It is difficult to keep the balance of high quality and high yield for graphene quantum dots (GQDs). Because the quality is uncontrollable during cutting large 2D nanosheets to small 0D nanodots by top-down methods and the yield is low for GQDs with high quality obtained from bottom-up strategy. Here, aphanitic graphite (AG), a low-cost graphite contains a large amount of small graphite nanocrystals with size of about 10 nm is used as the precursor of graphene oxide quantum dots (GO-QDs) for the first time. GO-QDs with high yield and high quality were successfully obtained directly by liquid phase exfoliating AG without high strength cutting. The yield of these GO-QDs can reach up to 40 wt. %, much higher than that obtained from flake graphite (FG) precursor (less than 10 wt. %). The size of GO-QDs can be controlled in 2–10 nm. The average thickness of GO-QDs is about 3 nm, less than 3 layer of graphene sheet. Graphene quantum dots (GQDs) with different surface properties can be easily obtained by simple hydrothermal treatment of GO-QDs, which can be used as highly efficient fluorescent probe. Developing AG as precursor for GQDs offers a way to produce GQDs in a low-cost, highly effective and scalable manner.
Effective therapeutic strategies to precisely eradicate primary tumors with minimal side effects on normal tissue, inhibit metastases, and prevent tumor relapses, are the ultimate goals in the battle against cancer. We report a novel therapeutic strategy that combines adjuvant black phosphorus nanoparticle-based photoacoustic (PA) therapy with checkpoint-blockade immunotherapy. With the mitochondria targeting nanoparticle, PA therapy can achieve localized mechanical damage of mitochondria via PA cavitation and thus achieve precise eradication of the primary tumor. More importantly, PA therapy can generate tumor-associated antigens via the presence of the R848-containing nanoparticles as an adjuvant to promote strong antitumor immune responses. When combined with the checkpoint-blockade using anti-cytotoxic T-lymphocyte antigen-4, the generated immunological responses will further promote the infiltrating CD8 and CD4 T-cells to increase the CD8/Foxp3 T-cell ratio to inhibit the growth of distant tumors beyond the direct impact range of the PA therapy. Furthermore, the number of memory T cells detected in the spleen is increased, and these cells inhibit tumor recurrence. This proposed strategy offers precise eradication of the primary tumor and can induce long-term tumor-specific immunity.
Electronic Supplementary Material
Supplementary material is available for this article at 10.1007/s12274-020-3028-x and is accessible for authorized users.
Microwave-induced thermoacoustic imaging (MTAI), combining the advantages of the high contrast of microwave imaging and the high resolution of ultrasonic imaging, is a potential candidate for breast tumor detection. MTAI...
Abstract:In this review, we provide an overview of recent progress in nanocarbons with different dimensions as noble-metal-free co-catalysts for photocatalysts. We put emphasis on the interface engineering between nanocarbon co-catalysts and various semiconductor photocatalysts and the novel properties generating of nanocarbon co-catalysts, also including the synthesis and application of nanocarbon-based photocatalyst composites.
Ultrathin In4SnS8nanosheets with a thickness of only 3.8 nm exhibited fast adsorption–visible-light photocatalysis dual function for various organic dyes.
In situ image guidance is one of the key techniques for accurate diagnosis and treatment in clinical medicine. Conventional imaging techniques such as CT, MRI provide critical information for diagnosis and treatment planning, but are less practical due to either technical complexity or ionizing radiation-related safety. Microwave-pumped thermoacoustic imaging (MTAI) is a promising alternative to real-time bioimaging due to its deep imaging depth, high resolution and minimal biological hazards. More importantly, by mapping the distribution of microwave absorbers, this method can also provide a new perspective for noninvasively observing the anatomy and functional structure of the target. In this work, we introduce a concept of in situ MTAI guidance by combining MTAI and an accurate spatial definition of invasive apparatus used in potential procedures. By mounting tiny MTAI beacons on the apparatus, it is possible to accurately reconstruct the relative position of the device to the target tissue for either real time visual guidance or as the foundation for potential automated procedures. The image quality including its applicable depth and resolution, the accuracy of the device localization is analyzed and tested with simulated breast tumor to demonstrate the capacity of the proposed technique. With refined adaptation for potential applications, this technique may provide a novel approach for a broad range of medical and biological applications.
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