In 68 of the 595 stimulation series (eight sites in eight animals), single-whisker movement was observed at threshold light intensity (Fig. 7D, left) and, in other cases, more than two whisker movements were evoked. Stimulation with a higher light intensity evoked movements of multiple selleck chemicals llc whiskers (Fig. 7D, center and right). Previous electrical microstimulation experiments showed that threshold current intensity and number of deflected whiskers were variable (Brecht et al., 2004). We observed similar results in this ChR2-assisted photostimulation. We stimulated various points in the endoscopic field of view (190 μm diameter). However,

no significant difference was observed in stimulation-evoked whisker movement (data not shown). This result indicates that spatial specificity of stimulation is at least as good as that of electrical microstimulation, and also indicates that the endoscope-based photostimulation can activate minimum unit beta-catenin cancer of motor behavior. In this paper we have described a new optical/electrical probe for controlling neural activity with high spatio-temporal resolution. By using a high-density optical fiber bundle combined with galvano-mirror-based scanning method, we demonstrated that multiple neurons in the endoscopic field of view could be activated independently. In vitro and in vivo experiments suggested that the spatial resolution of photostimulation is comparable to the soma size of cortical neurons in the XY plane (Figs 5 and

S3). In addition to better spatial resolution control of neural activity, another advantage of our method is that the activation of a neuron can be verified in real-time by observing action potential generation using the electrodes bundled with the probe (Figs 4–6). This means that one can stimulate neurons with minimal light intensity for target cell activation. Therefore, the combination of optical stimulation and electrical activity monitoring helps to maximize spatial resolution of stimulation and to prevent undesirable side-effects of stimulation. Several methods

for delivering stimulating light to small brain regions have been reported. A metal-coated, sharpened optical fiber Thiamet G was used for both light stimulation and electrical recording (Zhang et al., 2009). Another type of combined probe is based on a dual-core optical fiber – an optical core for delivering stimulating light and an electrolyte-filled hollow core for electrophysiological recording (LeChasseur et al., 2011). The optical apertures in these probes are so small (1–10 μm) that stimulation area is comparable to neuron diameter (Zhang et al., 2009; LeChasseur et al., 2011). Because these probes have only one stimulation and recording site, multiple probes should be arrayed for multi-site stimulation and recording. However, the density of arrayed probes is in general far lower than inter-neuron distance in brain tissue. For example, electrode pitch of ‘Utah’ multiple electrode array is 400 μm (Zhang et al., 2009).