Controlled aggregation of methylene blue in silica–methylene blue nanocomposite for enhanced 1O2 generation

[Display omitted] Organic photosensitizers can facilitate photochemical singlet-oxygen (1O2) production, providing a promising strategy for photocatalysis, photodynamic therapy, and environmental protection. Unfortunately, most organic photosensitizers tend to self-aggregate because of their hydroph...

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Published inColloids and surfaces. A, Physicochemical and engineering aspects Vol. 617; p. 126360
Main Authors Saita, Satoshi, Anzai, Maho, Mori, Nanase, Kawasaki, Hideya
Format Journal Article
LanguageEnglish
Published Elsevier B.V 20.05.2021
Subjects
Adsorption
environmental protection
hydrophobicity
irradiation
Methylene blue
Nanocomposite
nanocomposites
organosilicon compounds
photocatalysis
photochemotherapy
Photosensitizer
photosensitizing agents
silica
Silica nanoparticle
singlet oxygen
AA
ABDA
LMB
Silica nanoparticle
PDT
BJH
NP
PS
APTES
Methylene blue
UV–vis
BET
NA
Adsorption
MB
β-NADH
SEM
Nanocomposite
DMF
Photosensitizer
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Abstract [Display omitted] Organic photosensitizers can facilitate photochemical singlet-oxygen (1O2) production, providing a promising strategy for photocatalysis, photodynamic therapy, and environmental protection. Unfortunately, most organic photosensitizers tend to self-aggregate because of their hydrophobicity and conjugated π–π electronic structure, leading to the inactivation of their photosensitizing capabilities. Thus, the controlled aggregation of organic photosensitizers is critical for photosensitizer’s applications. We report a nanocomposite of porous silica nanoaggregates and the organic photosensitizer methylene blue (P-SiOx NAs/MB) that allows the aggregation control of methylene blue (MB). This nanocomposite-photosensitizer consists of highly dispersed MB in P-SiOx NAs and enhances 1O2 production under light irradiation without the inactivation of the photosensitizing ability of MB. The enhanced 1O2 generation rate of P-SiOx NAs/MB is 1.36 times larger than that of free MB. This behavior is contrasted with the inactivation of the photosensitizing ability of MB-encapsulated organo-silica nanoparticles, due to MB self-aggregation within the particles. This study provides a strategy for creating an efficient photosensitizer via suppression of MB self-aggregation to enhance the generation of 1O2.
AbstractList [Display omitted] Organic photosensitizers can facilitate photochemical singlet-oxygen (1O2) production, providing a promising strategy for photocatalysis, photodynamic therapy, and environmental protection. Unfortunately, most organic photosensitizers tend to self-aggregate because of their hydrophobicity and conjugated π–π electronic structure, leading to the inactivation of their photosensitizing capabilities. Thus, the controlled aggregation of organic photosensitizers is critical for photosensitizer’s applications. We report a nanocomposite of porous silica nanoaggregates and the organic photosensitizer methylene blue (P-SiOx NAs/MB) that allows the aggregation control of methylene blue (MB). This nanocomposite-photosensitizer consists of highly dispersed MB in P-SiOx NAs and enhances 1O2 production under light irradiation without the inactivation of the photosensitizing ability of MB. The enhanced 1O2 generation rate of P-SiOx NAs/MB is 1.36 times larger than that of free MB. This behavior is contrasted with the inactivation of the photosensitizing ability of MB-encapsulated organo-silica nanoparticles, due to MB self-aggregation within the particles. This study provides a strategy for creating an efficient photosensitizer via suppression of MB self-aggregation to enhance the generation of 1O2.
Organic photosensitizers can facilitate photochemical singlet-oxygen (¹O₂) production, providing a promising strategy for photocatalysis, photodynamic therapy, and environmental protection. Unfortunately, most organic photosensitizers tend to self-aggregate because of their hydrophobicity and conjugated π–π electronic structure, leading to the inactivation of their photosensitizing capabilities. Thus, the controlled aggregation of organic photosensitizers is critical for photosensitizer’s applications. We report a nanocomposite of porous silica nanoaggregates and the organic photosensitizer methylene blue (P-SiOₓ NAs/MB) that allows the aggregation control of methylene blue (MB). This nanocomposite-photosensitizer consists of highly dispersed MB in P-SiOₓ NAs and enhances ¹O₂ production under light irradiation without the inactivation of the photosensitizing ability of MB. The enhanced ¹O₂ generation rate of P-SiOₓ NAs/MB is 1.36 times larger than that of free MB. This behavior is contrasted with the inactivation of the photosensitizing ability of MB-encapsulated organo-silica nanoparticles, due to MB self-aggregation within the particles. This study provides a strategy for creating an efficient photosensitizer via suppression of MB self-aggregation to enhance the generation of ¹O₂.
ArticleNumber 126360
Author Mori, Nanase
Saita, Satoshi
Anzai, Maho
Kawasaki, Hideya
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Keywords AA
ABDA
LMB
Silica nanoparticle
PDT
BJH
NP
PS
APTES
Methylene blue
UV–vis
BET
NA
Adsorption
MB
β-NADH
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Photosensitizer
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Snippet [Display omitted] Organic photosensitizers can facilitate photochemical singlet-oxygen (1O2) production, providing a promising strategy for photocatalysis,...
Organic photosensitizers can facilitate photochemical singlet-oxygen (¹O₂) production, providing a promising strategy for photocatalysis, photodynamic therapy,...
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SubjectTerms Adsorption
environmental protection
hydrophobicity
irradiation
Methylene blue
Nanocomposite
nanocomposites
organosilicon compounds
photocatalysis
photochemotherapy
Photosensitizer
photosensitizing agents
silica
Silica nanoparticle
singlet oxygen
Title Controlled aggregation of methylene blue in silica–methylene blue nanocomposite for enhanced 1O2 generation
URI https://dx.doi.org/10.1016/j.colsurfa.2021.126360
https://www.proquest.com/docview/2552025467
Volume 617
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