Defined electrical stimulation emphasizing excitability for the development and testing of engineered skeletal muscle.

Electrical stimulation is required for the maturation of skeletal muscle and as a way to nondestructively monitor muscle development. However, the wrong stimulation parameters can result in electrochemical damage that impairs muscle development/regeneration. The goal of the current study was to determine what aspect of an electrical impulse, specifically the pulse amplitude or pulse width, was detrimental to engineered muscle function and subsequently how engineered muscle responded to continuous electrical stimulation for 24 h. Acute stimulation at a pulse amplitude greater than six-times rheobase resulted in a 2.4-fold increase in the half-relaxation time (32.3±0.49 ms vs. 77.4±4.35 ms; p<0.05) and a 1.59-fold increase in fatigability (38.2%±3.61% vs. 60.6%±4.52%; p<0.05). No negative effects were observed when the pulse energy was increased by lengthening the pulse width, indicating electrochemical damage was due to electric fields at or above six-times rheobase. Continuous stimulation for 24 h at electric fields greater than 0.5 V/mm consistently resulted in ∼2.5-fold increase in force (0.30±0.04 kN/m² vs. 0.67±0.06 kN/m²; p<0.05). Forty per cent of this increase in force was dependent on the mammalian target of rapamycin (RAP) complex 1 (mTORC1), as RAP prevented this portion of the increase in force (CON=0.30±0.04 kN/m² to 0.67±0.06 kN/m² compared with RAP=0.21±0.01 kN/m² to 0.37±0.04 kN/m²; p<0.05). Since there was no increase in myosin heavy chain, the remaining increase in force over the 24 h of stimulation is likely due to cytoskeletal rearrangement. These data indicate that electrochemical damage occurs in muscle at a voltage field greater than six-times rheobase and therefore optimal muscle stimulation should be performed using lower electric fields (two- to four-times rheobase).

[1]  Makoto Kanzaki,et al.  Accelerated de novo sarcomere assembly by electric pulse stimulation in C2C12 myotubes. , 2007, Experimental cell research.

[2]  In-Hyun Park,et al.  Skeletal myocyte hypertrophy requires mTOR kinase activity and S6K1. , 2005, Experimental cell research.

[3]  Keith Baar,et al.  Cultured slow vs. fast skeletal muscle cells differ in physiology and responsiveness to stimulation. , 2006, American journal of physiology. Cell physiology.

[4]  K. Baar,et al.  Regulating fibrinolysis to engineer skeletal muscle from the C2C12 cell line. , 2009, Tissue engineering. Part C, Methods.

[5]  E. Spangenburg,et al.  Lengthening contractions differentially affect p70s6k phosphorylation compared to isometric contractions in rat skeletal muscle , 2007, European Journal of Applied Physiology.

[6]  S. Cairns,et al.  Stimulation pulse characteristics and electrode configuration determine site of excitation in isolated mammalian skeletal muscle: implications for fatigue. , 2007, Journal of applied physiology.

[7]  S. L. Andersen,et al.  Calcitonin gene-related peptide stimulates active Na(+)-K+ transport in rat soleus muscle. , 1993, American Journal of Physiology.

[8]  Wei Chen Electroconformational Denaturation of Membrane Proteins , 2005, Annals of the New York Academy of Sciences.

[9]  F. Worek,et al.  Reevaluation of indirect field stimulation technique to demonstrate oxime effectiveness in OP-poisoning in muscles in vitro. , 2007, Toxicology.

[10]  A. Zahradníková,et al.  Local calcium release activation by DHPR calcium channel openings in rat cardiac myocytes , 2008, The Journal of physiology.

[11]  M. Hincke,et al.  Fibrin: a versatile scaffold for tissue engineering applications. , 2008, Tissue engineering. Part B, Reviews.

[12]  F. Booth,et al.  Skeletal muscle enlargement with weight-lifting exercise by rats. , 1988, Journal of applied physiology.

[13]  K. Esser,et al.  Phosphorylation of p70(S6k) correlates with increased skeletal muscle mass following resistance exercise. , 1999, The American journal of physiology.

[14]  E. Jaimovich,et al.  Depolarization-induced slow calcium transients activate early genes in skeletal muscle cells. , 2003, American journal of physiology. Cell physiology.

[15]  K. Donnelly,et al.  Engineered Muscle: A Tool for Studying Muscle Physiology and Function , 2007, Exercise and sport sciences reviews.

[16]  J. Teissié,et al.  Evidence of voltage-induced channel opening in Na/K ATPase of human erythrocyte membrane , 1980, The Journal of Membrane Biology.

[17]  Robert G. Dennis,et al.  Excitability and isometric contractile properties of mammalian skeletal muscle constructs engineered in vitro , 2000, In Vitro Cellular & Developmental Biology - Animal.

[18]  Makoto Kanzaki,et al.  Contractile C2C12 myotube model for studying exercise-inducible responses in skeletal muscle. , 2008, American journal of physiology. Endocrinology and metabolism.

[19]  R E Horch,et al.  Impact of electrical stimulation on three‐dimensional myoblast cultures ‐ a real‐time RT‐PCR study , 2005, Journal of cellular and molecular medicine.

[20]  S. L. Andersen,et al.  Na(+)‐K+ pump stimulation elicits recovery of contractility in K(+)‐paralysed rat muscle. , 1993, The Journal of physiology.

[21]  Daniel Stricker,et al.  BrightStat.com: Free statistics online , 2008, Comput. Methods Programs Biomed..

[22]  Raphael C. Lee,et al.  Dynamics of Membrane Sealing in Transient Electropermeabilization of Skeletal Muscle Membranes , 1999, Annals of the New York Academy of Sciences.

[23]  S. Salmons,et al.  Significance of impulse activity in the transformation of skeletal muscle type , 1976, Nature.

[24]  K. Overgaard,et al.  Relations between excitability and contractility in rat soleus muscle: role of the Na+‐K+ pump and Na+/K+ gradients , 1999, The Journal of physiology.

[25]  N. LeBrasseur,et al.  Contraction-mediated mTOR, p70S6k, and ERK1/2 phosphorylation in aged skeletal muscle. , 2004, Journal of applied physiology.

[26]  R G Dennis,et al.  Excitability and contractility of skeletal muscle engineered from primary cultures and cell lines. , 2001, American journal of physiology. Cell physiology.

[27]  T. Tsong,et al.  Electroporation of cell membranes. , 1991, Biophysical journal.

[28]  Jennifer Koh,et al.  Engineering skeletal myoblasts: roles of three-dimensional culture and electrical stimulation. , 2005, American journal of physiology. Heart and circulatory physiology.

[29]  Leslie Tung,et al.  Paradoxical loss of excitation with high intensity pulses during electric field stimulation of single cardiac cells. , 2005, Biophysical journal.

[30]  T. Clausen Role of Na+,K+‐pumps and transmembrane Na+,K+‐distribution in muscle function , 2008, Acta physiologica.

[31]  E. Blomstrand,et al.  Maximal lengthening contractions induce different signaling responses in the type I and type II fibers of human skeletal muscle. , 2009, Journal of applied physiology.

[32]  Jorge Hidalgo,et al.  Membrane Electrical Activity Elicits Inositol 1,4,5-Trisphosphate-dependent Slow Ca2+ Signals through a Gβγ/Phosphatidylinositol 3-Kinase γ Pathway in Skeletal Myotubes* , 2006, Journal of Biological Chemistry.

[33]  U. Boutellier,et al.  Electric Pulse Stimulation of Cultured Murine Muscle Cells Reproduces Gene Expression Changes of Trained Mouse Muscle , 2010, PloS one.

[34]  G. Somjen,et al.  Excitability and inhibitability of motoneurons of different sizes. , 1965, Journal of neurophysiology.

[35]  Ali Khademhosseini,et al.  Interdigitated array of Pt electrodes for electrical stimulation and engineering of aligned muscle tissue. , 2012, Lab on a chip.

[36]  R. Lee,et al.  Altered ion channel conductance and ionic selectivity induced by large imposed membrane potential pulse. , 1994, Biophysical journal.

[37]  R. Dennis,et al.  Functional evaluation of nerve-skeletal muscle constructs engineered in vitro , 2007, In Vitro Cellular & Developmental Biology - Animal.

[38]  G. Yancopoulos,et al.  Akt/mTOR pathway is a crucial regulator of skeletal muscle hypertrophy and can prevent muscle atrophy in vivo , 2001, Nature Cell Biology.

[39]  Douglas E Dow,et al.  Excitability of skeletal muscle during development, denervation, and tissue culture. , 2007, Tissue engineering.

[40]  M. Estrada,et al.  Dihydropyridine Receptors as Voltage Sensors for a Depolarization-evoked, IP3R-mediated, Slow Calcium Signal in Skeletal Muscle Cells , 2003, The Journal of general physiology.

[41]  A J Harris,et al.  Neural determination of muscle fibre numbers in embryonic rat lumbrical muscles. , 1987, Development.

[42]  Keith Baar,et al.  Rapid formation of functional muscle in vitro using fibrin gels. , 2005, Journal of applied physiology.

[43]  J. Teissié,et al.  Voltage modulation of Na+/K+ transport in human erythrocytes. , 1981, Journal de physiologie.

[44]  S. Bodine mTOR signaling and the molecular adaptation to resistance exercise. , 2006, Medicine and science in sports and exercise.

[45]  A. Quest,et al.  Depolarization of Skeletal Muscle Cells induces Phosphorylation of cAMP Response Element Binding Protein via Calcium and Protein Kinase Cα* , 2004, Journal of Biological Chemistry.

[46]  Louise Deldicque,et al.  A novel bioreactor for stimulating skeletal muscle in vitro. , 2010, Tissue engineering. Part C, Methods.

[47]  Stanley Salmons,et al.  Determination of the chronaxie and rheobase of denervated limb muscles in conscious rabbits. , 2005, Artificial organs.

[48]  K. Overgaard,et al.  The role of K+ channels in the force recovery elicited by Na+‐K+ pump stimulation in Ba2+‐paralysed rat skeletal muscle , 2000, The Journal of physiology.

[49]  E. Blomstrand,et al.  Maximal lengthening contractions increase p70 S6 kinase phosphorylation in human skeletal muscle in the absence of nutritional supply. , 2006, American journal of physiology. Endocrinology and metabolism.

[50]  D. Pette,et al.  Effects of chronic electrical stimulation on myosin heavy chain expression in satellite cell cultures derived from rat muscles of different fiber-type composition. , 1994, Differentiation; research in biological diversity.

[51]  J. Babraj,et al.  Selective activation of AMPK‐PGC‐1α or PKB‐TSC2‐mTOR signaling can explain specific adaptive responses to endurance or resistance training‐like electrical muscle stimulation , 2005, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.