X‐ray‐Controlled Bilayer Permeability of Bionic Nanocapsules Stabilized by Nucleobase Pairing Interactions for Pulsatile Drug Delivery

Deng, Hongzhang; Lin, Lisen; Wang, Sheng; Yu, Guocan; Zhou, Zijian; Liu, Yijing; Niu, Gang; Song, Jibin; Chen, Xiaoyuan

doi:10.1002/adma.201903443

Cited by 56 publications

(59 citation statements)

References 56 publications

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“…When analyzing the D-Exos/miR21i-L17E, the co-localization ratio of cargos to endosome was relatively low, suggesting that Dox and RNA began to escape from the endosome under L17E triggering. As the incubation time increased, the Dox in both groups gradually entered the nucleus, because small molecules could cross the biological membrane through a passive diffusion mechanism 50 . As cellular uptake time increased, the internalized miR-21i molecules of D-Exos/miR21i treatment group gradually dispersed into cytosol, but were still partially entrapped in endosomes.…”

Section: Resultsmentioning

confidence: 99%

Engineering blood exosomes for tumor-targeting efficient gene/chemo combination therapy

Zhan

et al. 2020

Theranostics

116

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Rationale: Developing an effective nanoplatform to realize 'multi-in-one' is essential to broaden the therapeutic potential of combination therapy. Exosomes are ideal candidates since their intrinsic abilities of integrating multiple contents and functions. However, only limited efforts have been devoted to engineering exosomes to integrate the needed properties, also considering the safety and yield, for tumor-targeted and efficient gene/chemo combination therapy. Methods: Herein, by manipulating the exosome membrane, blood exosomes with high abundance and safety are engineered as a versatile combinatorial delivery system, where the doxorubicin (Dox) and cholesterol-modified miRNA21 inhibitor (miR-21i) are co-embedded into the lipid bilayer of exosomes, and the magnetic molecules and endosomolytic peptides L17E are bind to the exosome membrane through ligand-receptor coupling and electrostatic interactions, respectively. Results: It is proved that such engineering strategy not only preserves their intrinsic features, but also readily integrates multiple properties of tumor targeting, efficient transfection and gene/chemo combination therapy into blood exosomes. The lipid bilayer structure of exosomes allows them to co-load Dox and miR-21i with high-payloads. Moreover, profiting from the integration of magnetic molecules and L17E peptides, the engineered exosomes exhibit an enhanced tumor accumulation and an improved endosome escape ability, thereby specifically and efficiently delivering encapsulated cargos to tumor cells. As a result, a remarkable inhibition of tumor growth is observed in the tumor-bearing mice, and without noticeable side effects. Conclusions: This study demonstrates the potential of engineered blood exosomes as feasible co-delivery nanosystem for tumor-targeted and efficient combination therapy. Further development by replacing the drugs combined regimens can potentially make this engineered exosome become a general platform for the design of safe and effective combination therapy modality.

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Section: Resultsmentioning

confidence: 99%

Engineering blood exosomes for tumor-targeting efficient gene/chemo combination therapy

Zhan

et al. 2020

Theranostics

116

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“…Subsequently, in vivo anti-tumor therapeutic effect of FBC nanogels was studied. When the volume of tumor xenograft in mice reached 100 mm 3 , the mice and FBC-200+L groups were treated with 750 nm laser irradiation (200 mW/cm 2 ) for 10 min, respectively. In the period of treatment, body weights of the mice and the volumes of the tumors were recorded every three days ( Fig.…”

Section: Resultsmentioning

confidence: 99%

“…However, the clinical utility of PDT is greatly limited by the inadequate NIR absorption, oxygen dependence and poor stability of conventional photosensitizers (PSs) such as photofin, verteporfin and padeliporfin. The short wavelength light absorbed by PSs cannot reach the deep tissue due to absorption of the skin and subcutaneous adipose tissue, resulting in lower photoconversion, serious tissue damage and the limited clinical application of PDT in deep tumors 3 . To address this issue, some strategies such as two-photon excitation (TPE) technique 4,5 and upconversion nanoparticles (UCNPs) 6,7 had been introduced for the therapy of deep tumors, but the complex equipment and the low conversion efficiency will bring about new problems for the clinic application 8,9 .…”

Section: Introductionmentioning

confidence: 99%

An ultra-stable bio-inspired bacteriochlorin analogue for hypoxia-tolerant photodynamic therapy

2021

Chem. Sci.

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“…[88] Themolecular structure of the related azo dyes has agreat effect on their reactivity towards COH. [89] Forinstance, the ortho isomer of Methyl red showed higher reactive sensitivity to COH than Methyl red and other derivatives because of the formation of internal H-bonding in the ortho Methyl red adduct. Significantly,t he azo bond is specifically broken by COH and not is not affected by other species.Onthe basis of the COH-mediated degradation of azo dyes,s everal luminescent COH nanoprobes have been developed and applied for both in vitro and in vivo detection of COH.…”

Section: Azo Dyesmentioning

confidence: 95%

Oxidative‐Species‐Selective Materials for Diagnostic and Therapeutic Applications

et al. 2020

Self Cite

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With the increasing recognition of the diverse roles and significance of oxidative species in the pathogenesis of many diseases, a tremendous amount of work on the development of oxidative‐species‐responsive materials has been conducted for 1) detecting oxygen metabolites or diagnosis of oxidative‐stress‐relevant diseases, 2) reducing oxidative stress in the disease sites, and/or 3) delivering therapeutic and diagnostic agents. In this review, we first discuss the distinct features and biological functions of each oxidative species. Then the selectivity and sensitivity of chemical linkers/groups to specific oxidative species and the underlying chemistry of their particular interactions are systematically elucidated. Their potential biomedical applications are also highlighted. We expect that this comprehensive review will provide more insights for the design and development of oxidative‐species‐selective materials for more effective diagnostic and therapeutic applications.

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X‐ray‐Controlled Bilayer Permeability of Bionic Nanocapsules Stabilized by Nucleobase Pairing Interactions for Pulsatile Drug Delivery

Cited by 56 publications

References 56 publications

Engineering blood exosomes for tumor-targeting efficient gene/chemo combination therapy

Engineering blood exosomes for tumor-targeting efficient gene/chemo combination therapy

An ultra-stable bio-inspired bacteriochlorin analogue for hypoxia-tolerant photodynamic therapy

Oxidative‐Species‐Selective Materials for Diagnostic and Therapeutic Applications

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