact of short- and long-term electrically induced muscle exercise on gene signaling pathways, gene expression, and PGC1a methylation in men with spinal cord injury.

Authors:  Michael A Petrie; Arpit Sharma; Eric B Taylor; Manish Suneja; Richard K Shields
Journal:  Physiol Genomics       Date:  2019-12-23       Impact factor: 3.107

6.  A minimal dose of electrically induced muscle activity regulates distinct gene signaling pathways in humans with spinal cord injury.

Authors:  Michael A Petrie; Manish Suneja; Elizabeth Faidley; Richard K Shields
Journal:  PLoS One       Date:  2014-12-22       Impact factor: 3.240

Review 7.  In Vivo Assessment of Mitochondrial Dysfunction in Clinical Populations Using Near-Infrared Spectroscopy.

Authors:  T Bradley Willingham; Kevin K McCully
Journal:  Front Physiol       Date:  2017-09-14       Impact factor: 4.566

8.  Mechanism of Fatigue Induced by Different Cycling Paradigms With Equivalent Dosage.

Authors:  Miao-Ju Hsu; Hsiao-Lung Chan; Ying-Zu Huang; Jau-Hong Lin; Heng-Hsiang Hsu; Ya-Ju Chang
Journal:  Front Physiol       Date:  2020-05-29       Impact factor: 4.566

9.  Low-Intensity Electrical Stimulation to Improve the Neurological Aspect of Weakness in Individuals with Chronic Anterior Cruciate Ligament Lesion.

Authors:  Wen-Tzu Tang; Miao-Ju Hsu; Yi-Ming Huang; Yu-Ting Hsu; Li-Ling Chuang; Ya-Ju Chang
Journal:  Biomed Res Int       Date:  2020-03-23       Impact factor: 3.411
  9 in total

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