Synthesis, photophysics, and solvatochromic studies of an aggregated-induced-emission luminogen useful in bioimaging
Synthesis, photophysics, and solvatochromic studies of an aggregated-induced-emission luminogen useful in bioimaging
Biological samples are a complex and heterogeneous matrix where different macromolecules with different physicochemical parameters cohabit in reduced spaces. The introduction of fluorophores into these samples, such as in the interior of cells, can produce changes in the fluorescence emission properties of these dyes, caused by the specific physicochemical properties of cells. This effect can be especially intense with solvatofluorochromic dyes, where changes in the polarity environment surrounding the dye can drastically change the fluorescence emission. In this article, we studied the photophysical behavior of a new dye and confirmed the aggregation-induced emission (AIE) phenomenon with different approaches, such as by using different solvent proportions, increasing the viscosity, forming micelles, and adding bovine serum albumin (BSA), through analysis of the absorption and steady-state and time-resolved fluorescence. Our results show the preferences of the dye for nonpolar media, exhibiting AIE under specific conditions through immobilization. Additionally, this approach offers the possibility of easily determining the critical micelle concentration (CMC). Finally, we studied the rate of spontaneous incorporation of the dye into cells by fluorescence lifetime imaging and observed the intracellular pattern produced by the AIE. Interestingly, different intracellular compartments present strong differences in fluorescence intensity and fluorescence lifetime. We used this difference to isolate different intracellular regions to selectively study these regions. Interestingly, the fluorescence lifetime shows a strong difference in different intracellular compartments, facilitating selective isolation for a detailed study of specific organelles.
Aggregated enhanced emission, Bioimaging, Photophysics
Espinar-Barranco, Laura
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Meazza, Marta
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Linares-Perez, Azahara
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Rios, Ramon
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Paredes, Jose Manuel
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Crovetto, Luis
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12 November 2019
Espinar-Barranco, Laura
c57fb7ee-400b-4242-b72e-767e4a462208
Meazza, Marta
c4665645-8c77-4cfd-aa02-6bcc3341c1aa
Linares-Perez, Azahara
3a0292a1-7de1-4223-ad54-aabd8f6774ce
Rios, Ramon
609bedf2-e886-4d62-a676-a32b6f8c1441
Paredes, Jose Manuel
fb8fcdcc-6e95-4853-8512-e9aad53869c1
Crovetto, Luis
45d4cd97-3fe5-4498-a861-bc06492eb09d
Espinar-Barranco, Laura, Meazza, Marta, Linares-Perez, Azahara, Rios, Ramon, Paredes, Jose Manuel and Crovetto, Luis
(2019)
Synthesis, photophysics, and solvatochromic studies of an aggregated-induced-emission luminogen useful in bioimaging.
Sensors (Switzerland), 19 (22), [4932].
(doi:10.3390/s19224932).
Abstract
Biological samples are a complex and heterogeneous matrix where different macromolecules with different physicochemical parameters cohabit in reduced spaces. The introduction of fluorophores into these samples, such as in the interior of cells, can produce changes in the fluorescence emission properties of these dyes, caused by the specific physicochemical properties of cells. This effect can be especially intense with solvatofluorochromic dyes, where changes in the polarity environment surrounding the dye can drastically change the fluorescence emission. In this article, we studied the photophysical behavior of a new dye and confirmed the aggregation-induced emission (AIE) phenomenon with different approaches, such as by using different solvent proportions, increasing the viscosity, forming micelles, and adding bovine serum albumin (BSA), through analysis of the absorption and steady-state and time-resolved fluorescence. Our results show the preferences of the dye for nonpolar media, exhibiting AIE under specific conditions through immobilization. Additionally, this approach offers the possibility of easily determining the critical micelle concentration (CMC). Finally, we studied the rate of spontaneous incorporation of the dye into cells by fluorescence lifetime imaging and observed the intracellular pattern produced by the AIE. Interestingly, different intracellular compartments present strong differences in fluorescence intensity and fluorescence lifetime. We used this difference to isolate different intracellular regions to selectively study these regions. Interestingly, the fluorescence lifetime shows a strong difference in different intracellular compartments, facilitating selective isolation for a detailed study of specific organelles.
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sensors-19-04932
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Accepted/In Press date: 7 November 2019
Published date: 12 November 2019
Keywords:
Aggregated enhanced emission, Bioimaging, Photophysics
Identifiers
Local EPrints ID: 436332
URI: http://eprints.soton.ac.uk/id/eprint/436332
ISSN: 1424-8220
PURE UUID: 7cde069d-734a-463a-9ed6-ae792e972c8c
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Date deposited: 06 Dec 2019 17:30
Last modified: 17 Mar 2024 12:36
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Contributors
Author:
Laura Espinar-Barranco
Author:
Marta Meazza
Author:
Azahara Linares-Perez
Author:
Jose Manuel Paredes
Author:
Luis Crovetto
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