Chao Liu scite author profile

Antibiotic‐free methods hold particular promise for preventing and controlling multidrug‐resistant (MDR) bacterial infection via eradiation of bacteria and their pathogenic virulence. A facile and bioinspired strategy is presented for bridging antibacterial sonodynamic therapy and antivirulence immunotherapy. As a proof‐of‐concept, an antibody which neutralizes alpha‐toxin of methicillin‐resistant Staphylococcus aureus (MRSA) is genetically engineered on to the surface of cell membrane nanovesicles, which then undergo sonosensitizer encapsulation. Compared with conventional passive virulence absorption using natural red blood membrane, the highly active antibody–toxin interaction enables the nanovesicles to capture virulence more potently in vitro. Upon ultrasound activation, the sonosensitizers efficiently generate reactive oxygen species to kill bacteria and accelerate the virulence clearance. In vivo optical imaging shows that the antibody‐piloted nanocapturer can successfully locate MRSA infection and accurately distinguish the foci from sterile inflammation. In situ magnetic resonance imaging and oxyhemoglobin saturation detection visualize the treatment progression, revealing a complete sono‐immunotherapeutic eradication of MRSA myositis in mice. The first combination of antibacterial sonodynamic therapy and antivirulence immunotherapy, which promises a new way for antibiotic‐free nanotheranostics to robustly combat MDR bacterial infections, is presented.

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Genetically Engineered Cell Membrane Nanovesicles for Oncolytic Adenovirus Delivery: A Versatile Platform for Cancer Virotherapy

Liu

Chen

et al. 2019

Nano Lett.

138

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Currently, various oncolytic adenoviruses (OA) are being explored in both preclinical and clinical virotherapy. However, the pre-existing neutralizing antibodies (nAbs) and poor targeting delivery are major obstacles for systemically administered OA. Therefore, we designed bioengineered cell membrane nanovesicles (BCMNs) that harbor targeting ligands to achieve robust antiviral immune shielding and targeting capabilities for oncolytic virotherapy. We employed two distinct biomimetic synthetic approaches: the first is based on in vitro genetic membrane engineering to embed targeting ligands on the cell membrane, and the second is based on in vivo expression of CRISPR-engineered targeting ligands on red-blood-cell membranes. The results indicate that both bioengineering approaches preserve the infectivity and replication capacity of OA in the presence of nAbs, in vitro and in vivo. Notably, OA@BCMNs demonstrated a significant suppression of the induced innate and adaptive immune responses against OA. Enhanced targeting delivery, viral oncolysis, and survival benefits in multiple xenograft models were observed without overt toxicity. These findings reveal that OA@BCMNs may provide a clinical basis for improving oncolytic virotherapy by overcoming undesired antiviral immunity and enhancing cancer cell selectivity via biomimetic synthesis approaches.

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The response of the Beijing carbon emissions allowance price (BJC) to macroeconomic and energy price indices

et al. 2017

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Adaptive Jacobian vision based control for robots with uncertain depth information

2010

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Chao Liu

Sono‐Immunotherapeutic Nanocapturer to Combat Multidrug‐Resistant Bacterial Infections

Genetically Engineered Cell Membrane Nanovesicles for Oncolytic Adenovirus Delivery: A Versatile Platform for Cancer Virotherapy

The response of the Beijing carbon emissions allowance price (BJC) to macroeconomic and energy price indices

Adaptive Jacobian vision based control for robots with uncertain depth information

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