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Posts Tagged ‘neural stimulation

Control of traveling waves in the Mammalian cortex.

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January, 2005

Source URL:  https://www.ncbi.nlm.nih.gov/pubmed/15698234?

Control of traveling waves in the Mammalian cortex.

Richardson KA1, Schiff SJ, Gluckman BJ.
Author information
Krasnow Institute for Advanced Study
George Mason University
Fairfax, Virginia 22030, USA.

Abstract

We experimentally confirmed predictions that modulation of the neuronal threshold with electrical fields can speed up, slow down, and even block traveling waves in neocortical slices. The predictions are based on a Wilson-Cowan-type integro-differential equation model of propagating neocortical activity. Wave propagation could be modified quickly and reversibly within targeted regions of the network. To the best of our knowledge, this is the first example of direct modulation of the threshold to control wave propagation in a neural system.

We therefore predicted that we could speed up, slow down, and block propagating neural activity in neocortical slices with the application of electric fields. Furthermore, we predicted that we could affect wave propagation either globally, over the whole slice, or locally, in a specific region of the slice, by changing the geometry of the applied field.

We experimentally confirmed theoretical predictions that threshold modulation can increase or decrease the propagation speed of, and even block, cortical traveling waves. To the best of our knowledge, this is the first example of direct modulation of threshold to control wave propagation in a neural system. Such modulation could be applied rapidly in a locally precise manner. Since neural systems permit direct access to threshold, these findings open avenues to novel neural prosthetic applications including control and containment of seizure propagation.

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Neural stimulation with optical radiation

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Neural stimulation with optical radiation.

Laser Photon Rev. Author manuscript; available in PMC 2012 October 16.

Claus-Peter Richter,1,3,* Agnella Izzo Matic,1,2 Jonathon D. Wells,4 E. Duco Jansen,5 and Joseph T. Walsh, Jr.2

Published in final edited form as:
Laser Photon Rev. 2011 January 1; 5(1): 68–80.
Published online 2010 June 7. doi: 10.1002/lpor.200900044
PMCID: PMC3472451
NIHMSID: NIHMS404629

Introduction
Pulsed mid-infrared lasers have been suggested as a method for neural stimulation [13]. The use of lasers has several appealing features when compared to electrical stimulation: no direct contact is necessary between the stimulating source and the tissue, fine spatial resolution of stimulation can be achieved, no stimulation artifact is generated to deter simultaneous recording of electrical responses from the neurons, and there is no electrochemical junction between the stimulation source and the tissue. Furthermore, at many of the radiation wavelengths used for infrared neural stimulation (INS), the radiation can be easily coupled to an optical fiber. Limitations of INS relate to the laser–tissue interaction. Irradiation of tissue with infrared wavelengths will result in a transient temperature increase, which can cause thermal tissue damage. Although it was possible to stimulate auditory neurons through thin bony structures in the cochlea, thick absorbing or scattering layers above the target structure may prevent neural stimulation.
2. Optical stimulation of neurons
…Neural stimulation may also occur via a photochemical reaction, which is initiated by the absorption of the radiation energy…
Photochemical neural activation can also involve the addition of a “caged” molecule that is released upon irradiation. Caged molecules are molecules that were rendered inert by chemically modifying the structure of a bioactive molecule. Irradiation transforms and/or cleaves the caged molecule to restore the biological activity, which is commonly referred to as “photorelease” or “uncaging” [22]. The resulting active molecules can be agonists or antagonists. Thus, photolysis of caged compounds is a method for using light to switch biological processes on or off…
…The authors suggested that the primary mechanism of stimulation was a thermal effect from the laser. Furthermore, they demonstrated that all of the laser-stimulated neurons were sensitive to capsaicin, which binds to a temperature-sensitive ion channel…
3. Neural stimulation with a pulsed infrared laser
3.1. Stimulation of peripheral nerves
…The upper limit for the repetition rate that ensures nondamaging laser stimulation in peripheral nerves occurred near 5 Hz. The maximum duration for constant low repetition rate stimulation (2 Hz) was approximately 4 min with adequate tissue hydration [50]. Note, these results differ from the findings for the auditory nerve (see below for details)..
3.2. Stimulation of Cranial nerves
3.3. Stimulation of the central auditory system in vivo

Lee et al. [68] have demonstrated that neurons of the central auditory system can be stimulated via INS.

4. Possible mechanisms for optical stimulation of neurons

Although some regimes of optical stimulation occur via photochemical interaction (see earlier sections), it is unlikely that pulsed, mid-infrared lasers, such as the FEL, Ho:YAG, or Aculight diode lasers, evoke neural responses via a photochemical reaction. The individual photon energies emitted by these lasers are significantly lower than the energies required to move an electron to an excited state, as is needed for a photochemical reaction.

 

Read More at:  http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3472451/