Fluorophores are chemical compounds or molecules that absorb light energy at one wavelength and re-emit it as light at a longer, lower-energy wavelength, acting as glowing tags or markers. The absorption process is known as excitation, and the re-emission is visible as fluorescent light, which makes these molecules crucial for biological imaging, diagnostics, and tracing cellular molecules like proteins or lipids under normal or various infectious conditions.
Fluorophores with red-light absorption properties are ideal for bioimaging. Red light refers to wavelengths above 600 nm, and in this range, the natural absorption capacity of chromophores inside our body, like DNA and proteins, is reduced. Therefore, fluorescent probes with absorption bands in this region are specifically excited. Recently, fluorophores featuring a single benzene ring as the core structure, known as single benzene-based fluorophores (SBBFs), have attracted increasing attention due to their small molecular size and excellent biocompatibility. However, no SBBF with absorption wavelengths above 600 nm has been reported to date.
To address this challenge, a team of scientists led by Professor Tetsuhiro Nemoto from the Graduate School of Pharmaceutical Sciences, Chiba University, Japan, has developed a new class of single benzene-based fluorophores, bis-pseudoindoxyls. The team comprised Tomohiro Yazawa and Akiko Takaya from the Graduate School of Pharmaceutical Sciences, Chiba University, and Masaya Nakajima from the Graduate School of Pharmaceutical Sciences, the University of Tokyo, Japan. Their research findings were made available online on November 10, 2025, and were published in Volume 27, Issue 46 of the journal Organic Letters on November 21, 2025.
A pseudoindoxyl scaffold is a unique bicyclic chemical structure with a five-membered nitrogen-containing ring fused to a six-membered benzene ring at its core. It is found in complex natural products that exhibit distinctive light absorption and emission properties. "Based on this understanding, our collaborators and our team conducted computational predictions of the photophysical properties of various pseudoindoxyl derivatives and explored new synthetic approaches to this framework," explains Dr. Nemoto. Based on this, the core scaffold of the molecule, 14CO25NH, was developed. This was further modified chemically to develop 14CO25Nallyl. Among all the synthesized dyes, this molecule was the most suitable for bioimaging due to its properties.
To test its suitability for bioimaging, the researchers conducted live cell imaging using 14CO25Nallyl as a red-light-excitable fluorescent dye. It was used for successful visualization of lipid droplet formation inside live cells during Salmonella infection. The dye showed low cytotoxicity and sufficient aqueous solubility, properties that make it suitable for live-cell bioimaging.
The dye exhibits some unique properties. "This fluorophore itself exhibits a blue color. It is also expected to find applications as a pigment material. In addition, compared with known molecules that possess comparable red-light absorption properties, it features a smaller molecular size and superior cell membrane permeability," says Prof. Nemoto. Red light in the visible region offers deeper tissue penetration and lower phototoxicity than shorter-wavelength light.
Due to its advantageous properties, this dye holds promise for applications in red-light-based bioimaging studies and as a functional coloring agent. Talking about the implications of the study, Dr. Nemoto mentions, "This study has laid the groundwork for creating new dye molecules that remain compact in size while still being able to absorb and emit long-wavelength light. By using this dye framework, we expect to open up new possibilities for developing medical technologies, including near-infrared light-based diagnostics and photodynamic therapy."
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