High-power pulsed electrochemiluminescence for optogenetic manipulation of Drosophila larval behaviour

Chang-Ki Moon; Matthias König; Ranjini Sircar; Julian F. Butscher; Ronald Alle; Klaus Meerholz; Stefan R. Pulver; Malte C. Gather

doi:10.1038/s41377-025-02143-y

High-power pulsed electrochemiluminescence for optogenetic manipulation of Drosophila larval behaviour

Chang-Ki Moon^*, Matthias König, Ranjini Sircar, Julian F. Butscher, Ronald Alle, Klaus Meerholz, Stefan R. Pulver, Malte C. Gather^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Electrochemiluminescence (ECL) produces light through electrochemical reactions and has shown promise for various analytic applications in biomedicine. However, the use of ECL devices (ECLDs) as light sources has been limited due to insufficient light output and low operational stability. In this study, we present a high-power pulsed operation strategy for ECLDs to address these limitations and demonstrate their effectiveness in optogenetic manipulation. By applying a biphasic voltage sequence with short opposing phases, we achieve intense and efficient ECL through an exciplex-formation reaction pathway. This approach results in an exceptionally high optical power density, exceeding 100 μW mm⁻², for several thousand pulses. Balancing the ion concentration by optimizing the voltage waveform further improves device stability. By incorporating multiple optimized pulses into a pulse train separated by short rest periods, extended light pulses of high brightness and with minimal power loss over time were obtained. These strategies were leveraged to elicit a robust optogenetic response in fruit fly (Drosophila melanogaster) larvae expressing the optogenetic effector CsChrimson. The semi-transparent nature of ECLDs facilitates simultaneous imaging of larval behaviour from underneath, through the device. These findings highlight the potential of ECLDs as versatile optical tools in biomedical and neurophotonics research.

Original language	English
Article number	104
Number of pages	11
Journal	Light: Science & Applications
Volume	15
DOIs	https://doi.org/10.1038/s41377-025-02143-y
Publication status	Published - 5 Feb 2026

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High-power pulsed electrochemiluminescence for optogenetic manipulation of Drosophila larval behaviour (dataset)
Moon, C. (Creator), König, M. (Creator), Sircar, R. (Creator), Butscher, J. (Creator), Alle, R. (Creator), Meerholz, K. (Creator), Pulver, S. (Creator) & Gather, M. (Creator), University of St Andrews, 4 Feb 2026
DOI: 10.17630/4ffc6f6f-7d04-43ed-9ed1-9d1002f0b775
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title = "High-power pulsed electrochemiluminescence for optogenetic manipulation of Drosophila larval behaviour",

abstract = "Electrochemiluminescence (ECL) produces light through electrochemical reactions and has shown promise for various analytic applications in biomedicine. However, the use of ECL devices (ECLDs) as light sources has been limited due to insufficient light output and low operational stability. In this study, we present a high-power pulsed operation strategy for ECLDs to address these limitations and demonstrate their effectiveness in optogenetic manipulation. By applying a biphasic voltage sequence with short opposing phases, we achieve intense and efficient ECL through an exciplex-formation reaction pathway. This approach results in an exceptionally high optical power density, exceeding 100 μW mm−2, for several thousand pulses. Balancing the ion concentration by optimizing the voltage waveform further improves device stability. By incorporating multiple optimized pulses into a pulse train separated by short rest periods, extended light pulses of high brightness and with minimal power loss over time were obtained. These strategies were leveraged to elicit a robust optogenetic response in fruit fly (Drosophila melanogaster) larvae expressing the optogenetic effector CsChrimson. The semi-transparent nature of ECLDs facilitates simultaneous imaging of larval behaviour from underneath, through the device. These findings highlight the potential of ECLDs as versatile optical tools in biomedical and neurophotonics research.",

author = "Chang-Ki Moon and Matthias K{\"o}nig and Ranjini Sircar and Butscher, \{Julian F.\} and Ronald Alle and Klaus Meerholz and Pulver, \{Stefan R.\} and Gather, \{Malte C.\}",

note = "Funding: This work was financially supported by the Alexander von Humboldt Foundation (Humboldt-Professorship to M.C.G.) and the Deutsche Forschungsgemeinschaft (DFG) through the research training group “Template Designed Organic Electronics (TIDE)” (RTG2591). C.-K.M. acknowledges funding from the European Commission through a Marie Sk{\l}odowska Curie individual fellowship (101029807). J.F.B. acknowledges funding from Beverly and Frank MacInnis via the University of St Andrews. R.S. acknowledges funding through the Global PhD programme at the University of St Andrews and the RS Macdonald Trust.",

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doi = "10.1038/s41377-025-02143-y",

language = "English",

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T1 - High-power pulsed electrochemiluminescence for optogenetic manipulation of Drosophila larval behaviour

AU - Moon, Chang-Ki

AU - König, Matthias

AU - Sircar, Ranjini

AU - Butscher, Julian F.

AU - Alle, Ronald

AU - Meerholz, Klaus

AU - Pulver, Stefan R.

AU - Gather, Malte C.

N1 - Funding: This work was financially supported by the Alexander von Humboldt Foundation (Humboldt-Professorship to M.C.G.) and the Deutsche Forschungsgemeinschaft (DFG) through the research training group “Template Designed Organic Electronics (TIDE)” (RTG2591). C.-K.M. acknowledges funding from the European Commission through a Marie Skłodowska Curie individual fellowship (101029807). J.F.B. acknowledges funding from Beverly and Frank MacInnis via the University of St Andrews. R.S. acknowledges funding through the Global PhD programme at the University of St Andrews and the RS Macdonald Trust.

PY - 2026/2/5

Y1 - 2026/2/5

N2 - Electrochemiluminescence (ECL) produces light through electrochemical reactions and has shown promise for various analytic applications in biomedicine. However, the use of ECL devices (ECLDs) as light sources has been limited due to insufficient light output and low operational stability. In this study, we present a high-power pulsed operation strategy for ECLDs to address these limitations and demonstrate their effectiveness in optogenetic manipulation. By applying a biphasic voltage sequence with short opposing phases, we achieve intense and efficient ECL through an exciplex-formation reaction pathway. This approach results in an exceptionally high optical power density, exceeding 100 μW mm−2, for several thousand pulses. Balancing the ion concentration by optimizing the voltage waveform further improves device stability. By incorporating multiple optimized pulses into a pulse train separated by short rest periods, extended light pulses of high brightness and with minimal power loss over time were obtained. These strategies were leveraged to elicit a robust optogenetic response in fruit fly (Drosophila melanogaster) larvae expressing the optogenetic effector CsChrimson. The semi-transparent nature of ECLDs facilitates simultaneous imaging of larval behaviour from underneath, through the device. These findings highlight the potential of ECLDs as versatile optical tools in biomedical and neurophotonics research.

AB - Electrochemiluminescence (ECL) produces light through electrochemical reactions and has shown promise for various analytic applications in biomedicine. However, the use of ECL devices (ECLDs) as light sources has been limited due to insufficient light output and low operational stability. In this study, we present a high-power pulsed operation strategy for ECLDs to address these limitations and demonstrate their effectiveness in optogenetic manipulation. By applying a biphasic voltage sequence with short opposing phases, we achieve intense and efficient ECL through an exciplex-formation reaction pathway. This approach results in an exceptionally high optical power density, exceeding 100 μW mm−2, for several thousand pulses. Balancing the ion concentration by optimizing the voltage waveform further improves device stability. By incorporating multiple optimized pulses into a pulse train separated by short rest periods, extended light pulses of high brightness and with minimal power loss over time were obtained. These strategies were leveraged to elicit a robust optogenetic response in fruit fly (Drosophila melanogaster) larvae expressing the optogenetic effector CsChrimson. The semi-transparent nature of ECLDs facilitates simultaneous imaging of larval behaviour from underneath, through the device. These findings highlight the potential of ECLDs as versatile optical tools in biomedical and neurophotonics research.

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DO - 10.1038/s41377-025-02143-y

M3 - Article

SN - 2047-7538

VL - 15

JO - Light: Science & Applications

JF - Light: Science & Applications

M1 - 104

ER -

High-power pulsed electrochemiluminescence for optogenetic manipulation of Drosophila larval behaviour

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High-power pulsed electrochemiluminescence for optogenetic manipulation of Drosophila larval behaviour (dataset)

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