Versatile Photosensitizers for Photodynamic Therapy at Infrared Excitation

Zhang, Peng; Steelant, Wim F.A.; Kumar, Manoj; Scholfield, Matthew

doi:10.1021/ja0700707

Cited by 549 publications

(434 citation statements)

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“…Monodisperse UCNPs with distinct shapes are model systems to advance the understanding of the shape-directed assembly/packing behaviors of nanocolloids, but also open new opportunities in fields such as bioimaging (18,19) and photodynamic therapy (20,49). Programming anisotropic NCs to assemble into desired two-and three-dimensional patterns enables the production of complex nanoscale architectures useful for applications such as solar cells (46) and plasmonic metamaterials (50).…”

Section: Discussionmentioning

confidence: 99%

“…These NCs often possess "peculiar" optical properties [e.g., quantum cutting (16) and photon upconversion (17)], allowing the management of photons that could benefit a variety of areas including biomedical imaging (18,19) and therapy (20), photovoltaics (16,21), solid state lighting (22), and display technologies (23). Colloidal upconversion nanophosphors (UCNPs) are capable of converting long-wavelength near-infrared excitation into short-wavelength visible emission through the long-lived, metastable excited states of the lanthanide dopants (24).…”

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confidence: 99%

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Morphologically controlled synthesis of colloidal upconversion nanophosphors and their shape-directed self-assembly

Collins

Kang

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

418

371

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We report a one-pot chemical approach for the synthesis of highly monodisperse colloidal nanophosphors displaying bright upconversion luminescence under 980 nm excitation. This general method optimizes the synthesis with initial heating rates up to 100°C∕ minute generating a rich family of nanoscale building blocks with distinct morphologies (spheres, rods, hexagonal prisms, and plates) and upconversion emission tunable through the choice of rare earth dopants. Furthermore, we employ an interfacial assembly strategy to organize these nanocrystals (NCs) into superlattices over multiple length scales facilitating the NC characterization and enabling systematic studies of shape-directed assembly. The global and local ordering of these superstructures is programmed by the precise engineering of individual NC's size and shape. This dramatically improved nanophosphor synthesis together with insights from shape-directed assembly will advance the investigation of an array of emerging biological and energy-related nanophosphor applications.doped nanocrystals | superlattice | lanthanides | luminescence R ecent advances in synthesis and controlled assembly of monodisperse colloidal nanocrystals (NCs) into superlattice structures have enabled their applications in optics (1), electronics (2), magnetic storage (3), etc. Single-and multicomponent superlattices composed of spherical NCs are increasingly studied and a rich family of structures is now accessible (4, 5), where the electronic and magnetic interactions between the constituents gives rise to new cooperative properties (6, 7). New synthetic approaches are yielding nonspherical NCs with physical properties unobtainable by simply tuning the size of the spheres (8-11), providing an even broader array of nanoscale building blocks. The size and shape dependence of NC's biological activity (12, 13) and toxicity (14) is also of intense interest. However, the challenge of precisely controlling particle shape while maintaining uniformity in size and surface functionality has limited studies of NC environmental health and safety just as it has hindered efforts to organize anisotropic building blocks and to establish methods to capture their unique properties in NC superlattice thin films.Lanthanide-doped nanophosphors are an emerging class of optical materials (15). These NCs often possess "peculiar" optical properties [e.g., quantum cutting (16) and photon upconversion (17)], allowing the management of photons that could benefit a variety of areas including biomedical imaging (18, 19) and therapy (20), photovoltaics (16, 21), solid state lighting (22), and display technologies (23). Colloidal upconversion nanophosphors (UCNPs) are capable of converting long-wavelength near-infrared excitation into short-wavelength visible emission through the long-lived, metastable excited states of the lanthanide dopants (24). In contrast to the Stokes-shifted emissions from semiconductor NCs or organic fluorophores and the multiphoton process employing fluorescent dyes, UCNPs offer several ...

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Morphologically controlled synthesis of colloidal upconversion nanophosphors and their shape-directed self-assembly

Collins

Kang

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

418

371

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“…UCNP-based PDT nanocomposites are considered promising platforms for cancer therapy due to the non-invasive manner and deep tissue penetration of NIR light, which breaks the dilemma of using UV or visible lights as irradiation source. Since Zhang et al 32 first demonstrated the application of UCNP-based nanocomposite for PDT of bladder cancer cells, recent advances in the integration of UCNPs with PSs such as chlorin e6, Rose Bengal, and IR825 (an NIR-absorbing dye) for their PDT applications in vitro and in vivo have created many excitements. [33][34][35] However, the phototoxic effect of 1 O 2 on PDT is restricted because of a hypoxic condition in tumor tissue.…”

Section: Introductionmentioning

confidence: 99%

Multifunctional upconversion–nanoparticles–trismethylpyridylporphyrin–fullerene nanocomposite: a near-infrared light-triggered theranostic platform for imaging-guided photodynamic therapy

Guan

Dong

et al. 2015

NPG Asia Mater

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Photodynamic therapy (PDT) is an excellent therapeutic modality for various malignant and nonmalignant cancers. This approach utilizes reactive oxygen species generated through the reaction between photosensitizer and oxygen in tissues upon light irradiation to achieve effective treatment. However, limited penetration depth and oxygen-deficient microenvironment hinder the efficiency of PDT. In this work, we design a multifunctional near-infrared (NIR)-triggered theranostic agent based on upconversion-nanoparticles-Polyoxyethylene bis (amine)-trismethylpyridylporphyrin-fullerene nanocomposite (UCNP-PEG-FA/ PC 70 ) for imaging (fluorescence/upconversion luminescence/magnetic resonance imaging)-guided photodynamic therapy. In this multimodal nanocompsite, UCNPs are employed as light transducers to convert NIR light into ultraviolet-visible light to activate PC 70 to generate singlet oxygen ( 1 O 2 ) even under low-oxygen conditions. Meanwhile, the upconversion emission, magnetic resonance imaging and fluorescence signal coming from UCNPs and PC 70 nanocomposite enable UCNP-PEG-FA/PC 70 to act as a multimodal imaging diagnostic agent, which facilitates the imaging-guided PDT. Furthermore, folate-mediated active targeting would enhance the accumulation of multifunctional hybrid in tumor. In vitro as well as in vivo results suggest that this smart nanocomposite is promising as an NIR light-triggered and -targeted theranostic platform for imaging-guided PDT of cancer, which may provide a solution to the bottleneck problems of PDT, namely, limited penetration depth and oxygen-deficient microenvironment.

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“…The application of Ln 3+ -UCNPs as an energy source for exciting photosensitizers has been proposed. [8][9][10][11][12][13] The nanoconstructs, which were prepared using upconverting nanoparticles for the excitation of different photosensitizers, made use of the Er 3+ transitions, 2 H 11/2 , 4 S 3/2 -4 I 11/2 and 4 F 9/2 -4 I 11/2 . The transitions have one major disadvantage, the emission from these transitions does not overlap with the strongest absorption peak, the Soret band, of the photosensitizer presently used, which is at B400 nm.…”

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confidence: 99%

Chemical modification of temoporfin – a second generation photosensitizer activated using upconverting nanoparticles for singlet oxygen generation

Rodriguez

Naccache

et al. 2014

Chem. Commun.

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In photodynamic therapy (PDT), the destruction of a target tissue (localized tumor) involves the combination of light of a specific wavelength, oxygen and a photosensitizer (PS). 1-3 Individually, these components are harmless; however, when combined, a putative cytotoxic agent, singlet oxygen ( 1 O 2 ), is generated. It is the 1 D g form of singlet oxygen that induces oxidation damages on cell components, resulting in cytotoxic reactions in the cells via necrosis or apoptosis, the self-destruction mechanisms of cells.The second generation PS, 5,10,15,20-tetra(m-hydroxyphenyl)-chlorin 4-6 (m-THPC, Foscan s , Temoporfin), with enhanced absorption of light in the red region (l max = 652 nm) has been found to be more specific than conventional porphyrins where skin photosensitization, usually a side effect of PDT, has been reported to be shorter. However, m-THPC does not make use of the optimal spectral biological window for tissue penetration in the 700-1000 nm range. Unfortunately, photons in this region are energetically too low for 1 O 2 generation. In addition to the band at 652 nm, which has a high molar extinction coefficient (e = 2.9 Â 10 4 cm À1 M À1 ), m-THPC has another absorption band in the blue region centered at 417 nm with a much higher molar absorption coefficient (e = 2.3 Â 10 5 cm À1 M À1 ). Excitation of m-THPC at 417 nm would eliminate the problem of low photon energy; however, direct excitation with high-energy blue light limits the use in biological applications due to its low tissue penetration depth. 7Lanthanide-doped upconverting nanoparticles (Ln 3+ -UCNPs) have been intensively studied in recent years. These nanoparticles can emit UV, visible and/or near-infrared (NIR) light upon NIR excitation (typically 980 nm) via a multiphoton process known as upconversion. The application of Ln 3+ -UCNPs as an energy source for exciting photosensitizers has been proposed. [8][9][10][11][12][13] The nanoconstructs, which were prepared using upconverting nanoparticles for the excitation of different photosensitizers, made use of the Er 3+ transitions, 2 H 11/2 , 4 S 3/2 -4 I 11/2 and 4 F 9/2 -4 I 11/2 . The transitions have one major disadvantage, the emission from these transitions does not overlap with the strongest absorption peak, the Soret band, of the photosensitizer presently used, which is at B400 nm. 14 The ideal modification would be to shift the Soret band of the photosensitizer to obtain the maximum overlap with the emission band(s) of the Ln 3+ -UCNPs. Temoporfin is one example of an approved second-generation photosensitizer. 15 Our group has recently synthesized LiYF 4 :Tm 3+ /Yb 3+ -UCNPs that showed stronger UV/blue emission following NIR excitation with 980 nm light compared to NaYF 4 . 16 Taking advantage of the high penetration depth and minimal autofluorescence of the NIR excitation light, LiYF 4 :Tm 3+ /Yb 3+ -UCNPs can be used as UV/blue excitation sources in biological applications.In this study we report on the functionalization of LiYF 4 :Tm 3+ / Yb 3+ -UCNPs with m-THPC to d...

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Versatile Photosensitizers for Photodynamic Therapy at Infrared Excitation

Cited by 549 publications

References 18 publications

Morphologically controlled synthesis of colloidal upconversion nanophosphors and their shape-directed self-assembly

Morphologically controlled synthesis of colloidal upconversion nanophosphors and their shape-directed self-assembly

Multifunctional upconversion–nanoparticles–trismethylpyridylporphyrin–fullerene nanocomposite: a near-infrared light-triggered theranostic platform for imaging-guided photodynamic therapy

Chemical modification of temoporfin – a second generation photosensitizer activated using upconverting nanoparticles for singlet oxygen generation

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