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Las Vegas, NV 4-Dec-10

Las Vegas, NV 4-Dec-10. The Benefits of Tight Contact Spacing: Computational Model on Avoiding Stimulation Gaps. Emarit Ranu MSEE MSBS, Ewan Gillespie MBA, Kerry Bradley MS Boston Scientific Neuromodulation Valencia, CA USA. Activating Function: Contact Distance. (mV/cm 2 ).

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Las Vegas, NV 4-Dec-10

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  1. Las Vegas, NV4-Dec-10 The Benefits of Tight Contact Spacing: Computational Model on Avoiding Stimulation Gaps Emarit Ranu MSEE MSBS, Ewan Gillespie MBA, Kerry Bradley MS Boston Scientific NeuromodulationValencia, CAUSA

  2. Activating Function: Contact Distance (mV/cm2) • Maps the change in potential on the nerve. • A function of position relative to electrode. • Shows the level depolarization and hyperpolarization. • Any depolarization above threshold causes neurons to fire. Modeling: E. Ranu. Modeling based on: Rattay, F, “Analysis of models for extracellular fiber stimulation,” IEEE Trans Biomed Eng., Jul;36(7):676-82, 1989.

  3. Activating Function: Contact Distance (mV/cm2) • Maps the change in potential on the nerve. • A function of position relative to electrode. • Shows the level depolarization and hyperpolarization. • Any depolarization above threshold causes neurons to fire. Modeling: E. Ranu. Modeling based on: Rattay, F, “Analysis of models for extracellular fiber stimulation,” IEEE Trans Biomed Eng., Jul;36(7):676-82, 1989.

  4. Activating Function: Contact Distance (mV/cm2) • Maps the change in potential on the nerve. • A function of position relative to electrode. • Shows the level depolarization and hyperpolarization. • Any depolarization above threshold causes neurons to fire. Modeling: E. Ranu. Modeling based on: Rattay, F, “Analysis of models for extracellular fiber stimulation,” IEEE Trans Biomed Eng., Jul;36(7):676-82, 1989.

  5. Activating Function: Contact Distance (mV/cm2) • Maps the change in potential on the nerve. • A function of position relative to electrode. • Shows the level depolarization and hyperpolarization. • Any depolarization above threshold causes neurons to fire. Modeling: E. Ranu. Modeling based on: Rattay, F, “Analysis of models for extracellular fiber stimulation,” IEEE Trans Biomed Eng., Jul;36(7):676-82, 1989.

  6. Activating Function: Contact Distance (mV/cm2) • Maps the change in potential on the nerve. • A function of position relative to electrode. • Shows the level depolarization and hyperpolarization. • Any depolarization above threshold causes neurons to fire. Modeling: E. Ranu. Modeling based on: Rattay, F, “Analysis of models for extracellular fiber stimulation,” IEEE Trans Biomed Eng., Jul;36(7):676-82, 1989.

  7. Tight Contact Spacing: Rolling Cathodes Modeling: E. Ranu. Modeling based on: Rattay, F, “Analysis of models for extracellular fiber stimulation,” IEEE Trans Biomed Eng., Jul;36(7):676-82, 1989.

  8. Wide Contact Spacing: Rolling Cathodes Modeling: E. Ranu. Modeling based on: Rattay, F, “Analysis of models for extracellular fiber stimulation,” IEEE Trans Biomed Eng., Jul;36(7):676-82, 1989.

  9. The Benefits of Tight Contact Spacing WideDiscontinuities TightContinuous Modeling: E. Ranu. Modeling based on: Rattay, F, “Analysis of models for extracellular fiber stimulation,” IEEE Trans Biomed Eng., Jul;36(7):676-82, 1989.

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