Boosting O<sub>2</sub><sup>•−</sup> Photogeneration via Promoting Intersystem‐Crossing and Electron‐Donating Efficiency of Aza‐BODIPY‐Based Nanoplatforms for Hypoxic‐Tumor Photodynamic Therapy

Chen, Dapeng; Wang, Zhichao; Dai, Hanming; Lv, Xinyi; Ma, Qin; Yang, Da‐Peng; Shao, Jinjun; Xu, Zhigang; Dong, Xiaochen

doi:10.1002/smtd.202000013

Cited by 91 publications

(62 citation statements)

References 37 publications

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“…Therefore, detecting the fluorescence of DCF can reflect the level of intracellular ROS. 39 As shown in Figure 4 a, Hep3B cells incubated with LBBr 2 NPs and DCFH-DA only show weak green fluorescence in the control group without laser irradiation, indicating nearly no ROS generation that proved weak dark toxicity of LBBr 2 NPs. However, the bright green fluorescence of DCF could be observed clearly in Hep3B cells under excitation of a 660 nm laser, which was ascribed to the high singlet oxygen quantum yield of BDPBr 2 , reflecting the outstanding ROS generation and phototoxicity of LBBr 2 NPs in Hep3B cells.…”

Section: Results and Discussionmentioning

confidence: 86%

pH-Responsive Pluronic F127–Lenvatinib-Encapsulated Halogenated Boron-Dipyrromethene Nanoparticles for Combined Photodynamic Therapy and Chemotherapy of Liver Cancer

et al. 2021

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Combination therapy such as photodynamic therapy (PDT)-enhanced chemotherapy is regarded as a promising strategy for cancer treatment. Boron-dipyrromethene (BODIPY), as close relatives of porphyrins, was widely used in PDT. However, poor water solubility, rapid metabolism by the body and lack of targeting limits its clinical application. Lenvatinib, as the first-line drug for molecular-targeted therapy of liver cancer, restricted its clinical application for its side effects. Herein, to achieve the synergy between PDT and chemotherapy, we synthesized two halogenated BODIPY, BDPBr 2 and BDPCl 2 , which were prepared into self-assembly nanoparticles with lenvatinib, and were encapsulated with Pluronic F127 through the nanoprecipitation method, namely, LBPNPs (LBBr 2 NPs and LBCl 2 NPs). The fluorescence quantum yields of LBPNPs were 0.73 and 0.71, respectively. The calculated loading rates of lenvatinib for LBBr 2 NPs and LBCl 2 NPs were 11.8 and 10.2%, respectively. LBPNPs can be hydrolyzed under weakly acidic conditions (pH 5.0) to generate reactive oxygen species (ROS), and the release rate of lenvatinib reached 88.5 and 82.4%. Additionally, LBPNPs can be effectively taken up by Hep3B and Huh7 liver cancer cells, releasing halogenated BODIPY and lenvatinib in the acidic environment of tumor cells to enhance the targeting performance of chemotherapeutics. Compared with free lenvatinib and separate halogenated BODIPY, LBPNPs can inhibit tumor growth more effectively through pH-responsive chemo/photodynamic synergistic therapy and significantly promote the cascade of caspase apoptotic protease. This study shows that LBPNPs can be a promising nanotheranostic agent for synergetic chemo/photodynamic liver cancer therapy.

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Section: Results and Discussionmentioning

confidence: 86%

pH-Responsive Pluronic F127–Lenvatinib-Encapsulated Halogenated Boron-Dipyrromethene Nanoparticles for Combined Photodynamic Therapy and Chemotherapy of Liver Cancer

et al. 2021

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“…Typically, the integration of intensive electron donor-acceptor (D-A) interaction into the conjugated structured chromophores could remarkably contribute to the bathochromic absorption/ emission and ROS generation on account of the reduced electronic bandgaps and promoted intersystem crossing (ISC) process. [34][35][36][37][38] In this work, as illustrated in Scheme 1, the designed compounds (TI, TSI, and TSSI) comprised by 1,3-bis(dicyanomethylidene)indane moiety (working as A), triphenylamine (TPA) unit (D), and/or thiophene segment (D and π-bridge), showed extremely strong D-A interaction and extended π-conjugation with varying degrees. In this design, TPA moiety is selected because it can not only serve as a strong electronic donor but also act as molecular rotors.…”

Section: To the Best Of The Knowledge There Have Been No Previous Rementioning

confidence: 99%

An All‐Round Athlete on the Track of Phototheranostics: Subtly Regulating the Balance between Radiative and Nonradiative Decays for Multimodal Imaging‐Guided Synergistic Therapy

et al. 2020

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Aiming to achieve versatile phototheranostics with the integrated functionalities of multiple diagnostic imaging and synergistic therapy, the optimum use of dissipated energy through both radiative and nonradiative pathways is definitely appealing, yet a significantly challenging task. To the best of the knowledge, there have been no previous reports on a single molecular species effective at affording all phototheranostic modalities including fluorescence imaging (FLI), photoacoustic imaging (PAI), photothermal imaging (PTI), photodynamic therapy (PDT), and photothermal therapy (PTT). Herein, a simple and highly powerful one‐for‐all phototheranostics based on aggregation‐induced emission (AIE)‐active fluorophores is tactfully designed and constructed. Thanks to its strong electron donor–acceptor interaction and finely modulated intramolecular motion, the AIE fluorophore‐based nanoparticles simultaneously exhibit bright near‐infrared II (NIR‐II) fluorescence emission, efficient reactive oxygen species generation, and high photothermal conversion efficiency upon NIR irradiation, indicating the actualization of a balance between radiative and nonradiative energy dissipations. Furthermore, the unprecedented performance on NIR‐II FLI‐PAI‐PTI trimodal‐imaging‐guided PDT–PTT synergistic therapy is demonstrated by the precise tumor diagnosis and complete tumor elimination outcomes. This study thus brings a new insight into the development of superior versatile phototheranostics for practical cancer theranostics.

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“…With the development of supramolecular technology, as shown in Table 1, some supramolecular nanomaterials have also attracted increasing attention for type I PDT. [ 10,11,66 ] For example, Gao et al. devised a O 2 •− photo‐generator (mTHPP‐PDPA) by assembling 5,10,15,20‐tetrakis(meso‐hydroxyphenyl) porphyrin (mTHPP) with electron‐rich polymer poly(ethylene glycol)‐ b ‐poly(2‐(diisopropylamino) ethyl methacrylate) (PEG‐ b ‐PDPA).…”

Section: Classification Of Type I Photosensitizersmentioning

confidence: 99%

“…[ 9 ] Nevertheless, most of these photosensitizers are based on type II mechanism in which 1 O 2 is generated to kill cancer cells. [ 10 ] As tumors grow in an exaggerated way, the O 2 ‐supply can hardly meet the metabolic requirements of proliferating tumor cells, leading to the hypoxic tumor microenvironment. [ 3 ] Emerging studies show the rather poor therapeutic efficacy of type II PDT for hypoxic cancer cell killing, owing to the oxygen‐dependent 1 O 2 production.…”

Section: Introductionmentioning

confidence: 99%

Type I Photosensitizers Revitalizing Photodynamic Oncotherapy

Chen

Wang

et al. 2021

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Photodynamic therapy (PDT) has shown great potential for tumor treatment with merits of non‐invasiveness, high selectivity, and minimal side effects. However, conventional type II PDT relying on 1O2 presents poor therapeutic efficacy for hypoxic tumors due to the oxygen‐dependent manner. Alternatively, emerging researches have demonstrated that type I PDT exhibits superiority over type II PDT in tumor treatment owing to its diminished oxygen‐dependence. In this review, state‐of‐the‐art studies concerning recent progress in type I photosensitizers are scrutinized, emphasizing the strategies to construct highly effective type I photosensitizers. As the foundation, basic principles of type I PDT are presented, and up‐to‐date type I photosensitizers are summarized and classified based on their attributes. Then, a literature review of representative type I photosensitizers (including nanomaterials and small molecules) is presented with impetus to delineate their novel designs, action mechanisms, as well as anticancer PDT applications. Finally, the remaining challenges and development directions of type I photosensitizers are outlined, highlighting key scientific issues toward clinical translations.

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Boosting O₂^•− Photogeneration via Promoting Intersystem‐Crossing and Electron‐Donating Efficiency of Aza‐BODIPY‐Based Nanoplatforms for Hypoxic‐Tumor Photodynamic Therapy

Cited by 91 publications

References 37 publications

pH-Responsive Pluronic F127–Lenvatinib-Encapsulated Halogenated Boron-Dipyrromethene Nanoparticles for Combined Photodynamic Therapy and Chemotherapy of Liver Cancer

pH-Responsive Pluronic F127–Lenvatinib-Encapsulated Halogenated Boron-Dipyrromethene Nanoparticles for Combined Photodynamic Therapy and Chemotherapy of Liver Cancer

An All‐Round Athlete on the Track of Phototheranostics: Subtly Regulating the Balance between Radiative and Nonradiative Decays for Multimodal Imaging‐Guided Synergistic Therapy

Type I Photosensitizers Revitalizing Photodynamic Oncotherapy

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Boosting O2•− Photogeneration via Promoting Intersystem‐Crossing and Electron‐Donating Efficiency of Aza‐BODIPY‐Based Nanoplatforms for Hypoxic‐Tumor Photodynamic Therapy

Cited by 91 publications

References 37 publications

pH-Responsive Pluronic F127–Lenvatinib-Encapsulated Halogenated Boron-Dipyrromethene Nanoparticles for Combined Photodynamic Therapy and Chemotherapy of Liver Cancer

pH-Responsive Pluronic F127–Lenvatinib-Encapsulated Halogenated Boron-Dipyrromethene Nanoparticles for Combined Photodynamic Therapy and Chemotherapy of Liver Cancer

An All‐Round Athlete on the Track of Phototheranostics: Subtly Regulating the Balance between Radiative and Nonradiative Decays for Multimodal Imaging‐Guided Synergistic Therapy

Type I Photosensitizers Revitalizing Photodynamic Oncotherapy

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Boosting O₂^•− Photogeneration via Promoting Intersystem‐Crossing and Electron‐Donating Efficiency of Aza‐BODIPY‐Based Nanoplatforms for Hypoxic‐Tumor Photodynamic Therapy