Regulation of C2C12 Differentiation and Control of the Beating Dynamics of Contractile Cells for a Muscle-Driven Biosyncretic Crawler by Electrical Stimulation

Soft Robotics ◽  
2018 ◽  
Vol 5 (6) ◽  
pp. 748-760 ◽  
Author(s):  
Lianqing Liu ◽  
Chuang Zhang ◽  
Wenxue Wang ◽  
Ning Xi ◽  
Yuechao Wang
Author(s):  
Amandine Bouguetoch ◽  
Alain Martin ◽  
Sidney Grosprêtre

Abstract Introduction Training stimuli that partially activate the neuromuscular system, such as motor imagery (MI) or neuromuscular electrical stimulation (NMES), have been previously shown as efficient tools to induce strength gains. Here the efficacy of MI, NMES or NMES + MI trainings has been compared. Methods Thirty-seven participants were enrolled in a training program of ten sessions in 2 weeks targeting plantar flexor muscles, distributed in four groups: MI, NMES, NMES + MI and control. Each group underwent forty contractions in each session, NMES + MI group doing 20 contractions of each modality. Before and after, the neuromuscular function was tested through the recording of maximal voluntary contraction (MVC), but also electrophysiological and mechanical responses associated with electrical nerve stimulation. Muscle architecture was assessed by ultrasonography. Results MVC increased by 11.3 ± 3.5% in NMES group, by 13.8 ± 5.6% in MI, while unchanged for NMES + MI and control. During MVC, a significant increase in V-wave without associated changes in superimposed H-reflex has been observed for NMES and MI, suggesting that neural adaptations occurred at supraspinal level. Rest spinal excitability was increased in the MI group while decreased in the NMES group. No change in muscle architecture (pennation angle, fascicle length) has been found in any group but muscular peak twitch and soleus maximal M-wave increased in the NMES group only. Conclusion Finally, MI and NMES seem to be efficient stimuli to improve strength, although both exhibited different and specific neural plasticity. On its side, NMES + MI combination did not provide the expected gains, suggesting that their effects are not simply cumulative, or even are competitive.


1980 ◽  
Vol 43 (10) ◽  
pp. 795-798 ◽  
Author(s):  
F. K. McKEITH ◽  
C. G. SMITH ◽  
T. R. DUTSON ◽  
J. W. SAVELL ◽  
R. L. HOSTETLER ◽  
...  

Fifteen carcasses, 10 from steers and 5 from cows, were used for the present study. Five steer carcasses (group A) were electrically stimulated as intact, unsplit carcasses. The left sides of 5 steer carcasses (group B) and of 5 cow carcasses (group C) were electrically stimulated; the right sides of the same 5 steer carcasses (group D) and of the same 5 cow carcasses (group E) were used as controls and were not electrically stimulated. Electrically stimulated carcasses and sides (groups A and B) had brighter, more youthful colored lean, less “heat-ring” and produced more tender and more palatable rib steaks than did control sides (group D). Electrical stimulation did not (P > .05) affect ultimate pH or sarcomere length in steers or cows. Light and electron micrographs revealed increased (P < .05) structural damage (more severe contracture bands) in steer or cow muscles from electrically stimulated sides than in muscles from control sides; however, structural damage was not (P >.05) increased when intact steer carcasses were electrically stimulated and compared to unstimulated sides. Troponin-T was reduced in SDS gels of muscle from electrically stimulated, as compared to control, sides of cow carcasses (group C versus group E); no differences in percentage of protein subunits were observed between electrically stimulated and control sides of steer carcasses (group B versus group D). Electrical stimulation can be done on intact carcasses or sides of young beef to improve USDA lean maturity and lean color scores, to reduce “heat-ring” incidence and to improve tenderness.


2005 ◽  
Vol 22 (2) ◽  
pp. 227-243 ◽  
Author(s):  
Tatiana Y. Kostrominova ◽  
Douglas E. Dow ◽  
Robert G. Dennis ◽  
Richard A. Miller ◽  
John A. Faulkner

Loss of innervation in skeletal muscles leads to degeneration, atrophy, and loss of force. These dramatic changes are reflected in modifications of the mRNA expression of a large number of genes. Our goal was to clarify the broad spectrum of molecular events associated with long-term denervation of skeletal muscles. A microarray study compared gene expression profiles of 2-mo denervated and control extensor digitorum longus (EDL) muscles from 6-mo-old rats. The study identified 121 genes with increased and 7 genes with decreased mRNA expression. The expression of 107 of these genes had not been identified previously as changed after denervation. Many of the genes identified were genes that are highly expressed in skeletal muscles during embryonic development, downregulated in adults, and upregulated after denervation of muscle fibers. Electrical stimulation of denervated muscles preserved muscle mass and maximal force at levels similar to those in the control muscles. To understand the processes underlying the effect of electrical stimulation on denervated skeletal muscles, mRNA and protein expression of a number of genes, identified by the microarray study, was compared. The hypothesis was that loss of nerve action potentials and muscle contractions after denervation play the major roles in upregulation of gene expression in skeletal muscles. With electrical stimulation of denervated muscles, the expression levels for these genes were significantly downregulated, consistent with the hypothesis that loss of action potentials and/or contractions contribute to the alterations in gene expression in denervated skeletal muscles.


Stroke ◽  
2021 ◽  
Author(s):  
Zeanna Jadavji ◽  
Jack Zhang ◽  
Brett Paffrath ◽  
Ephrem Zewdie ◽  
Adam Kirton

Background and Purpose: Perinatal stroke is the leading cause of hemiparetic cerebral palsy resulting in lifelong disability for millions of people worldwide. Options for motor rehabilitation are limited, especially for the most severely affected children. Brain computer interfaces (BCIs) sample brain activity to allow users to control external devices. Functional electrical stimulation enhances motor recovery after stroke, and BCI-activated functional electrical stimulation was recently shown to improve upper extremity function in adult stroke. We aimed to determine the ability of children with perinatal stroke to operate a simple BCI. Methods: Twenty-one children with magnetic resonance imaging–confirmed perinatal stroke (57% male, mean [SD] 13.5 [2.6] years, range 9–18) were compared with 24 typically developing controls (71% male, mean age [SD] 13.7 [3.7] years, range 6–18). Participants trained on a simple EEG-based BCI over 2 sessions (10 trials each) utilizing 2 different mental imagery strategies: (1) motor imagery (imagine opening and closing of hands) and (2) goal oriented (imagine effector object moving toward target) to complete 2 tasks: (1) drive a remote controlled car to a target and (2) move a computer cursor to a target. Primary outcome was Cohen Kappa with a score >0.40 suggesting BCI competence. Results: BCI performance was comparable between stroke and control participants. Mean scores were 0.39 (0.18) for stroke versus 0.42 (0.18) for controls (t[42]=0.478, P =0.94). No difference in performance between venous (M=0.45, SD=0.29) and arterial (M=0.34, SD=0.22) stroke (t[82]=1.89, P =0.090) was observed. No effect of task or strategy was observed in the stroke participants. Over 90% of stroke participants demonstrated competency on at least one of the 4 task-strategy combinations. Conclusions: Children with perinatal stroke can achieve proficiency in basic tasks using simple BCI systems. Future directions include exploration of BCI-functional electrical stimulation systems for rehabilitation for children with hemiparesis and other forms of cerebral palsy.


2004 ◽  
Vol 9 (4) ◽  
pp. 203-206 ◽  
Author(s):  
Ayla A Kabalak ◽  
Oytun O Senel ◽  
Nermin Gogus

BACKGROUND AND OBJECTIVES:Recent experiments have shown that transcranial electrical stimulation significantly increases the potency and duration of the analgesic effects of opioids in humans and rats. In the present study, the influence of transcranial electrical stimulation (TCES) on the analgesic effect of remifentanil hydrochloride (HCl) in rats was determined.METHODS:Experiments were performed on 80 albino male Wistar rats. Rats were randomly assigned to four groups: remifentanil HCl, remifentanil HCl and TCES, TCES, and control (n=20/group). Remifentanil HCl was injected on the 55th minute. Analgesia was assessed using the wet tail-flick latency test.RESULTS:In the remifentanil HCl group, analgesia (10.85±1.04 s) was reached at the fifth minute, and the analgesia was high for the first 10 min. In the remifentanil HCl and TCES group, the latency time peaked (16.60±1.19 s) at the fifth minute. This peak was 150% higher than that for the remifentanil HCl group, and 251% higher than the control or TCES groups. Analgesia in the remifentanil HCl and TCES group was sustained for 20 min at a statistically higher rate than the other treatment groups (P<0.001).CONCLUSIONS:TCES markedly increased the duration and analgesic potency of remifentanil HCl in rats. This effect appeared to be related to the release of enkephalins from brain structures, thus enhancing opioid analgesia.


Sign in / Sign up

Export Citation Format

Share Document