Hyeonji Rha scite author profile

Pyroptosis refers to the process of gasdermin-mediated lytic programmed cell death (PCD) characterized by the release of pro-inflammatory cytokines. Our knowledge of pyroptosis has expanded beyond the cellular level and now includes extracellular responses. In recent years, pyroptosis has attracted considerable attention due to its potential to induce host immunity. For instance, at the 2022 International Medicinal Chemistry of Natural Active Ligand Metal-Based Drugs (MCNALMD) conference, numerous researchers demonstrated an interest in photon-controlled pyroptosis activation ("PhotoPyro"), an emerging pyroptosis-engineered approach for activating systemic immunity via photoirradiation. Given this enthusiasm, we share in this Perspective our views on this emerging area and expound on how and why "PhotoPyro" could trigger antitumor immunity (i.e., turning so-called "cold" tumors "hot"). In doing so, we have tried to highlight cutting-edge breakthroughs in PhotoPyro while suggesting areas for future contributions. By providing insights into the current state of the art and serving as a resource for individuals interested in working in this area, it is hoped that this Perspective will set the stage for PhotoPyro to evolve into a broadly applicable cancer treatment strategy.

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Mechanical stimuli-driven cancer therapeutics

Hong

Won

et al. 2023

Chem. Soc. Rev.

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Photo-controllable biochemistry: Exploiting the photocages in phototherapeutic window

Xiong

Kim

et al. 2023

Chem

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THQ–Xanthene: An Emerging Strategy to Create Next‐Generation NIR‐I/II Fluorophores

et al. 2023

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Near‐infrared fluorescence imaging is vital for exploring the biological world. The short emissions (<650 nm) and small Stokes shifts (<30 nm) of current xanthene dyes obstruct their biological applications since a long time. Recently, a potent and universal THQ structural modification technique that shifts emission to the NIR‐I/II range and enables a substantial Stokes shift (>100 nm) for THQ‐modified xanthene dyes is established. Thus, a timely discussion of THQ–xanthene and its applications is extensive. Hence, the advent, working principles, development trajectory, and biological applications of THQ–xanthene dyes, especially in the fields of fluorescence probe‐based sensing and imaging, cancer theranostics, and super‐resolution imaging, are introduced. It is envisioned that the THQ modification tactic is a simple yet exceptional approach to upgrade the performance of conventional xanthene dyes. THQ–xanthene will advance the strides of xanthene‐based potentials in early fluorescent diagnosis of diseases, cancer theranostics, and imaging‐guided surgery.

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Structural modification of NIR-II fluorophores for angiography beyond 1300 nm: Expanding the xanthene universe

Zhang

et al. 2022

Biosensors and Bioelectronics

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Hyeonji Rha

Photon-Controlled Pyroptosis Activation (PhotoPyro): An Emerging Trigger for Antitumor Immune Response

Mechanical stimuli-driven cancer therapeutics

Photo-controllable biochemistry: Exploiting the photocages in phototherapeutic window

THQ–Xanthene: An Emerging Strategy to Create Next‐Generation NIR‐I/II Fluorophores

Structural modification of NIR-II fluorophores for angiography beyond 1300 nm: Expanding the xanthene universe

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