A modular system of techniques and software has been developed for the calibration and correction of intensity linearity, uniformity of response, spatial distortion, and image plate decay. With calibration the Molecular Dynamics TM Imaging Plate scanner system has been shown to give comparable results to the MarResearchTM scanner. The ESRF x-ray image intensifier/charge-coupled device detectors inherently cause large spatial and uniformity of response distortions, and successful data analysis depends on calibration and correction. Results of synchrotron radiation experiments are presented.
A Monte Carlo model has been developed to simulate light transport and absorption in neural tissue during infrared neural stimulation (INS). A range of fiber core sizes and numerical apertures are compared illustrating the advantages of using simulations when designing a light delivery system. A range of wavelengths, commonly used for INS, are also compared for stimulation of nerves in the cochlea, in terms of both the energy absorbed and the change in temperature due to a laser pulse. Modeling suggests that a fiber with core diameter of 200 μm and NA=0.22 is optimal for optical stimulation in the geometry used and that temperature rises in the spiral ganglion neurons are as low as 0.1°C. The results show a need for more careful experimentation to allow different proposed mechanisms of INS to be distinguished.
Our capacity to interface with the nervous system remains overwhelmingly reliant on electrical stimulation
devices, such as electrode arrays and cuff electrodes that can stimulate both central and peripheral nervous systems.
However, electrical stimulation has to deal with multiple challenges, including selectivity, spatial resolution, mechanical
stability, implant-induced injury and the subsequent inflammatory response. Optical stimulation techniques may avoid
some of these challenges by providing more selective stimulation, higher spatial resolution and reduced invasiveness of
the device, while also avoiding the electrical artefacts that complicate recordings of electrically stimulated neuronal
activity. This review explores the current status of optical stimulation techniques, including optogenetic methods,
photoactive molecule approaches and infrared neural stimulation, together with emerging techniques such as hybrid
optical-electrical stimulation, nanoparticle enhanced stimulation and optoelectric methods. Infrared neural stimulation is
particularly emphasised, due to the potential for direct activation of neural tissue by infrared light, as opposed to
techniques that rely on the introduction of exogenous light responsive materials. However, infrared neural stimulation
remains imperfectly understood, and techniques for accurately delivering light are still under development. While the
various techniques reviewed here confirm the overall feasibility of optical stimulation, a number of challenges remain to
be overcome before they can deliver their full potential.
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