Donor and Ring‐Fusing Engineering for Far‐Red to Near‐Infrared Triphenylpyrylium Fluorophores with Enhanced Fluorescence Performance for Sensing and Imaging
Fluorescent probes have become an indispensable tool in the detection and imaging of biological and disease‐related analytes due to their sensitivity and technical simplicity. In particular, fluorescent probes with far‐red to near‐infrared (FR‐NIR) emissions are very attractive for biomedical applic...
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| Published in | Chemistry : a European journal Vol. 25; no. 28; pp. 6973 - 6979 |
|---|---|
| Main Authors | , , , , , , , , |
| Format | Journal Article |
| Language | English |
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WEINHEIM
Wiley
17.05.2019
Wiley Subscription Services, Inc |
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| Abstract | Fluorescent probes have become an indispensable tool in the detection and imaging of biological and disease‐related analytes due to their sensitivity and technical simplicity. In particular, fluorescent probes with far‐red to near‐infrared (FR‐NIR) emissions are very attractive for biomedical applications. However, many available FR‐NIR fluorophores suffer from small Stokes shifts and sometimes low quantum yields, resulting in self‐quenching and low contrast. In this work, we describe the rational design and engineering of FR‐NIR 2,4,6‐triphenylpyrylium‐based fluorophores (TPP‐Fluors) with the help of theoretical calculations. Our strategy is based on the appending of electron‐donating substituents and fusing groups onto 2,4,6‐triphenylpyrylium. In contrast to the parent TPP with short emission wavelength, weak quantum yields, and low chemical stability, the obtained novel TPP‐Fluors display some favorable properties, such as long‐wavelength emission, large Stokes shifts, moderate to high quantum yields, and chemical stability. TPP‐Fluors demonstrate their biological value as mitochondria‐specific labeling reagents due to their inherently positive nature. In addition, TPP‐Fluors can also be applied to develop ratiometric fluorescent probes, as the electron‐donating ability of the 2,6‐phenyl substituents is closely correlated with their emission wavelength. A proof‐of‐concept ratiometric probe has been developed by derivatizing the amino groups of TPP‐Fluor for the detection and imaging of nitroreductase in vitro and in hypoxic cells.
Rigidified and activated probes: Rational modification of the 2,4,6‐triphenylpyrylium salt (TPP) results in fluorophores (TPPF) with far‐red to NIR emissions, large Stokes shifts, and high quantum yields (see figure). In addition, through acylation of the amino groups, TPPF dye can be exploited as a novel platform for designing ratiometric fluorescent probes with highly shifted emission bands. |
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| AbstractList | Fluorescent probes have become an indispensable tool in the detection and imaging of biological and disease‐related analytes due to their sensitivity and technical simplicity. In particular, fluorescent probes with far‐red to near‐infrared (FR‐NIR) emissions are very attractive for biomedical applications. However, many available FR‐NIR fluorophores suffer from small Stokes shifts and sometimes low quantum yields, resulting in self‐quenching and low contrast. In this work, we describe the rational design and engineering of FR‐NIR 2,4,6‐triphenylpyrylium‐based fluorophores (TPP‐Fluors) with the help of theoretical calculations. Our strategy is based on the appending of electron‐donating substituents and fusing groups onto 2,4,6‐triphenylpyrylium. In contrast to the parent TPP with short emission wavelength, weak quantum yields, and low chemical stability, the obtained novel TPP‐Fluors display some favorable properties, such as long‐wavelength emission, large Stokes shifts, moderate to high quantum yields, and chemical stability. TPP‐Fluors demonstrate their biological value as mitochondria‐specific labeling reagents due to their inherently positive nature. In addition, TPP‐Fluors can also be applied to develop ratiometric fluorescent probes, as the electron‐donating ability of the 2,6‐phenyl substituents is closely correlated with their emission wavelength. A proof‐of‐concept ratiometric probe has been developed by derivatizing the amino groups of TPP‐Fluor for the detection and imaging of nitroreductase in vitro and in hypoxic cells.
Rigidified and activated probes: Rational modification of the 2,4,6‐triphenylpyrylium salt (TPP) results in fluorophores (TPPF) with far‐red to NIR emissions, large Stokes shifts, and high quantum yields (see figure). In addition, through acylation of the amino groups, TPPF dye can be exploited as a novel platform for designing ratiometric fluorescent probes with highly shifted emission bands. Fluorescent probes have become an indispensable tool in the detection and imaging of biological and disease‐related analytes due to their sensitivity and technical simplicity. In particular, fluorescent probes with far‐red to near‐infrared (FR‐NIR) emissions are very attractive for biomedical applications. However, many available FR‐NIR fluorophores suffer from small Stokes shifts and sometimes low quantum yields, resulting in self‐quenching and low contrast. In this work, we describe the rational design and engineering of FR‐NIR 2,4,6‐triphenylpyrylium‐based fluorophores (TPP‐Fluors) with the help of theoretical calculations. Our strategy is based on the appending of electron‐donating substituents and fusing groups onto 2,4,6‐triphenylpyrylium. In contrast to the parent TPP with short emission wavelength, weak quantum yields, and low chemical stability, the obtained novel TPP‐Fluors display some favorable properties, such as long‐wavelength emission, large Stokes shifts, moderate to high quantum yields, and chemical stability. TPP‐Fluors demonstrate their biological value as mitochondria‐specific labeling reagents due to their inherently positive nature. In addition, TPP‐Fluors can also be applied to develop ratiometric fluorescent probes, as the electron‐donating ability of the 2,6‐phenyl substituents is closely correlated with their emission wavelength. A proof‐of‐concept ratiometric probe has been developed by derivatizing the amino groups of TPP‐Fluor for the detection and imaging of nitroreductase in vitro and in hypoxic cells. Fluorescent probes have become an indispensable tool in detection and imaging of biological and disease related analytes due to their sensitivity and technical simplicity. In particular, fluorescent probes with far red to near-infrared emission are very attractive for biomedical application. However, many available FR-NIR fluorophores suffer from small Stokes shifts and sometimes low quantum yield, resulting in self-quenching and low contrast. In this work, we described the rational design and engineering of FR-NIR 2,4,6-triphenylpyrylium-based fluorophores (TPP-Fluors) with the help of theoretical calculation. Our strategy is based on incorporation of electron donating substituent and fusing group into 2,4,6-triphenylpyrylium. Different from the original TPP with short emission wavelength, weak quantum yields and low chemical stability, the obtained novel TPP-Fluors display some favorable properties, such as long wavelength, large Stokes shift, moderate to high quantum yields and chemical stability. TPP-Fluors demonstrate their biological values as mitochondria-specific labeling reagent due to the inherent positive nature. In addition, TPP-Fluor also can be applied to develop ratiometric fluorescent probes as the electron donating ability in 2, 6-phenyl has a close correlation with their emission wavelength. A proof-of-concept ratiometric probe was developed by decorating the amino group of TPP-Fluor for detection and imaging of nitroreductase in vitro and hypoxic cells. Fluorescent probes have become an indispensable tool in the detection and imaging of biological and disease-related analytes due to their sensitivity and technical simplicity. In particular, fluorescent probes with far-red to near-infrared (FR-NIR) emissions are very attractive for biomedical applications. However, many available FR-NIR fluorophores suffer from small Stokes shifts and sometimes low quantum yields, resulting in self-quenching and low contrast. In this work, we describe the rational design and engineering of FR-NIR 2,4,6-triphenylpyrylium-based fluorophores (TPP-Fluors) with the help of theoretical calculations. Our strategy is based on the appending of electron-donating substituents and fusing groups onto 2,4,6-triphenylpyrylium. In contrast to the parent TPP with short emission wavelength, weak quantum yields, and low chemical stability, the obtained novel TPP-Fluors display some favorable properties, such as long-wavelength emission, large Stokes shifts, moderate to high quantum yields, and chemical stability. TPP-Fluors demonstrate their biological value as mitochondria-specific labeling reagents due to their inherently positive nature. In addition, TPP-Fluors can also be applied to develop ratiometric fluorescent probes, as the electron-donating ability of the 2,6-phenyl substituents is closely correlated with their emission wavelength. A proof-of-concept ratiometric probe has been developed by derivatizing the amino groups of TPP-Fluor for the detection and imaging of nitroreductase in vitro and in hypoxic cells.Fluorescent probes have become an indispensable tool in the detection and imaging of biological and disease-related analytes due to their sensitivity and technical simplicity. In particular, fluorescent probes with far-red to near-infrared (FR-NIR) emissions are very attractive for biomedical applications. However, many available FR-NIR fluorophores suffer from small Stokes shifts and sometimes low quantum yields, resulting in self-quenching and low contrast. In this work, we describe the rational design and engineering of FR-NIR 2,4,6-triphenylpyrylium-based fluorophores (TPP-Fluors) with the help of theoretical calculations. Our strategy is based on the appending of electron-donating substituents and fusing groups onto 2,4,6-triphenylpyrylium. In contrast to the parent TPP with short emission wavelength, weak quantum yields, and low chemical stability, the obtained novel TPP-Fluors display some favorable properties, such as long-wavelength emission, large Stokes shifts, moderate to high quantum yields, and chemical stability. TPP-Fluors demonstrate their biological value as mitochondria-specific labeling reagents due to their inherently positive nature. In addition, TPP-Fluors can also be applied to develop ratiometric fluorescent probes, as the electron-donating ability of the 2,6-phenyl substituents is closely correlated with their emission wavelength. A proof-of-concept ratiometric probe has been developed by derivatizing the amino groups of TPP-Fluor for the detection and imaging of nitroreductase in vitro and in hypoxic cells. Fluorescent probes have become an indispensable tool in the detection and imaging of biological and disease‐related analytes due to their sensitivity and technical simplicity. In particular, fluorescent probes with far‐red to near‐infrared (FR‐NIR) emissions are very attractive for biomedical applications. However, many available FR‐NIR fluorophores suffer from small Stokes shifts and sometimes low quantum yields, resulting in self‐quenching and low contrast. In this work, we describe the rational design and engineering of FR‐NIR 2,4,6‐triphenylpyrylium‐based fluorophores ( TPP‐Fluors ) with the help of theoretical calculations. Our strategy is based on the appending of electron‐donating substituents and fusing groups onto 2,4,6‐triphenylpyrylium. In contrast to the parent TPP with short emission wavelength, weak quantum yields, and low chemical stability, the obtained novel TPP‐Fluors display some favorable properties, such as long‐wavelength emission, large Stokes shifts, moderate to high quantum yields, and chemical stability. TPP‐Fluors demonstrate their biological value as mitochondria‐specific labeling reagents due to their inherently positive nature. In addition, TPP‐Fluors can also be applied to develop ratiometric fluorescent probes, as the electron‐donating ability of the 2,6‐phenyl substituents is closely correlated with their emission wavelength. A proof‐of‐concept ratiometric probe has been developed by derivatizing the amino groups of TPP‐Fluor for the detection and imaging of nitroreductase in vitro and in hypoxic cells. |
| Author | Zhang, Qian‐Ling Hu, Rongfeng Zhang, Xiao‐Bing Yuan, Lin Zhang, Wei Liu, Yu‐Peng Shi, Ling Wen, Si‐Yu Ren, Tian‐Bing |
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| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/30901120$$D View this record in MEDLINE/PubMed |
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| Keywords | fluorophores DESIGN DYES structure-photophysical property relationships RHODAMINE ORGANIC FLUOROPHORE HOST imaging agents fluorescent probes PROBES density functional calculations WAVELENGTH PHOTODEGRADATION PYRYLIUM fluorophore imaging structure-photophysical property relationship |
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| Snippet | Fluorescent probes have become an indispensable tool in the detection and imaging of biological and disease‐related analytes due to their sensitivity and... Fluorescent probes have become an indispensable tool in the detection and imaging of biological and disease-related analytes due to their sensitivity and... Fluorescent probes have become an indispensable tool in detection and imaging of biological and disease related analytes due to their sensitivity and technical... |
| Source | Web of Science |
| SourceID | proquest pubmed webofscience crossref wiley |
| SourceType | Aggregation Database Index Database Enrichment Source Publisher |
| StartPage | 6973 |
| SubjectTerms | Amino groups Biomedical materials Chemical compounds Chemistry Chemistry, Multidisciplinary Corrosion resistance density functional calculations Emission Emissions Fluorescent indicators fluorescent probes Fluorophores Hypoxia Imaging imaging agents Mitochondria Nitroreductase Organic chemistry Physical Sciences Probes Reagents Science & Technology Sensitivity analysis Stability structure–photophysical property relationships Wavelength |
| Title | Donor and Ring‐Fusing Engineering for Far‐Red to Near‐Infrared Triphenylpyrylium Fluorophores with Enhanced Fluorescence Performance for Sensing and Imaging |
| URI | https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fchem.201900246 http://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcApp=Summon&SrcAuth=ProQuest&DestApp=WOS&DestLinkType=FullRecord&UT=000471040700015 https://www.ncbi.nlm.nih.gov/pubmed/30901120 https://www.proquest.com/docview/2226339098 https://www.proquest.com/docview/2196514536 |
| Volume | 25 |
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