Lanthanide-Doped Core–Shell–Shell Nanocomposite for Dual Photodynamic Therapy and Luminescence Imaging by a Single X-ray Excitation Source

Hsu, Chang-Chieh; Lin, Syue Liang; Chang, C. Allen

doi:10.1021/acsami.8b00015

Cited by 90 publications

(56 citation statements)

References 59 publications

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“…Coating mSiO 2 on the surface of oleate-capped UCNP was prepared according to the previously reported method 60 . Cetyltrimethyl-ammonium chloride (CTAC, 0.2 g) and the previously prepared core-shell-shell UCNPs (5 mg) were dissolved in 25 mL water at 50 °C with stirring overnight.…”

Section: Methodsmentioning

confidence: 99%

Nd³⁺ sensitized core-shell-shell nanocomposites loaded with IR806 dye for photothermal therapy and up-conversion luminescence imaging by a single wavelength NIR light irradiation

Lin¹,

Chen²,

Chang³

2018

Nanotheranostics

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To perform photothermal therapy (PTT) and luminescence imaging by a single wavelength NIR light irradiation, we have designed and prepared a novel nanocomposite incorporating the IR806 photothermal sensitizers (PTS) into the core-shell-shell NaYF4:Yb,Er@ NaYF4:Yb@NaYF4:Yb,Nd up-conversion nanoparticles (UCNPs). Irradiation with the 793 nm near-infrared (NIR) laser, the Nd3+ ions in the UCNPs were sensitized to up-convert energy via Yb3+ to the Er3+ ions to emit visible light at 540 nm and 654 nm, as well as to down-convert energy to the Yb3+ ions to emit NIR light at 980 nm. For luminescence imaging, the 793 nm NIR radiation is more suitable to use for deeper-tissue penetration and to reduce overheating problem due to water absorption as compared to 980 nm radiation. Additionally, the same 793 nm NIR radiation could also excite the IR806 dye for effective PTT. Surface modifications of the UCNPs with mesoporous silica (mSiO2) and polyallylamine (PAH) allow stable loading of IR806 dye and further derivatization with polyethylene glycol-folic acid (PEG-FA) for tumor targeting. Preliminary in vitro studies demonstrated that the final UCNP@mSiO2/IR806@PAH-PEG-FA nanocomposites (UCNC-FAs) could be uptaken by the MDA-MB-231 cancer cells and were “dark” viable, and when irradiated with the 793 nm laser, the MDA-MB-231 cell viability was effectively reduced. This indicated that the UCNC-FAs nanocomposites could be potentially useful for targeted photothermal therapy and up-conversion luminescence imaging by a single wavelength NIR light irradiation.

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Section: Methodsmentioning

confidence: 99%

Nd³⁺ sensitized core-shell-shell nanocomposites loaded with IR806 dye for photothermal therapy and up-conversion luminescence imaging by a single wavelength NIR light irradiation

Lin¹,

Chen²,

Chang³

2018

Nanotheranostics

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“…For future studies, in addition to reducing the non‐specific binding, It would be helpful to design Ln III chelates or other substances such as nanocomposites with longer wavelength excitation (e.g. λ ex > 380 nm or preferably in the near infrared region) or X‐ray excitation for more convenient, deep‐penetrating in vivo bioimaging applications.…”

Section: Resultsmentioning

confidence: 99%

A Cyclic‐RGD Dinuclear Tb^III Macrocyclic Complex as a Tumor Integrin‐Selective Luminescent Probe

Chang

Chia²,

Lin

2018

Eur J Inorg Chem

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To develop small molecular integrin-selective luminescent imaging probes, we have prepared the binary dipicolinate (DPA) Tb III dinuclear macrocyclic complex, Tb 2 (cRGDfK-ODO2A-dimer) (DPA) 2 2or complex I, and reference ligands and Tb III complexes which were purified by HPLC and characterized by NMR, mass spectrometry and luminescence spectroscopy. Luminescence titrations of the structural and bonding model Tb 2 (m-ODO2A-dimer) 2+ complex by DPA 2ion confirmed the molecular formula of the adduct was Tb 2 (m-ODO2A-dimer)(DPA) 2 2-, and the first binary binding con- [a]

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“…Due to the tissue penetration depths afforded to X‐ray radiation relative to the visible spectrum, imaging techniques that exploit X‐ray sensitive agents have been a focus of growing research interest both as negative and positive contrast agents, while the coupling of diagnostic and therapeutic roles for scintillating probes, generally inorganic systems, which convert X‐ray energy into visible/NIR light have also been recently explored . For example, in the theranostic role, the poor efficiency of 1 O 2 generation by organic photodynamic therapy (PDT) photosensitizers has been mitigated by coupling the photosensitizers with scintillating particles to stimulate the PDT photosensitizers .…”

Section: Cie Coordinates Dominant Wavelength and Color Purity mentioning

confidence: 99%

Dynamic Emission Tuning of X‐ray Radioluminescent Crystalline Colloidal Arrays: Coupling the Optical Stop Band with Sequential Förster Resonance Energy Transfers

Burdette

Bandera

Gray³

et al. 2018

Advanced Optical Materials

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efficiency of 1 O 2 generation by organic photodynamic therapy (PDT) photosensitizers has been mitigated by coupling the photosensitizers with scintillating particles to stimulate the PDT photosensitizers. [9] The scintillation mechanism of inorganic systems are inherently tied to the electronic bandstructure of the crystal, while for organic scintillators, the molecular electronic structure dictates the radioluminescence properties. [10] This latter feature allows the organic systems to be used as scintillators in a solid, liquid, or gas phase.Though X-ray projection imaging and computed tomography (CT) [11] are established imaging techniques which detect X-ray attenuation in a sample, X-ray fluorescence (XRF) [12] is an alternative imaging approach which focuses on a positive contrast and can be coupled with CT in X-ray fluorescence computed tomography (XRCT) [13] to produce 3D elemental maps in a sample. Probes that exhibit X-ray radioluminescence are employed in X-ray excited optical luminescence (XEOL) and X-ray luminescence computed tomography (XLCT) with XLCT being proposed as a dual molecular/anatomical imaging modality that utilizes the selective excitation and optical detection of X-ray radioluminescent nanoparticles. [14,15] X-ray attenuation, X-ray fluorescence, and optical luminescence performance is enhanced with nanoparticle probes composed of materials with increasing atomic number. For example, successful nanoparticle X-ray imaging agents include gadolinium oxide, [16] gadolinium or lanthanum oxysulfides doped with europium or terbium, [17] sodium gadolinium tungstate, [18] and alkali metal gadolinium fluorides doped with europium [5] as well as alkali metal yttrium fluorides doped with ytterbium/ erbium [19] or gadolinium. [20] Color tuning of radioluminescent perovskite nanocrystals has also recently been reported where counter-ion type and concentration influenced the emission wavelength. [21] However, the majority of these inorganic nanoparticle systems may pose varying levels of toxicity when employed in vivo [22][23][24][25] and require chelating agents or a passivation overcoat, for example, biocompatible polymers, [26,27] to deter leaching into tissue [28] which can be particularly damaging for patients experiencing renal failure, [29] as kidney inflammation is a serious, common side effect of their use. [30] In order to mitigate the toxicity effects of current scintillating nanoparticles, we present a fully organic X-ray radioluminescent X-ray radiation exhibits diminished scattering and a greater penetration depth in tissue relative to the visible spectrum and has spawned new medical imaging techniques that exploit X-ray luminescence of nanoparticles. The majority of the nanoparticles finding applications in this field incorporate metals with high atomic numbers and pose potential toxicity effects. Here, a general strategy for the preparation of a fully organic X-ray radioluminescent colloidal platform that can be tailored to emit anywhere in the visible spectrum through a judicious cho...

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Lanthanide-Doped Core–Shell–Shell Nanocomposite for Dual Photodynamic Therapy and Luminescence Imaging by a Single X-ray Excitation Source

Cited by 90 publications

References 59 publications

Nd³⁺ sensitized core-shell-shell nanocomposites loaded with IR806 dye for photothermal therapy and up-conversion luminescence imaging by a single wavelength NIR light irradiation

Nd³⁺ sensitized core-shell-shell nanocomposites loaded with IR806 dye for photothermal therapy and up-conversion luminescence imaging by a single wavelength NIR light irradiation

A Cyclic‐RGD Dinuclear Tb^III Macrocyclic Complex as a Tumor Integrin‐Selective Luminescent Probe

Dynamic Emission Tuning of X‐ray Radioluminescent Crystalline Colloidal Arrays: Coupling the Optical Stop Band with Sequential Förster Resonance Energy Transfers

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Lanthanide-Doped Core–Shell–Shell Nanocomposite for Dual Photodynamic Therapy and Luminescence Imaging by a Single X-ray Excitation Source

Cited by 90 publications

References 59 publications

Nd3+ sensitized core-shell-shell nanocomposites loaded with IR806 dye for photothermal therapy and up-conversion luminescence imaging by a single wavelength NIR light irradiation

Nd3+ sensitized core-shell-shell nanocomposites loaded with IR806 dye for photothermal therapy and up-conversion luminescence imaging by a single wavelength NIR light irradiation

A Cyclic‐RGD Dinuclear TbIII Macrocyclic Complex as a Tumor Integrin‐Selective Luminescent Probe

Dynamic Emission Tuning of X‐ray Radioluminescent Crystalline Colloidal Arrays: Coupling the Optical Stop Band with Sequential Förster Resonance Energy Transfers

Contact Info

Product

Resources

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Nd³⁺ sensitized core-shell-shell nanocomposites loaded with IR806 dye for photothermal therapy and up-conversion luminescence imaging by a single wavelength NIR light irradiation

Nd³⁺ sensitized core-shell-shell nanocomposites loaded with IR806 dye for photothermal therapy and up-conversion luminescence imaging by a single wavelength NIR light irradiation

A Cyclic‐RGD Dinuclear Tb^III Macrocyclic Complex as a Tumor Integrin‐Selective Luminescent Probe