Previous work has shown that multiple plasmids can be introduced into the same cells by in utero electroporation (Saito & Nakatsuji, 2001; Mizuno et al., 2007). First, we confirmed that roughly 50% of layer 2/3 projection neurons were labeled with EGFP (Fig. 2E and F), we then evaluated the co-expression rate of ChR2 and fluorescent marker protein. For this purpose, we employed a red fluorescent protein tdTomato instead of EGFP, for separating the fluorescent signal of marker protein
from ChR2-EYFP fluorescence. Although ChR2-EYFP fluorescence was detectable in almost all tdTomato-labeled neurons, only about 20% of tdTomato-labeled neurons strongly express ChR2-EYFP (Fig. 2H). This indicates that expression efficiency of ChR2-EYFP was much lower than that of EGFP or tdTomato. Hence, we used EGFP fluorescence as a marker for the ChR2-expressing learn more region, not for individual ChR2-expressing cells. With the optical/electrical probe inserted into the cerebral cortex of the anesthetized mouse in which the EGFP and ChR2-EYFP gene were transfected
into layer 2/3 cortical projection neurons, EGFP-labeled neurons were clearly visualized (Fig. 2G). This layer-restricted expression pattern of ChR2 by in utero electroporation (Fig. 2F and H) is suited for restricting the region of photoactivation by our optical fiber bundle-based BTK inhibitor nmr photostimulation method, because the axial intensity distribution of stimulating light is less localized compared with radial
distribution (Fig. 2D). We first recorded spontaneous neural activity of cortical neurons with the probe. Spontaneous activity was detected by multiple electrodes in the probe (Fig. 3). In most cases, each electrode detected multiple unit activities (Fig. 3), this is probably because we used low-impedance electrodes (∼300–800 kΩ at 1 kHz) to monitor activity over a large area. This result indicates that considerable numbers of neurons surrounding the probe are viable and excitable. http://www.selleck.co.jp/products/Paclitaxel(Taxol).html We then stimulated ChR2-EGFP co-expressing cortical pyramidal neurons in the anesthetized mouse with blue light (473 nm) through the probe. As shown in Fig. 4A, stimulating light was raster-scanned in rectangular areas in the endoscopic field of view. Light-evoked neural activities were recorded with the electrodes bundled with the probe (Fig. 4B). Photostimulation through the probe sometimes evoked both spiking and non-spiking activities. Therefore, in this case, neural waveforms were high-pass filtered to extract action potential-like activity (Fig. 4C). Typical waveforms of light-evoked activity are shown in Fig. 4B. When the site A was stimulated, light-evoked spiking activity was detected at only electrode 1. On the other hand, activity was detected at electrode 2 when stimulating site B (Fig. 4B). No activity was detected with the other eight electrodes in the probe when stimulating either site A or B (data not shown).