Yunxia Wu

The recent prevalence of monkeypox has led to the declaration of a Public Health Emergency of International Concern. Monkeypox lesions are typically ulcers or pustules (containing high titers of replication-competent virus) in the skin and mucous membranes, which allow monkeypox virus to transmit predominantly through intimate contact. Currently, effective clinical treatments for monkeypox are lacking, and strategies for blocking virus transmission are fraught with drawbacks. Herein, this work constructs a biomimetic nanotemplate (termed TBD@M NPs) with macrophage membranes as the coat and polymeric nanoparticles loading a versatile aggregation-induced emission featured photothermal molecule TPE-BT-DPTQ as the core. In a surrogate mouse model of monkeypox (vaccinia-virus-infected tail scarification model), intravenously injected TBD@M NPs show precise tracking and near-infrared region II fluorescence imaging of the lesions. Upon 808 nm laser irradiation, the virus is eliminated by the photothermal effect and the infected wound heals rapidly. More importantly, the inoculation of treated lesion tissue suspensions does not trigger tail infection or inflammatory activation in healthy mice, indicating successful blockage of virus transmission. This study demonstrates for the first time monkeypox theranostics using nanomedicine, and may bring a new insight into the development of a viable strategy for monkeypox management in clinical trials.

MicroRNAs (miRNAs) participate in important processes of life course. Because of their characters of small sizes, vulnerable degradabilities, and sequences similarities, the existing detection technologies mostly contain enzymatic amplification reactions for acquisition of high sensitivities and specificities. However, specific reaction conditions and time-dependent enzyme activities are caused by the accession of enzymes. Herein, we designed a target-triggered enzyme-free amplification platform that is realized by circulatory interactions of two hairpin probes and the integrated electrochemiluminescence (ECL) signal giving-out component. Benefiting from outstanding performances of the enzyme-free amplification system and ECL, this strategy is provided with a simplified reaction process, high sensitivity, and operation under isothermal conditions. Through detection of the miRNA standard substance, the sensitivity of this platform reached 10 fmol, and a splendid specificity was achieved. We also analyzed three tumor cell lines (human lung adenocarcinoma, breast adenocarcinoma, and hepatocellular liver carcinoma cell lines) through this platform. The sensitivities of 10(3) cells, 10(4) cells, and 10(4) cells were, respectively, achieved. Furthermore, clinical tumor samples were tested, and 21 of 30 experimental samples gave out positive signals. Thus, this platform possesses potentials to be an innovation in miRNA detection methodology.

Zika virus (ZIKV) is a re-emerging flavivirus that leads to devastating consequences for fetal development. It is crucial to visualize the pathogenicity activities of ZIKV ranging from infection pathways to immunity processes, but the accurate labeling of ZIKV remains challenging due to the lack of a reliable labeling technique. We introduce the photo-activated bio-orthogonal cycloaddition to construct a fluorogenic probe for the labeling and visualizing of ZIKV. Via a simple UV photoirradiation, the fluorogenic probes could be effectively labeled on the ZIKV. We demonstrated that it can be used for investigating the interaction between ZIKV and diverse cells and avoiding the autofluorescence phenomenon in traditional immunofluorescence assay. Thus, this bioorthogonal-enabled labeling strategy can serve as a promising approach to monitor and understand the interaction between the ZIKV and host cells.