Photophysical Property and Photostability of J-Aggregate Thin Films of Thiacyanine Dyes Prepared by the Spin-Coating Method

Tani, Kotaro; Ito, Chizuru; Hanawa, Yasuhiro; Uchida, Mamoru; Otaguro, Kunihiko; Horiuchi, Hiroaki; Hiratsuka, Hiroshi

doi:10.1021/jp077088o

Cited by 34 publications

(38 citation statements)

References 45 publications

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“…The formation of thin films on their surface can be achieved by exploring the principle of layer-by-layer assembly [147,148]. Thus the films of PIC dye on a cellulose acetate support were prepared by spin coating [149], and it was reported that the spin-coating of dye-polymer mixtures allows obtaining stable thin layers of J-aggregates [150].…”

Section: J-aggregates Formed On Scaffoldsmentioning

confidence: 99%

Fluorescent J-aggregates of cyanine dyes: basic research and applications review

Bricks

Slominskii

Panas

et al. 2017

Methods Appl. Fluoresc.

340

299

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J-aggregates are fascinating fluorescent nanomaterials formed by highly ordered assembly of organic dyes with the spectroscopic properties dramatically different from that of single or disorderly assembled dye molecules. They demonstrate very narrow red-shifted absorption and emission bands, strongly increased absorbance together with the decrease of radiative lifetime, highly polarized emission and other valuable features. The mechanisms of their electronic transitions are understood by formation of delocalized excitons already on the level of several coupled monomers. Cyanine dyes are unique in forming J-aggregates over the broad spectral range, from blue to near-IR. With the aim to inspire further developments, this review is focused on the optical characteristics of J-aggregates in connection with the dye structures and on their diverse already realized and emerging applications.

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Section: J-aggregates Formed On Scaffoldsmentioning

confidence: 99%

Fluorescent J-aggregates of cyanine dyes: basic research and applications review

Bricks

Slominskii

Panas

et al. 2017

Methods Appl. Fluoresc.

340

299

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“…The J-band is attributed to delocalized Frenkel-type exciton states present in the assemblies of dye molecules interacting by electrostatic forces when J-aggregate is formed in concentrated solution or thin films [21]. Photophysical properties of the film of cyanine have been investigated by determining the fluorescence quantum yields and lifetimes [22][23][24]. A novel hybrid organic/inorganic nanocomposite of alternating monolayers of J-aggregated cyanine and crystalline semiconductor quantum dots have been fabricated by a layer-by-layer self-assembly technique [25].…”

Section: Introductionmentioning

confidence: 99%

Patterning of J-aggregated dyes using directed self-assembly on micro- and nanopatterned templates fabricated from phase-separated mixed Langmuir–Blodgett films

Watanabe

Shibata

Horiuchi

et al. 2010

Journal of Colloid and Interface Science

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“…Thus ultrasound may induce disaggregation of weakly connected aggregate. Generally, the aggregation of organic dyes induces enhancement of internal conversion, 11,12 and the aggregate shows lower Φ ¦ than monomer according to eq 1,where Φ isc is the quantum yield of intersystem crossing, k isc , k f , and k ic are rate constants of intersystem crossing, fluorescence, and internal conversion, respectively. On the basis of this fact, we expected that the OFF to ON switching of singlet oxygen sensitization can be achieved by using disaggregation of photosensitizer induced by sonication.…”

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confidence: 99%

mentioning

confidence: 99%

Sono-activatable Photosensitizer for Photodynamic Therapy

et al. 2014

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A carboxy tetraphenylporphyrin derivative formed aggregate by decreasing its pH, and suppressed its fluorescence and sensitization of singlet oxygen. This indicates that ON/OFF switching of the photosensitization can be achieved by aggregation and disaggregation of photosensitizers. To induce disaggregation, ultrasound was applied to the solution of the aggregate of photosensitizers, and disaggregation was confirmed by studying the fluorescence of the photosensitizer and phosphorescence of singlet oxygen sensitized. Thus this system works as a sono-activatable photosensitizer for photodynamic therapy.Photodynamic therapy (PDT) is known as a promising cancer treatment. PDT is expected to show lower side effects than conventional major treatments for cancer such as surgery, chemotherapy, and radiotherapy. PDT is based on light irradiation and injection of photosensitizer which are preferentially taken up and/or retained by tumors. To develop PDT, improvements of photosensitizer are indispensable. Mainly, there are two methods to improve photosensitizers. The first is improvement of activity. Factors controlling the activity of a photosensitizer involve accumulation efficiency to tumors, cellular uptake efficiency, light absorption efficiency in the red to near-IR region, and quantum yield of singlet oxygen sensitization Φ ¦ . Many studies have been devoted to improve these factors.14 We have also improved photosensitizers by introducing silyl groups into tetraphenylporphyrin derivatives and clarified that silylation improves Φ ¦ , 57 cellular uptake efficiency, 6,7 and selective accumulation efficiency to tumors, 7 simultaneously. As a result of these improvements, we confirmed the enhancement of in vivo PDT activity by using tumorbearing mice. 7 The second method is to reduce side effects. Photosensitizers themselves show no side effects in the dark. During treatment, the tumor is irradiated with intense light as a trigger to kill cancer cells. However, patients are also exposed to this trigger in daily life (room light and/or sunlight). Although the photosensitizer used for PDT possesses tumor selectivity, its concentration is not negligibly small in normal tissue such as skin. Thus patients have to remain in a dark room until almost all the photosensitizers injected are eliminated. The period for staying in the dark room is usually one week for NPe6, and one month for Photofrinμ. These long periods are one of the reasons for hesitation in selecting PDT as a cancer treatment. There are two strategies to reduce this side effect. The first is to reduce concentration of photosensitizer in normal tissue, i.e., improvement of tumor selectivity. Various kinds of drug delivery systems have been developed not only for photosensitizers but also for anticancer agents. Silylation of porphyrin derivatives is also a method to improve tumor selectivity. 7 The second strategy is to introduce an ON/OFF switch on the photosensitizer. This activatable photosensitizer should not sensitize singlet oxygen in the normal condition (OF...

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Photophysical Property and Photostability of J-Aggregate Thin Films of Thiacyanine Dyes Prepared by the Spin-Coating Method

Cited by 34 publications

References 45 publications

Fluorescent J-aggregates of cyanine dyes: basic research and applications review

Fluorescent J-aggregates of cyanine dyes: basic research and applications review

Patterning of J-aggregated dyes using directed self-assembly on micro- and nanopatterned templates fabricated from phase-separated mixed Langmuir–Blodgett films

Sono-activatable Photosensitizer for Photodynamic Therapy

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