Yueqiang Zhu scite author profile

The intrinsic pathological microenvironment of tumor tissue enforces barriers to the passive diffusion of nanomedicine, which results in inefficient tumor penetration of drugs and unsatisfactory therapeutic efficacy. Various strategies have been developed to improve the tumor penetration of nanomedicine, but they mostly overcome the barriers separately at different steps in a passive diffusion process. Here, the development of a large polymeric nanocarrier, DA T-PPE D&F (≈180 nm), is reported, which comprises a flowable polyphosphoester core, ferrimagnetic nanocubes, and a tumor extracellular pH-sensitive transactivator of transcription (TAT). Compared with a polylactic acid-based nanocarrier with a rigid core, this deformable DA T-PPE D&F with a similar diameter exhibits efficient penetration into the deep tumor tissue under magnetic actuation and an enhanced reactivation rate of the pH esensitive TAT. Therefore, DA T-PPE D&F is able to efficiently deliver doxorubicin into most tumor cells in vivo, and the superior anticancer effect indicates the potential of DA T-PPE D&F as a universal, responsive, and active nanocarrier to deliver various hydrophobic drugs into the deep tumor tissue.

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On-demand PEGylation and dePEGylation of PLA-based nanocarriers via amphiphilic mPEG-TK-Ce6 for nanoenabled cancer chemotherapy

Zhu

Chen

Cao

et al. 2019

Theranostics

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Rationale: PEGylation of nanocarriers could extend blood circulation time and enhance tumor accumulation via the enhanced permeability and retention (EPR) effect. Unfortunately, the PEG moiety suppresses tumor cell internalization of nanocarriers, resulting in limited therapeutic efficiency (known as the PEG dilemma). Designing stimuli-responsive shell-detachable nanocarriers, which could detach the PEG corona from the nanocarriers in desired tumor tissues in response to the local environment, is an appealing approach to overcome the PEG dilemma, but nanocarrier applications are also limited by a lack of universal stimuli for PEG detachment.Methods: In this study, we synthesized red light-responsive, amphiphilic mPEG bridged to the photosensitizer Ce6 via a thioketal (TK) bond (mPEG-TK-Ce6), which was then used to achieve the PEGylation of polylactide (PLA)-based nanoparticles encapsulating the Pt(IV) prodrug. The therapeutic efficacy of the prepared nanoparticles was evaluated in vitro and in vivo.Results: We demonstrated that the amphiphilic mPEG-TK-Ce6 can realize the PEGylation of Pt(IV) prodrug-loaded PLA nanoparticles and consequently enhanced nanoparticle accumulation in tumor tissues. When the tumor tissues were subjected to 660 nm irradiation, reactive oxygen species (ROS) generated by Ce6 induced the rapid degradation of the adjacent TK bond, resulting in PEG detachment and enhanced tumor cell internalization. Therefore, mPEG-TK-Ce6 facilely achieved PEGylation and light-responsive dePEGylation of the nanocarrier for enhanced antitumor efficacy in nanomedicine.Conclusion: Such red light-responsive amphiphilic mPEG-TK-Ce6 facilely achieved PEGylation and dePEGylation of the nanocarrier, providing a facile strategy to overcome PEG dilemma.

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Microfluidic synthesis of manganese-alginate nanogels with self-supplying H2O2 capability for synergistic chemo/chemodynamic therapy and boosting anticancer immunity

Zhu

Chen

et al. 2022

Chemical Engineering Journal

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In Situ Programming of Nanovaccines for Lymph Node-Targeted Delivery and Cancer Immunotherapy

et al. 2022

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In situ cancer vaccines consisting of antigens and adjuvants are a promising cancer treatment modality; however, the convenient manufacture of vaccines in vivo and their efficient delivery to lymph nodes (LNs) remains a major challenge. Herein, we outline a facile approach to simultaneously achieve the in situ programming of vaccines via two synergetic nanomedicines, Tu-NPFN and Ln-NPR848. Tu-NPFN (∼100 nm) generated a large number of antigens under an alternating magnetic field, and Ln-NPR848 (∼35 nm) encapsulating adjuvant R848 captured a portion of generated antigens for the manufacture of nanovaccines in situ and LN-targeted delivery, which significantly promoted the uptake and maturation of dendritic cells to initiate potent anticancer immune responses. Notably, combined with an anti-CTLA4 antibody (aCTLA-4), this therapy completely eradicated distant tumors in some mice and exerted a long-term immune memory effect on tumor metastasis. This study provides a generalizable strategy for in situ cancer vaccination.

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A Magnetically Driven Amoeba‐Like Nanorobot for Whole‐Process Active Drug Transport

et al. 2023

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The passive diffusion performance of nanocarriers results in inefficient drug transport across multiple biological barriers and consequently cancer therapy failure. Here, a magnetically driven amoeba-like nanorobot (amNR) is presented for whole-process active drug transport. The amNR is actively extravasated from blood vessels and penetrated into deep tumor tissue through a magnetically driven deformation effect. Moreover, the acidic microenvironment of deep tumor tissue uncovers the masked targeting ligand of amNR to achieve active tumor cell uptake. Furthermore, the amNR rapidly releases the encapsulated doxorubicin (DOX) after alternating magnetic field application. The amNRs eventually deliver DOX into ≈92.3% of tumor cells and completely delay tumor growth with an inhibition rate of 96.1%. The deformable amNRs, with the assistance of magnetic field application, provide a facile strategy for whole-process active drug transport.

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Yueqiang Zhu

Magnetically Actuated Active Deep Tumor Penetration of Deformable Large Nanocarriers for Enhanced Cancer Therapy

On-demand PEGylation and dePEGylation of PLA-based nanocarriers via amphiphilic mPEG-TK-Ce6 for nanoenabled cancer chemotherapy

Microfluidic synthesis of manganese-alginate nanogels with self-supplying H2O2 capability for synergistic chemo/chemodynamic therapy and boosting anticancer immunity

In Situ Programming of Nanovaccines for Lymph Node-Targeted Delivery and Cancer Immunotherapy

A Magnetically Driven Amoeba‐Like Nanorobot for Whole‐Process Active Drug Transport

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