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1. Flavylium Polymethine Fluorophores for Near‐ and Shortwave Infrared Imaging

   https://doi.org/10.1002/ange.201706974  

   Cosco, Emily D. ; Caram, Justin R. ; Bruns, Oliver T. ; Franke, Daniel ; Day, Rachael A. ; Farr, Erik P. ; Bawendi, Moungi G. ; Sletten, Ellen M. ( September 2017 , Angewandte Chemie)

   Bright fluorophores in the near‐infrared and shortwave infrared (SWIR) regions of the electromagnetic spectrum are essential for optical imaging in vivo. In this work, we utilized a 7‐dimethylamino flavylium heterocycle to construct a panel of novel red‐shifted polymethine dyes, with emission wavelengths from 680 to 1045 nm. Photophysical characterization revealed that the 1‐ and 3‐methine dyes display enhanced photostability and the 5‐ and 7‐methine dyes exhibit exceptional brightness for their respective spectral regions. A micelle formulation of the 7‐methine facilitated SWIR imaging in mice. This report presents the first polymethine dye designed and synthesized for SWIR in vivo imaging.

    

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2. Photophysical Properties of Indocyanine Green in the Shortwave Infrared Region

   https://doi.org/10.1002/cptc.202100045  

   Cosco, Emily D. ; Lim, Irene ; Sletten, Ellen M. ( May 2021 , ChemPhotoChem)

   With the growing development of new contrast agents for optical imaging using near‐infrared and shortwave infrared (SWIR) wavelengths, it is essential to have consistent benchmarks for emitters in these regions. Indocyanine green (ICG), a ubiquitous and FDA‐approved organic dye and optical imaging agent, is commonly employed as a standard for photophysical properties and biological performance for imaging experiments at these wavelengths. Yet, its reported photophysical properties across organic and aqueous solvents vary greatly in the literature, which hinders its ability to be used as a consistent benchmark. Herein, we measure photophysical properties in organic and aqueous solvents using InGaAs detection (∼950–1,700 nm), providing particular relevance for SWIR imaging.

    

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3. Interlayer Transition in a vdW Heterostructure toward Ultrahigh Detectivity Shortwave Infrared Photodetectors

   https://doi.org/10.1002/adfm.201905687  

   Qi, Tailei ; Gong, Youpin ; Li, Alei ; Ma, Xiaoming ; Wang, Peipei ; Huang, Rui ; Liu, Chang ; Sakidja, Ridwan ; Wu, Judy Z. ; Chen, Rui ; et al ( October 2019 , Advanced Functional Materials)

   Van der Waals (vdW) heterostructures of 2D atomically thin layered materials (2DLMs) provide a unique platform for constructing optoelectronic devices by staking 2D atomic sheets with unprecedented functionality and performance. A particular advantage of these vdW heterostructures is the energy band engineering of 2DLMs to achieve interlayer excitons through type‐II band alignment, enabling spectral range exceeding the cutoff wavelengths of the individual atomic sheets in the 2DLM. Herein, the high performance of GaTe/InSe vdW heterostructures device is reported. Unexpectedly, this GaTe/InSe vdWs p–n junction exhibits extraordinary detectivity in a new shortwave infrared (SWIR) spectrum, which is forbidden by the respective bandgap limits for the constituent GaTe (bandgap of ≈1.70 eV in both the bulk and monolayer) and InSe (bandgap of ≈1.20–1.80 eV depending on thickness reduction from bulk to monolayer). Specifically, the uncooled SWIR detectivity is up to ≈10¹⁴Jones at 1064 nm and ≈10¹²Jones at 1550 nm, respectively. This result indicates that the 2DLM vdW heterostructures with type‐II band alignment produce an interlayer exciton transition, and this advantage can offer a viable strategy for devising high‐performance optoelectronics in SWIR or even longer wavelengths beyond the individual limitations of the bandgaps and heteroepitaxy of the constituent atomic layers.

    

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4. Ultra‐Bright Near‐Infrared Sulfonate‐Indolizine Cyanine‐ and Squaraine‐Albumin Chaperones: Record Quantum Yields and Applications

   https://doi.org/10.1002/cptc.202200127  

   Meador, William E. ; Kapusta, Karina ; Owolabi, Iyanuoluwani ; Autry, Shane A. ; Saloni, Julia ; Kolodziejczyk, Wojciech ; Hammer, Nathan I. ; Flynt, Alex S. ; Hill, Glake A. ; Delcamp, Jared H. ( August 2022 , ChemPhotoChem)

   The design of bright, high quantum yield (QY) materials in the near‐infrared (NIR) spectral region in water remains a significant challenge. A series of cyanine and squaraine dyes varying water solubilizing groups and heterocycles are studied to probe the interactions of these groups with albumin in water. Unprecedented, ′ultra‐bright′ emission in water is observed for a sulfonate indolizine squaraine dye (61.1 % QY) and a sulfonate indolizine cyanine dye (46.7 % QY) at NIR wavelengths of >700 nm and >800 nm, respectively. The dyes presented herein have a lower limit of detection than the most sensitive dyes known in the NIR region for albumin detection by at least an order of magnitude, which enables more sensitive diagnostic testing. Additionally, biotinylated human serum albumin complexed with the dyes reported herein was observed to function as an immunohistochemical reagent enabling high resolution imaging of cellular α‐tubulin at low dye concentrations.

    

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5. Shortwave-infrared (SWIR) emitters for biological imaging: a review of challenges and opportunities

   https://doi.org/10.1515/nanoph-2017-0039  

   Thimsen, Elijah ; Sadtler, Bryce ; Berezin, Mikhail Y. ( January 2017 , Nanophotonics)

   Abstract Shortwave infrared radiation (SWIR) is the portion of the electromagnetic spectrum from approximately 900 nm to 2500 nm. Recent advances in imaging systems have expanded the application of SWIR emitters from traditional fields in materials science to biomedical imaging, and the new detectors in SWIR opened an opportunity of deep tissue imaging. Achieving deep photon penetration while maintaining high resolution is one of the main objectives and challenges in bioimaging used for the investigation of diverse processes in living organisms. The application of SWIR emitters in biological settings is, however, hampered by low quantum efficiency. So far, photoluminescent properties in the SWIR region have not been improved by extending concepts that have been developed for the visible (400–650 nm) and near-infrared (NIR, 700–900 nm) wavelengths, which indicates that the governing behavior is fundamentally different in the SWIR. The focus of this minireview is to examine the mechanisms behind the low efficiency of SWIR emitters as well as to highlight the progress in their design for biological applications. Several common mechanisms will be considered in this review: (a) the effect of the energy gap between the excited and ground state on the quantum efficiency, (b) the coupling of the excited electronic states in SWIR emitters to vibrational states in the surrounding matrix, and (c) the role of environment in quenching the excited states. General strategies to improve the quantum yields for a diverse type of SWIR emitters will be also presented. 

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