Fluidic Spatial-Confinement Scaffold Affords a Multicomponent DNA Reaction with Improved Efficiency and Accelerated Kinetics.

Enzyme-free nucleic acid amplification reactions with the capability of signal catalytic amplification have been widely used in biosensors. However, these multicomponent, multistep nucleic acid amplification systems often suffer from low reaction efficiency and kinetics. Herein, inspired by the natural cell membrane system, we utilized the red blood cell membrane as a fluidic spatial-confinement scaffold to construct a novel accelerated reaction platform. By simply modifying with cholesterol, DNA components can be efficiently integrated into the red blood cell membrane through hydrophobic interactions, which greatly increases the local concentration of DNA strands. Moreover, the fluidity of the erythrocyte membrane improves the collision efficiency of DNA components in the amplification system. Based on the increased local concentration and improved collision efficiency, the fluidic spatial-confinement scaffold significantly improved the reaction efficiency and kinetics. Taking catalytic hairpin assembly (CHA) as a model reaction, an RBC-CHA probe based on the erythrocyte membrane platform enables a more sensitive detection of miR-21 with a sensitivity that is 2 orders of magnitude higher than the free CHA probe and a fast reaction rate (about 3.3-fold). The proposed strategy provides a new idea for the construction of a novel spatial-confinement accelerated DNA reaction platform.

Activatable Magnetic/Photoacoustic Nanoplatform for Redox-Unlocked Deep-Tissue Molecular Imaging In Vivo via Prussian Blue Nanoprobe.

Drug-induced hepatic damage has drawn great attention on public health problems. Drugs are biotransformed in the liver by enzymatic processes, accompanied by the production of reactive free radicals, which is the main cause of drug-induced hepatotoxicity. However, the limited penetration of optics makes the use of current luminescence imaging more difficult for acquiring free radicals mapping for lesion location, when applied to whole-body imaging in vivo. In this work, we develop an activatable nanoprobe based on Prussian blue (PB) that can combine magnetic resonance imaging (MRI) and photoacoustic imaging (PAI) for deep-tissue ONOO- imaging. We discover that ONOO- can oxidize FeII within PB into FeIII and meanwhile destroy the crystal structure of PB so that the strong absorption of PB at 710 nm that originated from the electron transferring between FeII and FeIII is greatly diminished. As a result, the reduced photoacoustic imaging (PA) signal of PB is able to function as an indicator for sensing ONOO-. Importantly, after reaction with ONOO-, the reduced size of PB results in the decrease of rotational correlation time (τR), leading to the activatable MRI signal for sensing ONOO-. Finally, we demonstrate that the PB nanoprobe is successfully able to image the variation of ONOO- in drug-induced hepatotoxicity in vivo by PAI and MRI bimodal imaging. Notably, the complementarity of such dual-modality imaging could not only endow our probes with better accuracy and higher penetration depth for visualizing of ONOO- in drug-induced liver injury but also provide anatomical structure to identify the injury area of livers.

Efficient and Reliable MicroRNA Imaging in Living Cells via a FRET-Based Localized Hairpin-DNA Cascade Amplifier.

MicroRNAs (miRNAs) play critical roles in many biological processes and are vital biomarkers for disease diagnostics. Hence, it is of significance to develop miRNA biosensors with fast responses, high sensitivity, and excellent reliability in living cells. As one kind of DNA molecular machine, DNA amplifiers are very promising for intracellular miRNA imaging due to their nonenzymatic, isothermal working principle and excellent signal-amplification ability. However, the practical application of current DNA amplifiers is still an issue because of their slow kinetics, unsatisfactory efficiency, and false-positive signals. Herein, taking advantage of the spatial-confinement effect on a three-dimensional (3D) finite DNA nanostructure, a FRET-based localized hairpin-DNA cascade amplifier (termed as localized-HDCA) is developed for the rapid, efficient, and reliable imaging of intracellular tumor-related miRNA. The localized-HDCA system consists of two metastable hairpin DNAs (H1 and H2) localized on a DNA nanocube. Benefiting from the spatial-confinement effect in the confined space of DNA nanocubes, not only was the speed of the miRNA-triggered HDCA reaction significantly accelerated (7 times faster), but also the reaction efficiency was greatly improved (2.6 times higher). In addition, the FRET-based 3D finite DNA nanocubes provide this localized-HDCA with improved cell permeability and better nuclease resistance as well as the ability to avoid false-positive signals, which guarantee reliable miRNA imaging in living cells. With these advantages, this strategy is expected to be widely applied to the development of more efficient and robust DNA molecular machines for biomedical research and clinical diagnosis.

In Situ Localization of Enzyme Activity in Live Cells by a Molecular Probe Releasing a Precipitating Fluorochrome.

Current enzyme-responsive, fluorogenic probes fail to provide in situ information because the released fluorophores tend to diffuse away from the reaction sites. The problem of diffusive signal dilution can be addressed by designing a probe that upon enzyme conversion releases a fluorophore that precipitates. An excited-state intramolecular proton transfer (ESIPT)-based solid-state fluorophore HTPQ was developed that is strictly insoluble in water and emits intense fluorescence in the solid state, with λex/em =410/550 nm, thus making it far better suited to use with a commercial confocal microscope. HTPQ was further utilized in the design of an enzyme-responsive, fluorogenic probe (HTPQA), targeting alkaline phosphatase (ALP) as a model enzyme. HTPQA makes possible diffusion-resistant in situ detection of endogenous ALP in live cells. It was also employed in the visualizing of different levels of ALP in osteosarcoma cells and tissue, thus demonstrating its interest for the diagnosis of this type of cancer.

Research on the Influence of AI and VR Technology for Students' Concentration and Creativity.

The application of digital technology in teaching has triggered the evolution of traditional teaching. Students have different corresponding relationships under digital behavior. The interactive technology of artificial intelligence (AI) and virtual reality (VR) provides a new driving force for the development of art education and psychology. Firstly, this thesis analyzes the limitations and existing problems of traditional art education. Especially, the influence of the teaching mode of art education on the teaching of other disciplines develops a targeted student-centered digital education program. Secondly, the author used VR equipment and technology to let students experience the virtual world freely, and then, the relevant data model was established on the basis of analyzing the reasons affecting students' creativity and concentration. Thirdly, the data model was applied to art education in order to improve students' concentration and creativity. Then, the author compared and analyzed the data of the students under different teaching models through questionnaires. The results show that introducing VR and AI technology into art education and encouraging students to carry out deep learning can significantly improve student concentration and creativity. Finally, the influence reasons are analyzed from the perspective of psychology. VR interaction and Artificial Intelligence can be introduced into middle school fine art education which is to the benefit of students' deep learning, thus students' concentration and creativity can be improved.

Hybridization chain reaction-based nanoprobe for cancer cell recognition and amplified photodynamic therapy.

Precision diagnosis and effective treatment are the cores of early cancer therapy. Here, for the first time, we report a hybridization chain reaction-based nanoprobe for selective and sensitive cancer cell recognition and amplified photodynamic therapy.

Two-dimensional graphitic carbon nitride nanosheets for biosensing applications.

Two-dimensional graphitic carbon nitride nanosheets (CNNSs) with planar graphene-like structure have stimulated increasingly research interest in recent years due to their unique physicochemical properties. CNNSs possess superior stability, high fluorescence quantum yield, low-toxicity, excellent biocompatibility, unique electroluminescent and photoelectrochemical properties, which make them appropriate candidates for biosensing. In this review, we first introduce the preparation and unique properties of CNNSs, with emphasis on their superior properties for biosensing. Then, recent advances of CNNSs in photoelectrochemical biosensing, electrochemiluminescence biosensing and fluorescence biosensing are highlighted. An additional attention is paid to the marriage of CNNSs and nucleic acids, which exhibits great potentials in both biosensing and intracellular imaging. Finally, current challenges and opportunities of this 2D material are outlined. Inspired by the unique properties of CNNSs and their advantages in biological applications, we expect that more attention will be drawn to this promising 2D material and extensive applications can be found in bioanalysis and diseases diagnosis.

In vivo imaging of alkaline phosphatase in tumor-bearing mouse model by a promising near-infrared fluorescent probe.

Alkaline phosphatase (ALP), one of the important hydrolases, is associated with the progress of many diseases as a well-defined biomarker. Fluorescence imaging of ALP in living organisms is of great importance for biological studies. However, in vivo detection of ALP remains a great challenge because current fluorescent probes show short excitation and emission wavelength, which are not desired for in vivo fluorescence imaging. Herein we reported a near-infrared (NIR) fluorescent probe (NALP) for turn-on trapping of ALP activity in living cancer cells and tumors. NALP was composed of a NIR-emitting fluorophore as a reporter and phosphate as a triggered moiety. Phosphate group was directly tethered to the hydroxyl group of fluorophore, which prohibited the fluorescence. The probe exhibited a high selectivity and remarkable fluorescence turn-on response to ALP in aqueous solutions with a detection limit of 0.28U/L. Benefiting from NIR excitation and emission, high contrast on the imaging signal could be achieved in response to endogenous ALP activity. Impressively, not only we successfully used NALP for imaging of endogenous ALP activity in cancer cells, but also, applied it for fluorescence imaging of ALP in tumor tissues and living tumor xenograft in nude mice for the first time. The probe was expected to be promising tool for practical application in disease diagnosis on the roles of ALP in disease.

A mitochondrial-targeted prodrug for NIR imaging guided and synergetic NIR photodynamic-chemo cancer therapy.

Nontoxic prodrugs, especially activated by tumor microenvironment, are urgently required for reducing the side effects of cancer therapy. And combination of chemo-photodynamic therapy prodrugs show effectively synergetic therapeutic efficiency, however, this goal has not been achieved in a single molecule. In this work, we developed a mitochondrial-targeted prodrug PNPS for near infrared (NIR) fluorescence imaging guided and synergetic chemo-photodynamic precise cancer therapy for the first time. PNPS contains a NIR photosensitizer (NPS) and an anticancer drug 5'-deoxy-5-fluorouridine (5'-DFUR). These two parts are linked and caged through a bisboronate group, displaying no fluorescence and very low cytotoxicity. In the presence of H2O2, the bisboronate group is broken, resulting in activation of NPS for NIR photodynamic therapy and activation of 5'-DFUR for chemotherapy. The activated NPS can also provide a NIR fluorescence signal for monitoring the release of activated drug. Taking advantage of the high H2O2 concentration in cancer cells, PNPS exhibits higher cytotoxicity to cancer cells than normal cells, resulting in lower side effects. In addition, based on its mitochondrial-targeted ability, PNPS exhibits enhanced chemotherapy efficiency compare to free 5'-DFUR. It also demonstrated a remarkably improved and synergistic chemo-photodynamic therapeutic effect for cancer cells. Moreover, PNPS exhibits excellent tumor microenvironment-activated performance when intravenously injected into tumor-bearing nude mice, as demonstrated by in vivo fluorescence imaging. Thus, PNPS is a promising prodrug for cancer therapy based on its tumor microenvironment-activated drug release, synergistic therapeutic effect and "turn-on" NIR imaging guide.

A membrane-anchored fluorescent probe for detecting K(+) in the cell microenvironment.

Cell-surface fluorescent probes are effective tools in cell biology and engineering. Here, we for the first time report a diacyllipid-aptamer conjugate-based fluorescent probe which could anchor on cell membrane for real-time tracking of potassium ions in the cell microenvironment.

Chemometrics-enhanced high performance liquid chromatography-diode array detection strategy for simultaneous determination of eight co-eluted compounds in ten kinds of Chinese teas using second-order calibration method based on alternating trilinear decomposition algorithm.

In this work, an attractive chemometrics-enhanced high performance liquid chromatography-diode array detection (HPLC-DAD) strategy was proposed for simultaneous and fast determination of eight co-eluted compounds including gallic acid, caffeine and six catechins in ten kinds of Chinese teas by using second-order calibration method based on alternating trilinear decomposition (ATLD) algorithm. This new strategy proved to be a useful tool for handling the co-eluted peaks, uncalibrated interferences and baseline drifts existing in the process of chromatographic separation, which benefited from the "second-order advantages", making the determination of gallic acid, caffeine and six catechins in tea infusions within 8 min under a simple mobile phase condition. The average recoveries of the analytes on two selected tea samples ranged from 91.7 to 103.1% with standard deviations (SD) ranged from 1.9 to 11.9%. Figures of merit including sensitivity (SEN), selectivity (SEL), root-mean-square error of prediction (RMSEP) and limit of detection (LOD) have been calculated to validate the accuracy of the proposed method. To further confirm the reliability of the method, a multiple reaction monitoring (MRM) method based on LC-MS/MS was employed for comparison and the obtained results of both methods were consistent with each other. Furthermore, as a universal strategy, this new proposed analytical method was applied for the determination of gallic acid, caffeine and catechins in several other kinds of Chinese teas, including different levels and varieties. Finally, based on the quantitative results, principal component analysis (PCA) was used to conduct a cluster analysis for these Chinese teas. The green tea, Oolong tea and Pu-erh raw tea samples were classified successfully. All results demonstrated that the proposed method is accurate, sensitive, fast, universal and ideal for the rapid, routine analysis and discrimination of gallic acid, caffeine and catechins in Chinese tea samples.