A novel bioreactor for stimulating skeletal muscle in vitro.

For over 300 years, scientists have understood that stimulation, in the form of an electrical impulse, is required for normal muscle function. More recently, the role of specific parameters of the electrical impulse (i.e., the pulse amplitude, pulse width, and work-to-rest ratio) has become better appreciated. However, most existing bioreactor systems do not permit sufficient control over these parameters. Therefore, the aim of the current study was to engineer an inexpensive muscle electrical stimulation bioreactor to apply physiologically relevant electrical stimulation patterns to tissue-engineered muscles and monolayers in culture. A low-powered microcontroller and a DC-DC converter were used to power a pulse circuit that converted a 4.5 V input to outputs of up to 50 V, with pulse widths from 0.05 to 4 ms, and frequencies up to 100 Hz (with certain operational limitations). When two-dimensional cultures were stimulated at high frequencies (100 Hz), this resulted in an increase in the rate of protein synthesis (at 12 h, control [CTL] = 5.0 + or - 0.16; 10 Hz = 5.0 + or - 0.07; and 100 Hz = 5.5 + or - 0.13 fmol/min/mg) showing that this was an anabolic signal. When three-dimensional engineered muscles were stimulated at 0.1 ms and one or two times rheobase, stimulation improved force production (CTL = 0.07 + or - 0.009; 1.25 V/mm = 0.10 + or - 0.011; 2.5 V/mm = 0.14146 + or - 0.012; and 5 V/mm = 0.03756 + or - 0.008 kN/mm(2)) and excitability (CTL = 0.53 + or - 0.022; 1.25 V/mm = 0.44 + or - 0.025; 2.5 V/mm = 0.41 + or - 0.012; and 5 V/mm = 0.60 + or - 0.021 V/mm), suggesting enhanced maturation. Together, these data show that the physiology and function of muscles can be improved in vitro using a bioreactor that allows the control of pulse amplitude, pulse width, pulse frequency, and work-to-rest ratio.

[1]  K. Donnelly,et al.  Bioreactors for guiding muscle tissue growth and development. , 2009, Advances in biochemical engineering/biotechnology.

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

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

[4]  Douglas E Dow,et al.  Number of contractions to maintain mass and force of a denervated rat muscle , 2004, Muscle & nerve.

[5]  R. Dennis Bipolar implantable stimulator for long-term denervated-muscle experiments , 1998, Medical and Biological Engineering and Computing.

[6]  D. Bolster,et al.  Regulation of protein synthesis associated with skeletal muscle hypertrophy by insulin-, amino acid- and exercise-induced signalling , 2004, The Proceedings of the Nutrition Society.

[7]  R. B. Young,et al.  Effect of electrical stimulation on β-adrenergic receptor population and cyclic AMP production in chicken and rat skeletal muscle cell cultures , 2000, In Vitro Cellular & Developmental Biology - Animal.

[8]  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.

[9]  A. J. Harris,et al.  Formation of myotubes in aneural rat muscles. , 1993, Developmental biology.

[10]  Jonathan C. Jarvis,et al.  Implantable device for long-term electrical stimulation of denervated muscles in rabbits , 2005, Medical and Biological Engineering and Computing.

[11]  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.

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

[13]  A. J. Harris,et al.  Neural control of the sequence of expression of myosin heavy chain isoforms in foetal mammalian muscles. , 1989, Development.

[14]  Stephen F. Badylak,et al.  Comparison of three methods of electrical stimulation for converting skeletal muscle to a fatigue resistant power source suitable for cardiac assistance , 2006, Annals of Biomedical Engineering.

[15]  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.

[16]  J. Faulkner,et al.  An implantable device for stimulation of denervated muscles in rats. , 2003, Medical engineering & physics.

[17]  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.

[18]  Douglas E Dow,et al.  Comparison of gene expression of 2-mo denervated, 2-mo stimulated-denervated, and control rat skeletal muscles. , 2005, Physiological genomics.

[19]  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.

[20]  L. Landmesser,et al.  A reevaluation of the role of innervation in primary and secondary myogenesis in developing chick muscle. , 1991, Developmental biology.

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

[22]  G. Vrbóva,et al.  Changes in the speed of mammalian fast muscle following longterm stimulation. , 1967, The Journal of physiology.

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

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

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

[26]  S. Marom,et al.  Electrophysiological Modulation of Cardiomyocytic Tissue by Transfected Fibroblasts Expressing Potassium Channels: A Novel Strategy to Manipulate Excitability , 2002, Circulation.