Steady‐state Fluorescence Method for Evaluating Excited State Proton Reactions: Application to Fluorescein

Yguerabide, Juan; Talavera, Eva M.; Alvarez, J.M.; Quintero, B.

doi:10.1111/j.1751-1097.1994.tb05130.x

Cited by 61 publications

(91 citation statements)

References 10 publications

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“…Thus, under these conditions, the excited monoanion is converted to the dianion during its lifetime. Similar behavior was found in fluorescein with phosphate buffer 6,7 and N-acetyl aspartic acid. 8 We also compared, in Figure 8, fluorescence intensity versus pH curves in 1 M acetate buffered media and in the absence of buffer.…”

Section: Steady-state Fluorescence Features Of Aqueous Solutions Of Osupporting

confidence: 76%

Absorption and Emission Study of 2‘,7‘-Difluorofluorescein and Its Excited-State Buffer-Mediated Proton Exchange Reactions

et al. 2005

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2′,7′-Difluorofluorescein (Oregon Green 488) is a new fluorescein-based dye, which has found many applications, above all in biochemistry and neurosciences, and its use has become very popular in the last years. In recent years, we have been investigating the excited-state proton exchange reactions of fluorescein and the effect of suitable proton acceptors and donors which promote these reactions. The excited-state proton transfer reactions may appreciably influence the fluorescence results when using these dyes. We present steady-state emission evidence that acetate buffer species promote an excited-state proton transfer between neutral, monoanionic, and dianionic forms of 2′,7′-difluorofluorescein. The time course of the excited species in this reaction was characterized through time-resolved fluorescence measurements, and the kinetics of the reaction was solved by using the global compartmental analysis. A previous identifiability study on the compartmental system set the conditions to design the fluorescence decay surface. This is the first experimental system, studied within this kinetic model, solved under identifiability conditions through global compartmental analysis. The recovered rate constant values for deactivation were 2.94 × 10 8 s -1 for the monoanion and 2.47 × 10 8 s -1 for the dianion, whereas the rate constant values of the buffer-mediated excited-state reaction were 9.70 × 10 8 and 1.79 × 10 8 M -1 s -1 for the deprotonation and protonation, respectively. With these values, a pK a * ) 4.02 was obtained. In this work, we additionally provide an absorption study, including acid-base equilibria, determination of ground-state pK a values (1.02, 3.61, and 4.69), and recovery of molar absorption coefficients of every prototropic species, including absorption and NMR evidence for the existence of three tautomers in neutral species. Steady-state emission spectra of 2′,7′-difluorofluorescein in aqueous solution are also described, where the strong photoacid behavior of the cation is noteworthy.

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Section: Steady-state Fluorescence Features Of Aqueous Solutions Of Osupporting

confidence: 76%

Absorption and Emission Study of 2‘,7‘-Difluorofluorescein and Its Excited-State Buffer-Mediated Proton Exchange Reactions

et al. 2005

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“…Low Phosphate (1 mM) Buffer Concentration. In our previous publication, 2 we found that at low phosphate buffer concentration, the excited monoanion-dianion proton-transfer reaction does not occur to any significant extent. In the present work, we find that the lifetimes and weighting coefficients which we have evaluated at low phosphate buffer concentration are consistent with this mechanism as explained in the next paragraphs.…”

Section: Results and Analysismentioning

confidence: 99%

“…At equilibrium, the value of the ratio is determined by the equilibrium relation [D*(t)] eq /[M*(t)] eq ) K A */[H + ] where K A * is the dissociation equilibrium constant for the excited-state proton reaction M* h D* + H + (pK A * ) pK M * ) 6.3). 2 As soon as equilibrium is established, D* and M* must decay monoexponentially and with the same lifetime in order to maintain a constant value for the equilibrium ratio.…”

Section: Rate Of Equilibration Of Excited-state Proton Exchangementioning

confidence: 99%

“…The extinction coefficient vs wavelength graphs were obtained by methods described in our previous publication. 2 To measure the emission spectra of the (s) dianion and (; ‚‚) monoanion, we recorded fluorescence spectra at pH 11 (λex ) 490 nm) and pH 5.0 (λex ) 440 nm). These spectra correspond respectively to the dianion and monoanion.…”

Section: I(t)mentioning

confidence: 99%

“…In the pH range 6-10, the monoanion-dianion equilibrium prevails, i.e, above pH 6 the concentrations of the cation and neutral forms are essentially zero. 2 When a fluorescein solution is excited by a fast pulse of light, the initial concentrations of the different excited prototropic forms are not at equilibrium values because of (a) preferential excitation of one or more of the forms (depending on exciting wavelength and extinction coefficients) and (b) differences in the values of the equilibrium constants pK a * in the excited state compared to the ground state (pK* M ) 6.3). Therefore, there is a tendency for the different excited forms to interconvert through excited-state proton reactions so as to achieve equilibrium during their lifetimes.…”

Section: Introductionmentioning

confidence: 99%

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Fluorescein Excited-State Proton Exchange Reactions: Nanosecond Emission Kinetics and Correlation with Steady-State Fluorescence Intensity

et al. 2001

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Fluorescein is a complex fluorophore that can exist in one or more of four different prototropic forms (cation, neutral, dianion, and monoanion) depending on pH. In the pH range 6-10, only the dianion and monanion forms are important. In a previous article, we showed by steady-state fluorescein measurements that an excited fluorescein molecule displays excited-state proton transfer reactions which interconvert the monoanion and dianion forms. However, we found that these reactions can occur only in the presence of a suitable proton donor-acceptor buffer such as phosphate buffer. Assuming that, at 1 M phosphate buffer concentration, the excited-state proton exchange reaction of fluorescein rapidly equilibrates during the lifetime of fluorescein, we were able to fit quantitatively steady-state fluorescence intensity vs pH titration graphs to a relatively simple reaction model. In this article, we use nanosecond emission (decay time) methods to study the excitedstate proton reactions of fluorescein in the pH range 6-10 and in the presence of a phosphate buffer concentration. Fluorescein is a challenging fluorophore for the study of excited-state proton reactions because of the strong overlap of the absorption and emission spectra of the monoanion and dianion forms of fluorescein. However by recording nanosecond emission graphs and using methods of analysis of high precision, we have been able to test kinetic mechanisms and evaluate the specific rate constants for the excited-state proton reactions as well as the lifetimes of the monoanion and dianion. Using these values for lifetimes and rate constants, we discuss the process of equilibration in the excited-state and derive expressions which allow us to predict how quickly the excited-state reactions can reach equilibrium. Moreover, we use the above kinetic and spectral parameters to calculate steady-state fluorescence intensity F S vs pH at 1 M phosphate buffer concentration and compare this theoretically calculated graph with the experimental graph.

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Optical pH Sensor with Rapid Response Based on a Fluorescein‐Intercalated Layered Double Hydroxide

Shi

Wei

et al. 2010

Adv Funct Materials

116

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The preparation of a highly oriented photoluminescent film of fluorescein (FLU) and 1‐heptanesulfonic acid sodium (HES) co‐intercalated in a layered double hydroxide (LDH) matrix by electrophoretic deposition (EPD) is reported, and its application as an optical pH sensor is demonstrated. The FLU‐HES/LDH films with thickness ranging from nanometer to micrometer on indium tin oxide substrates exhibite good c‐orientation of LDH platelets (the ab‐plane of the LDH platelets parallel to the substrate), as confirmed by X‐ray diffraction and scanning electron microscopy. Polarized luminescence of the film is observed with anisotropy value r = 0.29, resulting from the highly oriented FLU in the LDH gallery. Furthermore, the optical pH sensor with film thickness of 300 nm exhibits a broad linear dynamic range for solution pH (5.02–8.54), good repeatability (relative standard deviation (RSD) less than 1.5% in 20 consecutive cycles) and reversibility (RSD less than 1.5% in 20 cycles), high photostability and storage stability (ca. 95.2% of its initial fluorescence intensity remains after one month) as well as fast response time (2 s). Therefore, this work creates new opportunities for the preparation and application of LDH‐based chromophores in the field of optical sensors.

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Steady‐state Fluorescence Method for Evaluating Excited State Proton Reactions: Application to Fluorescein

Cited by 61 publications

References 10 publications

Absorption and Emission Study of 2‘,7‘-Difluorofluorescein and Its Excited-State Buffer-Mediated Proton Exchange Reactions

Absorption and Emission Study of 2‘,7‘-Difluorofluorescein and Its Excited-State Buffer-Mediated Proton Exchange Reactions

Fluorescein Excited-State Proton Exchange Reactions: Nanosecond Emission Kinetics and Correlation with Steady-State Fluorescence Intensity

Optical pH Sensor with Rapid Response Based on a Fluorescein‐Intercalated Layered Double Hydroxide

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