Novel Ideas for Fast Muscle Action Potential Simulations Using the Line Source Model

Hammarberg, Björn; Stålberg, Erik

doi:10.1109/tbme.2004.834292

Cited by 9 publications

(2 citation statements)

References 25 publications

(37 reference statements)

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“…This is likely due to the longer period over which the depolarization occurs, the propagation of the intracellular action potential along the myotube, and the changing shape and location of the myotube during excitation and contraction. 16‐18 Despite the variability in spike shape, however, spikes generated by a single biological unit are remarkably reproducible, as evidenced by the small within‐unit variability (Figure 1E).…”

Section: Resultsmentioning

confidence: 99%

Skeletal myotube integration with planar microelectrode arrays in vitro for spatially selective recording and stimulation: A comparison of neuronal and myotube extracellular action potentials

Langhammer

Kutzing

Luo

et al. 2011

Biotechnology Progress

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Microelectrode array (MEA) technology holds tremendous potential in the fields of bio-detection, lab-on-a-chip applications, and tissue engineering by facilitating non-invasive electrical interaction with cells in vitro. To date, significant efforts at integrating the cellular component with this detection technology have worked exclusively with neurons or cardiac myocytes. We investigate the feasibility of using MEAs to record from skeletal myotubes derived from primary myoblasts as a way of introducing a third electrogenic cell type and expanding the potential end applications for MEA-based biosensors. We find that the extracellular action potentials (EAPs) produced by spontaneously contractile myotubes have similar amplitudes to neuronal EAPs. It is possible to classify myotube EAPs by biological signal source using a shape-based spike sorting process similar to that used to analyze neural spike trains. Successful spike-sorting is indicated by a low within-unit variability of myotube EAPs. Additionally, myotube activity can cause simultaneous activation of multiple electrodes, in a similar fashion to the activation of electrodes by networks of neurons. The existence of multiple electrode activation patterns indicates the presence of several large, independent myotubes. The ability to identify these patterns suggests that MEAs may provide an electrophysiological basis for examining the process by which myotube independence is maintained despite rapid myoblast fusion during differentiation. Finally, it is possible to use the underlying electrodes to selectively stimulate individual myotubes without stimulating others nearby. Potential uses of skeletal myotubes grown on MEA substrates include lab-on-a-chip applications, tissue engineering, co-cultures with motor neurons, and neural interfaces.

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Section: Resultsmentioning

confidence: 99%

Skeletal myotube integration with planar microelectrode arrays in vitro for spatially selective recording and stimulation: A comparison of neuronal and myotube extracellular action potentials

Langhammer

Kutzing

Luo

et al. 2011

Biotechnology Progress

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“…20 Meanwhile, on the basis of recent advances in computer technology, a computational discretization approach to solve nonlinear differential equations has been introduced into the numerical modeling of various biological phenomena in the fi eld of applied mathematics. 22,23 This approach has paved the way to quantify various types of pharmacokinetic modeling that were unsolvable by the previous formulative approach.…”

Section: Introductionmentioning

confidence: 99%

Functional computed tomography imaging of tumor-induced angiogenesis: preliminary results of new tracer kinetic modeling using a computer discretization approach

et al. 2008

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Electromyography (EMG) Modeling

Dimitrova

Dimitrov

2006

Wiley Encyclopedia of Biomedical Engineering

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Modeling is a measure of our understanding of processes and a tool for checking hypotheses and making prognoses. Any attempt to understand and explain electromyographic (EMG) signals, their characteristics, and changes is related to modeling. The authors’ aim is to present the main ideas of EMG modeling in terms understandable to people without special mathematical education. The main physical regularities that rule the formation of electrical potentials in a volume conductor (extracellular medium) are pictorially demonstrated and can be realized ignoring equations. Potentials produced by individual muscle fibers are the basis of EMG signals, which is why a more detailed picture of the physical basis for modeling single‐fiber potentials (SFPs) generated in a homogeneous volume conductor of infinite extent is presented. It is demonstrated why the shape of SFP changes with distance from the active fibers, why amplitude of EMG signal can be an unreliable characteristic, and why detection of EMG by needle and surface electrodes has different sensitivity to prolonged phase of repolarization or to after‐depolarization in intracellular action potential (IAP) and to IAP propagation velocity along the fiber. Description of some equations resulting in fast calculation of the motor unit potentials and interference EMG are presented. The latest papers on mathematical modeling that take into account inhomogeneous and restricted muscle tissue are discussed.

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Novel Ideas for Fast Muscle Action Potential Simulations Using the Line Source Model

Cited by 9 publications

References 25 publications

Skeletal myotube integration with planar microelectrode arrays in vitro for spatially selective recording and stimulation: A comparison of neuronal and myotube extracellular action potentials

Skeletal myotube integration with planar microelectrode arrays in vitro for spatially selective recording and stimulation: A comparison of neuronal and myotube extracellular action potentials

Functional computed tomography imaging of tumor-induced angiogenesis: preliminary results of new tracer kinetic modeling using a computer discretization approach

Electromyography (EMG) Modeling

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