Photon Upconversion Hydrogels for 3D Optogenetics

Meir, Rinat; Hirschhorn, Tal; Kim, Sung‐Soo; Fallon, Kealan J.; Churchill, Emily M.; Wu, Dino; Yang, Hee Won; Stockwell, Brent R.; Campos, Luis M.

doi:10.1002/adfm.202010907

Cited by 20 publications

(18 citation statements)

References 50 publications

(71 reference statements)

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“…Unconventional strategies for expanding the use of solar energy have attracted significant attention in recent years. , Using photon upconversion (UC), in which low-energy photons are combined to form high-energy light, it is expected that the conventional limits in photovoltaics can be shifted upward . This process has also been utilized in contexts of, for example, optogenetics, , targeted drug-delivery, photocatalysis, and photochemistry. , …”

Section: Introductionmentioning

confidence: 99%

Approaching the Spin-Statistical Limit in Visible-to-Ultraviolet Photon Upconversion

et al. 2022

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Triplet–triplet annihilation photon upconversion (TTA-UC) is a process in which triplet excitons combine to form emissive singlets and holds great promise in biological applications and for improving the spectral match in solar energy conversion. While high TTA-UC quantum yields have been reported for, for example, red-to-green TTA-UC systems, there are only a few examples of visible-to-ultraviolet (UV) transformations in which the quantum yield reaches 10%. In this study, we investigate the performance of six annihilators when paired with the sensitizer 2,3,5,6-tetra(9 H -carbazol-9-yl)benzonitrile (4CzBN), a purely organic compound that exhibits thermally activated delayed fluorescence. We report a record-setting internal TTA-UC quantum yield (Φ UC,g ) of 16.8% (out of a 50% maximum) for 1,4-bis((triisopropylsilyl)ethynyl)naphthalene, demonstrating the first example of a visible-to-UV TTA-UC system approaching the classical spin-statistical limit of 20%. Three other annihilators, of which 2,5-diphenylfuran has never been used for TTA-UC previously, also showed impressive performances with Φ UC,g above 12%. In addition, a new method to determine the rate constant of TTA is proposed, in which only time-resolved emission measurements are needed, circumventing the need for more challenging transient absorption measurements. The results reported herein represent an important step toward highly efficient visible-to-UV TTA-UC systems that hold great potential for driving high-energy photochemical reactions.

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Section: Introductionmentioning

confidence: 99%

Approaching the Spin-Statistical Limit in Visible-to-Ultraviolet Photon Upconversion

et al. 2022

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“…For example, new inorganic UPNC have been characterized and the conditions for their optimal use have been studied (Krajnik et al, 2020;Skripka et al, 2020). Organic UPNC have been formed into hydrogels, which has been utilized in a 3D cell model and in vitro hippocampal neurons to activate blue light optogenetic systems (Sasaki et al, 2019;Meir et al, 2021).…”

Section: Illuminationmentioning

confidence: 99%

Red Light Optogenetics in Neuroscience

Lehtinen

Nokia

Takala

2022

Front. Cell. Neurosci.

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Optogenetics, a field concentrating on controlling cellular functions by means of light-activated proteins, has shown tremendous potential in neuroscience. It possesses superior spatiotemporal resolution compared to the surgical, electrical, and pharmacological methods traditionally used in studying brain function. A multitude of optogenetic tools for neuroscience have been created that, for example, enable the control of action potential generation via light-activated ion channels. Other optogenetic proteins have been used in the brain, for example, to control long-term potentiation or to ablate specific subtypes of neurons. In in vivo applications, however, the majority of optogenetic tools are operated with blue, green, or yellow light, which all have limited penetration in biological tissues compared to red light and especially infrared light. This difference is significant, especially considering the size of the rodent brain, a major research model in neuroscience. Our review will focus on the utilization of red light-operated optogenetic tools in neuroscience. We first outline the advantages of red light for in vivo studies. Then we provide a brief overview of the red light-activated optogenetic proteins and systems with a focus on new developments in the field. Finally, we will highlight different tools and applications, which further facilitate the use of red light optogenetics in neuroscience.

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“… 6 Because of these benefits, there is an increasing trend for developing NIR-sensitive nanoparticles, devices, and systems that operate in the tissue transparency window to control neural activity. 7 − 11 …”

Section: Introductionmentioning

confidence: 99%

“…For example, upconversion nanoparticles (NPs) recently rendered NIR sensitivity to optogenetic systems operating in the visible spectrum, and overcame the light penetration limitation of visible light and implantation requirement of light-delivery fibers into the tissue . Because of these benefits, there is an increasing trend for developing NIR-sensitive nanoparticles, devices, and systems that operate in the tissue transparency window to control neural activity. − …”

Section: Introductionmentioning

confidence: 99%

Electrical Stimulation of Neurons with Quantum Dots via Near-Infrared Light

et al. 2022

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Photovoltaic biointerfaces offer wireless and battery-free bioelectronic medicine via photomodulation of neurons. Near-infrared (NIR) light enables communication with neurons inside the deep tissue and application of high photon flux within the ocular safety limit of light exposure. For that, nonsilicon biointerfaces are highly demanded for thin and flexible operation. Here, we devised a flexible quantum dot (QD)-based photovoltaic biointerface that stimulates cells within the spectral tissue transparency window by using NIR light (λ = 780 nm). Integration of an ultrathin QD layer of 25 nm into a multilayered photovoltaic architecture enables transduction of NIR light to safe capacitive ionic currents that leads to reproducible action potentials on primary hippocampal neurons with high success rates. The biointerfaces exhibit low in vitro toxicity and robust photoelectrical performance under different stability tests. Our findings show that colloidal quantum dots can be used in wireless bioelectronic medicine for brain, heart, and retina.

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Photon Upconversion Hydrogels for 3D Optogenetics

Cited by 20 publications

References 50 publications

Approaching the Spin-Statistical Limit in Visible-to-Ultraviolet Photon Upconversion

Approaching the Spin-Statistical Limit in Visible-to-Ultraviolet Photon Upconversion

Red Light Optogenetics in Neuroscience

Electrical Stimulation of Neurons with Quantum Dots via Near-Infrared Light

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