Optical techniques in optogenetics

Mohanty, Samarendra; Lakshminarayanan, Vasudevan

doi:10.1080/09500340.2015.1010620

Cited by 61 publications

(50 citation statements)

References 119 publications

(127 reference statements)

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“…The optogenetic activation method is very promising because it requires only a low intensity of light, which can be delivered by a light-emitting diode or laser [7][8][9][10] . In addition, optogenetic approaches offer several advantages over electrical stimulation, such as cellular specificity, high temporal and spatial resolution, and minimal invasiveness [7][8][11][12][13][14] . However, the clinical translation of optogenetic activation for vision restoration suffers from the lack of a method for the delivery of opsinencoding genes into spatially targeted regions of a retina that has degenerated (e.g., the periphery of the retina in retinitis pigmentosa (RP) or the macula in age-related macular degeneration (AMD).…”

Section: Introductionmentioning

confidence: 99%

Optical delivery of multiple opsin-encoding genes leads to targeted expression and white-light activation

et al. 2015

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In photodegenerative diseases such as retinitis pigmentosa (RP) and age-related macular degeneration (AMD), progressive loss of vision occurs as a result of degeneration of the periphery of the retina and the macula, respectively. Current optogenetic stimulation-based approaches to vision restoration offer the advantages of cellular specificity, high resolution, and minimal invasiveness over electrode arrays; however, the clinical translation of optogenetic activation suffers from the lack of a method for the delivery of opsins into spatially targeted regions of a retina that has degenerated. Non-targeted opsin delivery through viral or non-viral methods to non-photodegenerated retinal areas will perturb these already functioning retinal regions. Furthermore, viral methods are subject to limitations on the delivery of large plasmids, such as fusion constructs of multiple spectrally separated opsins (e.g., channelrhodopsin-2 (ChR2), chimeric opsin variants (C1V1), ReaChR), which can provide higher photo-excitability than can a single narrow-band opsin under ambient light conditions. Here, we report the ultrafast near-infrared laser-based spatially targeted transfection of single and multiple opsins and present a comparison with the opsin expression distribution achieved using another non-viral, but non-targeted, transfection method, lipofection. Functional evaluation of cells transfected with multiple opsins using the laser method revealed a significantly higher white-light-induced photocurrent than in cells expressing a single opsin (ChR2). The laser-assisted targeted delivery of multiple opsin-encoding genes to the peripheral retina/macula is ideal for sensitizing retinal areas that have degenerated, thus paving the way toward the restoration of lost vision in RP/AMD patients.

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Section: Introductionmentioning

confidence: 99%

Optical delivery of multiple opsin-encoding genes leads to targeted expression and white-light activation

et al. 2015

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“…Although beneficial for research, these methods are not viable translational strategies for human treatment. Moreover, these methods possess limitations such as not being able to specifically target cells, posing a risk to cellular components or the foreign DNA, and association with axonal pathology (Bryson et al, 2016;Mohanty & Lakshminarayananan, 2015). Due to the lack in cell specific targeting and the lack of lateralization to humans of non-viral methods, it seems viral delivery methods provide the most sensible means of creating an optogenetic treatment, especially when studied in non-human primate models.…”

Section: Current Delivery Strategies and Therapeutic Obstaclesmentioning

confidence: 99%

“…Non-viral delivery methods of expressing ChR2 in cells include in utero electroporation, transgenic models, chemical lipofection, and laser-assisted cellular poration (Boyden et al, 2005;Carter & de Lecea, 2011;Mohanty & Lakshminarayananan, 2015). Although beneficial for research, these methods are not viable translational strategies for human treatment.…”

Section: Current Delivery Strategies and Therapeutic Obstaclesmentioning

confidence: 99%

“…Ultimately, furthering this therapeutic tool is limited by the knowledge present for specific symptoms as well as their mechanisms (Bryson et al, 2016;Jazayeri & Remington, 2016;Mohanty & Lakshminarayananan, 2015;Mudiayi et al, 2015). Just as optogenetics may be used as a therapeutic tool, it can be utilized to understand these symptoms as it is currently used as an investigative tool (Carter & de Lecea, 2011;Mohanty & Lakshminarayananan, 2015;Mudiayi et al, 2015).…”

Section: Future Directions and Conclusionmentioning

confidence: 99%

“…Just as optogenetics may be used as a therapeutic tool, it can be utilized to understand these symptoms as it is currently used as an investigative tool (Carter & de Lecea, 2011;Mohanty & Lakshminarayananan, 2015;Mudiayi et al, 2015). A first step to identifying how photostimulation can lead to therapeutic effects could ultimately be using optogenetics to understand individual symptoms by experimenting with its circuitry and inhibiting or activating symptom pathways.…”

Section: Future Directions and Conclusionmentioning

confidence: 99%

See 2 more Smart Citations

Therapeutic Potential of Optogenetic Treatment for Individuals with Multiple Sclerosis

Koussy¹,

Jadavji²

2017

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Tailoring Organic LEDs for Bidirectional Optogenetic Control via Dual‐Color Switching

Ciccone

Meloni

Lahore

et al. 2021

Adv Funct Materials

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Revealing the intricate logic of neuronal circuits and its connection to the physiopathology of living systems constitutes a fundamental question in neuroscience. Optogenetics offers the possibility to use light of specific wavelengths to study the activity of neurons with unprecedented spatiotemporal resolution. To make use of this technique at its full potential, bidirectional proteins may be expressed across the neuronal membrane to provoke both enhancement and inhibition of neuronal activity depending on the excitation wavelength. This generates the demand for light sources with high spatial precision, high operation speed, and multi‐color emission from the same location. To meet these requirements, the design, realization, and characterization of organic light‐emitting diodes (OLEDs) are presented with switchable bicolor emission, exhibiting high irradiance and good efficiency. The OLEDs can switch between blue and red/green light upon changing the voltage polarity, triggering both optogenetic inhibition and excitation in ND7/23 cells and Drosophila melanogaster larvae expressing bidirectional optogenetic proteins. This work shows the potential of engineering OLEDs to enable multicolor optogenetics with a single, organic device, and provides a new avenue towards bicolor optical brain stimulation in vivo.

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Optical techniques in optogenetics

Cited by 61 publications

References 119 publications

Optical delivery of multiple opsin-encoding genes leads to targeted expression and white-light activation

Optical delivery of multiple opsin-encoding genes leads to targeted expression and white-light activation

Therapeutic Potential of Optogenetic Treatment for Individuals with Multiple Sclerosis

Tailoring Organic LEDs for Bidirectional Optogenetic Control via Dual‐Color Switching

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