Revealing the sensing mechanism of a fluorescent pH probe based on a bichromophore approach
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Revealing the sensing mechanism of a fluorescent pH probe based on a bichromophore approach. / Zhang, Wei; Zhao, Li; Laursen, Bo W.; Chen, Junsheng.
I: Physical Chemistry Chemical Physics, Bind 24, Nr. 43, 13.10.2022, s. 26731–26737.Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt
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TY - JOUR
T1 - Revealing the sensing mechanism of a fluorescent pH probe based on a bichromophore approach
AU - Zhang, Wei
AU - Zhao, Li
AU - Laursen, Bo W.
AU - Chen, Junsheng
PY - 2022/10/13
Y1 - 2022/10/13
N2 - Fluorescence sensing plays an increasingly important role in biology and biomedicine. For many practical applications of fluorescent probes, an "off-on" response is preferred. The question of how fluorescence quenching/enhancement occurs is fundamental and of high importance for application and design of new fluorescent probes. The sensing mechanism of an aminorhodamine (TMARh) pH probe is investigated using femtosecond transient absorption spectroscopy and quantum chemical calculations, showing that this probe is best understood using the bichromophore model rather than the more common models such as photoinduced electron transfer or intramolecular charge transfer. Under excitation in the main absorption band at 530 nm, a fast internal conversion to the first excited state (S-1) is observed for TMARh; meanwhile, no new transient components are obtained when TMARh is excited directly to S-1 in the weakly absorbing red tail at 630 nm. It is confirmed that the S-1 of TMARh is a dark "off" state. Theoretical calculations show that the S-1 "off" state is an intramolecular charge transfer state from an aminophenyl group to a rhodamine chromophore. After protonation of the aminophenyl group, to yield HTMARh, the transient S-2/S-1 internal conversion process that occurs in TMARh under 530 nm excitation is absent, suggesting that the charge transfer state becomes highly unfavorable. All calculations and spectral data confirm that HTMARh has localized transition in the rhodamine chromophore, in agreement with this being the bright "on" state of the pH probe. The current work not only provides a photophysical insight into the sensing mechanism of this specific probe, but also shows that the bichromophore model is useful and may be relevant for analyzing other probes or in the designing of new ones.
AB - Fluorescence sensing plays an increasingly important role in biology and biomedicine. For many practical applications of fluorescent probes, an "off-on" response is preferred. The question of how fluorescence quenching/enhancement occurs is fundamental and of high importance for application and design of new fluorescent probes. The sensing mechanism of an aminorhodamine (TMARh) pH probe is investigated using femtosecond transient absorption spectroscopy and quantum chemical calculations, showing that this probe is best understood using the bichromophore model rather than the more common models such as photoinduced electron transfer or intramolecular charge transfer. Under excitation in the main absorption band at 530 nm, a fast internal conversion to the first excited state (S-1) is observed for TMARh; meanwhile, no new transient components are obtained when TMARh is excited directly to S-1 in the weakly absorbing red tail at 630 nm. It is confirmed that the S-1 of TMARh is a dark "off" state. Theoretical calculations show that the S-1 "off" state is an intramolecular charge transfer state from an aminophenyl group to a rhodamine chromophore. After protonation of the aminophenyl group, to yield HTMARh, the transient S-2/S-1 internal conversion process that occurs in TMARh under 530 nm excitation is absent, suggesting that the charge transfer state becomes highly unfavorable. All calculations and spectral data confirm that HTMARh has localized transition in the rhodamine chromophore, in agreement with this being the bright "on" state of the pH probe. The current work not only provides a photophysical insight into the sensing mechanism of this specific probe, but also shows that the bichromophore model is useful and may be relevant for analyzing other probes or in the designing of new ones.
KW - PHOTOINDUCED ELECTRON-TRANSFER
KW - INTRAMOLECULAR CHARGE-TRANSFER
KW - DENSITY-FUNCTIONAL THEORY
KW - STRUCTURAL-CHANGES
KW - RATIONAL DESIGN
KW - CHEMOSENSOR
KW - INVALIDITY
KW - STATES
KW - PET
U2 - 10.1039/d2cp04339d
DO - 10.1039/d2cp04339d
M3 - Journal article
C2 - 36314051
VL - 24
SP - 26731
EP - 26737
JO - Physical Chemistry Chemical Physics
JF - Physical Chemistry Chemical Physics
SN - 1463-9076
IS - 43
ER -
ID: 324961883