NIR-BODIPY-based fluorescent nanoparticles: synthesis, spectral properties study and bioimaging applications

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NIR-BODIPY-based fluorescent nanoparticles: synthesis, spectral properties study and bioimaging applications. / Антина, Любовь; Калинкина, Валерия; Калягин, Александр; Ксенофонтов, Александр; Соловьева, Елена Викторовна ; Смирнов, Алексей Александрович ; Семёнов, Константин Николаевич ; Шаройко, Владимир Владимирович; Березин, Михаил; Антина , Антина.

в: Journal of Molecular Liquids, Том 436, 128215, 15.10.2025.

Результаты исследований: Научные публикации в периодических изданиях › статья › Рецензирование

BibTeX

@article{fd6bdfa9ca5641eda8a7d9c8c3fd119b,

title = "NIR-BODIPY-based fluorescent nanoparticles: synthesis, spectral properties study and bioimaging applications",

abstract = "Fluorescence imaging techniques have been widely used to visualize biological molecules. Near-infrared BODIPYs are attractive candidates due to their intensive absorbance, fluorescence, photostability, and biocompatibility. Nevertheless, BODIPYs are highly hydrophobic, which is often problematic in fluorescence imaging of living cells. The uncharged nature of BODIPY molecules and their high hydrophobicity result in high affinity for lipid membranes, but this often leads to irreversible accumulation in subcellular membranes. In this paper, using three near-infrared aminostyryl-, hydroxystyryl- and pyrrolyl-BODIPYs 1-3 as an example, a simple method is proposed to solve the problem of high hydrophobicity and molecular aggregation by encapsulating luminophores in micelles of the amphiphilic block copolymer Pluronic{\textregistered} F127. The structural and optical characteristics of both NIR-BODIPYs 1-3 and their water-soluble forms NIR-BODIPY@Pluronic, as well as their effects on cell membrane permeability and fluorescence intensity in living cells, are analyzed in detail. HeLa cell staining tests demonstrate that all three types of nanoparticles with BODIPYs 1-3@Pluronic exhibit high membrane penetration and retention in cells, localizing in their cytoplasm. The nanoparticles with low dye loading are preferable for cell staining as they give the brightest images. Excellent optical properties, lack of toxicity, and high water solubility make the NIR-BODIPY@Pluronic nanoparticles as promising candidates for bioimaging in the red and NIR spectral ranges.",

keywords = "Pluronic{\textregistered} F127, Water-soluble forms of NIR-BODIPYs, Вiological imaging capability, Рolymer micelles",

author = "Любовь Антина and Валерия Калинкина and Александр Калягин and Александр Ксенофонтов and Соловьева, {Елена Викторовна} and Смирнов, {Алексей Александрович} and Семёнов, {Константин Николаевич} and Шаройко, {Владимир Владимирович} and Михаил Березин and Антина Антина",

note = "2. L. A. Antina, V. A. Kalinkina, A. A. Kalyagin, A. A. Ksenofontov, E. V. Solovyeva, A. A. Smirnov, K. N. Semenov, V. V. Sharoyko, M. B. Berezin, E. V. Antina, NIR-BODIPY-based fluorescent nanoparticles: synthesis, spectral properties study and bioimaging applications, Journal of Molecular Liquids, 436 (2025) 128215 10.1016/j.molliq.2025.128215",

year = "2025",

month = oct,

day = "15",

doi = "10.1016/j.molliq.2025.128215",

language = "English",

volume = "436",

journal = "Journal of Molecular Liquids",

issn = "0167-7322",

publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - NIR-BODIPY-based fluorescent nanoparticles: synthesis, spectral properties study and bioimaging applications

AU - Антина, Любовь

AU - Калинкина, Валерия

AU - Калягин, Александр

AU - Ксенофонтов, Александр

AU - Соловьева, Елена Викторовна

AU - Смирнов, Алексей Александрович

AU - Семёнов, Константин Николаевич

AU - Шаройко, Владимир Владимирович

AU - Березин, Михаил

AU - Антина , Антина

N1 - 2. L. A. Antina, V. A. Kalinkina, A. A. Kalyagin, A. A. Ksenofontov, E. V. Solovyeva, A. A. Smirnov, K. N. Semenov, V. V. Sharoyko, M. B. Berezin, E. V. Antina, NIR-BODIPY-based fluorescent nanoparticles: synthesis, spectral properties study and bioimaging applications, Journal of Molecular Liquids, 436 (2025) 128215 10.1016/j.molliq.2025.128215

PY - 2025/10/15

Y1 - 2025/10/15

N2 - Fluorescence imaging techniques have been widely used to visualize biological molecules. Near-infrared BODIPYs are attractive candidates due to their intensive absorbance, fluorescence, photostability, and biocompatibility. Nevertheless, BODIPYs are highly hydrophobic, which is often problematic in fluorescence imaging of living cells. The uncharged nature of BODIPY molecules and their high hydrophobicity result in high affinity for lipid membranes, but this often leads to irreversible accumulation in subcellular membranes. In this paper, using three near-infrared aminostyryl-, hydroxystyryl- and pyrrolyl-BODIPYs 1-3 as an example, a simple method is proposed to solve the problem of high hydrophobicity and molecular aggregation by encapsulating luminophores in micelles of the amphiphilic block copolymer Pluronic® F127. The structural and optical characteristics of both NIR-BODIPYs 1-3 and their water-soluble forms NIR-BODIPY@Pluronic, as well as their effects on cell membrane permeability and fluorescence intensity in living cells, are analyzed in detail. HeLa cell staining tests demonstrate that all three types of nanoparticles with BODIPYs 1-3@Pluronic exhibit high membrane penetration and retention in cells, localizing in their cytoplasm. The nanoparticles with low dye loading are preferable for cell staining as they give the brightest images. Excellent optical properties, lack of toxicity, and high water solubility make the NIR-BODIPY@Pluronic nanoparticles as promising candidates for bioimaging in the red and NIR spectral ranges.

AB - Fluorescence imaging techniques have been widely used to visualize biological molecules. Near-infrared BODIPYs are attractive candidates due to their intensive absorbance, fluorescence, photostability, and biocompatibility. Nevertheless, BODIPYs are highly hydrophobic, which is often problematic in fluorescence imaging of living cells. The uncharged nature of BODIPY molecules and their high hydrophobicity result in high affinity for lipid membranes, but this often leads to irreversible accumulation in subcellular membranes. In this paper, using three near-infrared aminostyryl-, hydroxystyryl- and pyrrolyl-BODIPYs 1-3 as an example, a simple method is proposed to solve the problem of high hydrophobicity and molecular aggregation by encapsulating luminophores in micelles of the amphiphilic block copolymer Pluronic® F127. The structural and optical characteristics of both NIR-BODIPYs 1-3 and their water-soluble forms NIR-BODIPY@Pluronic, as well as their effects on cell membrane permeability and fluorescence intensity in living cells, are analyzed in detail. HeLa cell staining tests demonstrate that all three types of nanoparticles with BODIPYs 1-3@Pluronic exhibit high membrane penetration and retention in cells, localizing in their cytoplasm. The nanoparticles with low dye loading are preferable for cell staining as they give the brightest images. Excellent optical properties, lack of toxicity, and high water solubility make the NIR-BODIPY@Pluronic nanoparticles as promising candidates for bioimaging in the red and NIR spectral ranges.

KW - Pluronic® F127

KW - Water-soluble forms of NIR-BODIPYs

KW - Вiological imaging capability

KW - Рolymer micelles

UR - https://www.mendeley.com/catalogue/c2a20dd2-f4ff-34b0-b696-f939c7dcc91f/

U2 - 10.1016/j.molliq.2025.128215

DO - 10.1016/j.molliq.2025.128215

M3 - Article

VL - 436

JO - Journal of Molecular Liquids

JF - Journal of Molecular Liquids

SN - 0167-7322

M1 - 128215

ER -

ID: 139342504