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. 2020 Mar 27;9:e54937. doi: 10.7554/eLife.54937

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© 2020, Antinucci et al

This article is distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use and redistribution provided that the original author and source are credited.

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Figure 5. — (A) Example membrane depolarisations induced by 5 ms light pulses (20 mW/mm²). (B) Number of optogenetically-evoked spikes vs. pulse duration (across irradiance levels 1–30 mW/mm²). Longer pulse duration induced more spikes in both CoChR- and ChrimsonR-expressing cells. Left plots show single neurons and right plot shows mean ± SEM across cells. (C) Example voltage responses from CoChR- and ChrimsonR-expressing cells upon pulse train stimulation (1–100 Hz, 2–5 ms pulse duration). (D) Number of spikes vs. pulse number within a train (mean ± SEM, across cells; shaded area depicts average number of spikes is below 1). In CoChR-expressing cells, the initial 3–4 pulses within the train induced bursts of 2–4 spikes. (E) Heatmap of mean spike number elicited via CoChR stimulation, separated according to stimulation frequency and pulse duration. Primary motor neurons often responded with bursts of action potentials, even for short light pulses. (F) Example responses to the 1^st (top) and last (bottom) 0.5 ms light pulse in a train, recorded from a CoChR-positive neuron. (G) Spike latency vs. pulse frequency (mean ± SEM). (H) Spike jitter (mean ± SEM) vs. pulse frequency shows that ChrimsonR-expressing cells exhibited lower spike jitter than CoChR-expressing cells. See also Figure 5—figure supplement 1.

Figure 5—source data 1. Data related to Figure 5.
Data provided as a XLSX file.

elife-54937-fig5-data1.xlsx^{(27.5KB, xlsx)}

Figure 5—figure supplement 1. — (A) Example membrane depolarisations induced by 5 ms light pulses (20 mW/mm²). (B) Number of optogenetically-evoked spikes vs. pulse duration (across irradiance levels 1–30 mW/mm²). Longer pulse duration induced more spikes in both CoChR- and ChrimsonR-expressing cells. Left plots show single neurons and right plot shows mean ± SEM across cells. (C) Example voltage responses from CoChR- and ChrimsonR-expressing cells upon pulse train stimulation (1–100 Hz, 2–5 ms pulse duration). (D) Number of spikes vs. pulse number within a train (mean ± SEM, across cells; shaded area depicts average number of spikes is below 1). In CoChR-expressing cells, the initial 3–4 pulses within the train induced bursts of 2–4 spikes. (E) Heatmap of mean spike number elicited via CoChR stimulation, separated according to stimulation frequency and pulse duration. Primary motor neurons often responded with bursts of action potentials, even for short light pulses. (F) Example responses to the 1^st (top) and last (bottom) 0.5 ms light pulse in a train, recorded from a CoChR-positive neuron. (G) Spike latency vs. pulse frequency (mean ± SEM). (H) Spike jitter (mean ± SEM) vs. pulse frequency shows that ChrimsonR-expressing cells exhibited lower spike jitter than CoChR-expressing cells. See also Figure 5—figure supplement 1.

Figure 5—source data 1. Data related to Figure 5.
Data provided as a XLSX file.

elife-54937-fig5-data1.xlsx^{(27.5KB, xlsx)}