Jingfang Shangguan

Rapid and ultrasensitive Salmonella Typhimurium quantification using positive dielectrophoresis driven on-line enrichment and fluorescent nanoparticleslabel

This paper describes a convenient and sensitive methodology for Salmonella Typhimurium (S. Typhimurium) detection in microfluidic channels using positive dielectrophoresis (pDEP) driven on-line enrichment and fluorescent nanoparticles label. In the protocol, S. Typhimurium was first incubated with the anti-S. Typhimurium antibody conjugated RuBpy-doped fluorescent nanoparticles (Ab(S. Typhimurium)-FNPs). After incubation, the reacted mixture of S. Typhimurium and Ab(S. Typhimurium)-FNPs bioconjugates was directly introduced into the pDEP-based microfluidic system. On applying an AC voltage to the electrodes in a pDEP frequency region, the FNPs labeled S. Typhimurium cells moved to the electrodes and accumulated in the electrode gap, while the free Ab(S. Typhimurium)-FNPs were flowed away. The enriched FNPs labeled S. Typhimurium were detected by fluorescence microscopy at the focused detection areas. This new method constructed a simultaneous on-line enrichment and detection platform, eliminated the separation and washing-out steps usually required for FNPs label involved bioassay. Utilizing signal amplification effects produced by pDEP on-line enrichment and FNPs label, the detection limit for S. Typhimurium in deionized water is 56 colony forming units per milliliter (cfu/mL). We applied the established approach to detecting artificially contaminated bottled mineral water samples; S. Typhimurium of 110 cfu/mL was accurately detected. It is believed that the proposed method will find wide applications in biomedicine fields demanding higher sensitive bacterial identification.

Synthesis of Hollow Mesoporous Silica Nanorods with Controllable Aspect Ratios for Intracellular Triggered Drug Release in Cancer Cells

Here, we have reported a straightforward and effective synthetic strategy for synthesis of aspect-ratios-controllable mesoporous silica nanorods with hollow structure (hMSR) and its application for transcription factor (TF)-responsive drug delivery intracellular. Templating by an acid-degradable nickel hydrazine nanorods (NHNT), we have first synthesized the hollow dense silica nanorods and then coated on a mesoporous silica layer. Subsequently, the dense silica layer was removed by the surface-protected etching method and the hollow structure of hMSR was finally formed. The aspect ratios of the hMSR can be conveniently controlled by regulating the aspect ratios of NHNT. Four different hMSR with aspect ratios of ca. 2.5, ca. 5.3, ca. 8.1, and ca. 9.0 has been obtained. It was demonstrated that the as-prepared hMSRs have good stability, high drug loading capacity, and fast cell uptake capability, which makes them to a potential nanocarrier for drug delivery. As the paradigm, hMSR with an aspect ratio of ca. 8.1 was then applied for TF-responsive intracellular anticancer drug controlled release by using a Ag(+)-stabilized molecular switch of triplex DNA (TDNA) as capping agents and probes for TFs recognition. In the presence of TF, the pores of hMSR can be unlocked by the TFs induced disassembly of TDNA, leading to the leakage of DOX. The research in vitro displayed that this system has a TFs-triggered DOX release, and the cytotoxicity in L02 normal cells was lower than that of HeLa cells. We hope that this developed hMSR-based system will promote the development of cancer therapy in related fields.

Dumbbell DNA-templated CuNPs as a nano-fluorescent probe for detection of enzymes involved in ligase-mediated DNA repair

DNA repair processes are responsible for maintaining genome stability. Ligase and polynucleotide kinase (PNK) have important roles in ligase-mediated DNA repair. The development of analytical methods to monitor these enzymes involved in DNA repair pathways is of great interest in biochemistry and biotechnology. In this work, we reported a new strategy for label-free monitoring PNK and ligase activity by using dumbbell-shaped DNA templated copper nanoparticles (CuNPs). In the presence of PNK and ligase, the dumbbell-shaped DNA probe (DP) was locked and could resist the digestion of exonucleases and then served as an efficient template for synthesizing fluorescent CuNPs. However, in the absence of ligase or PNK, the nicked DP could be digested by exonucleases and failed to template fluorescent CuNPs. Therefore, the fluorescence changes of CuNPs could be used to evaluate these enzymes activity. Under the optimal conditions, highly sensitive detection of ligase activity of about 1U/mL and PNK activity down to 0.05U/mL is achieved. To challenge the practical application capability of this strategy, the detection of analyte in dilute cells extracts was also investigated and showed similar linear relationships. In addition to ligase and PNK, this sensing strategy was also extended to the detection of phosphatase, which illustrates the versatility of this strategy.

Polyvalent and Thermosensitive DNA Nanoensembles for Cancer Cell Detection and Manipulation

Development of smart DNA nanostructures is of great value in cancer studies. Here, by integrating rolling circle amplification (RCA) into split aptamer design, a novel strategy of polyvalent and thermosensitive DNA nanoensembles was first proposed for cancer cell detection and manipulation. In this strategy, a long nanosolo ssDNA with repeated Split-b and Poly T regions was generated through RCA. Split-b supplied polyvalent binding sites while Poly T supported signal output by hybridizing with fluorophore-labeled poly A. After addition of Split-a, nanoensembles formed on the cell surface due to target-induced assembly of Split-a/Split-b from the free state to the recognition structure, and on the basis of the thermosensitivity of split aptamer, nanoensembles were controlled reversibly by changing temperatures. As proof of concept, split ZY11 against SMMC-7721 cancer was used to construct nanoensembles. Compared with monovalent split aptamer, nanoensembles were demonstrated to have a much stronger interaction with target cells, thus realizing an ∼2.8-time increase in signal-to-background ratio (SBR). Moreover, nanoensembles extended the tolerance range of target binding from 4 °C to room temperature and speeded recognition thus achieving almost 50% binding in 1 min. Then, nanoensembles were successfully applied to detect 7721 cells in serum and mixed cell samples. By utilizing microplate well surface as the model, temperature-controlled catch/release of target cells was also realized with nanoensembles, even under unfriendly conditions for monovalent split aptamer. The RCA-mediated aptameric nanoensembles strategy not only solved the problem of split aptamer in inefficient binding but also paved a brand new way for developing polyvalent and intelligent nanomaterials.

Nucleic acid tool enzymes-aided signal amplification strategy for biochemical analysis: status and challenges

AbstractOwing to their highly efficient catalytic effects and substrate specificity, the nucleic acid tool enzymes are applied as ‘nano-tools’ for manipulating different nucleic acid substrates both in the test-tube and in living organisms. In addition to the function as molecular scissors and molecular glue in genetic engineering, the application of nucleic acid tool enzymes in biochemical analysis has also been extensively developed in the past few decades. Used as amplifying labels for biorecognition events, the nucleic acid tool enzymes are mainly applied in nucleic acids amplification sensing, as well as the amplification sensing of biorelated variations of nucleic acids. With the introduction of aptamers, which can bind different target molecules, the nucleic acid tool enzymes-aided signal amplification strategies can also be used to sense non-nucleic targets (e.g., ions, small molecules, proteins, and cells). This review describes and discusses the amplification strategies of nucleic acid tool enzymes-aided biosensors for biochemical analysis applications. Various analytes, including nucleic acids, ions, small molecules, proteins, and cells, are reviewed briefly. This work also addresses the future trends and outlooks for signal amplification in nucleic acid tool enzymes-aided biosensors. Graphical abstractNucleic acid tool enzymes-aided signal amplification sensing

Facile fabrication of a resveratrol loaded phospholipid@reduced graphene oxide nanoassembly for targeted and near-infrared laser-triggered chemo/photothermal synergistic therapy of cancer in vivo

Resveratrol (Res) has emerged as an extremely promising natural molecule due to its vast therapeutic prospects. However, the potential of the drug is immensely hindered by several limiting factors including poor water solubility, limited chemical stability and high metabolization. Herein we report a facile synthesis of a Res-loaded folate-terminated PEG-phospholipid coated reduced graphene oxide nanoassembly (FA-PEG-Lip@rGO/Res) by simply sonicating Res and rGO in FA-PEG linked liposome (FA-PEG-liposome) suspensions. The as-obtained FA-PEG-Lip@rGO/Res exhibits a nanoscale size (148 ± 7 nm), a negative surface potential (-23.6 mV), an excellent drug loading (69.5 ± 4.3%), a high drug entrapment efficiency (86.9 ± 5.6%), good monodispersity and controlled release. Additionally, the nanoassembly can protect Res from UV-light induced instability. Owing to the folate mediated targeted delivery, the robust FA-PEG-Lip@rGO/Res can deliver loaded Res to human MCF-7 breast cancer cells with high specificity and excellent efficiency. The cell toxicity viability shows that unloaded FA-PEG-Lip@rGO has no cytotoxicity, confirming its suitability as a drug vehicle. Furthermore, a systematic in vivo study shows that, under near-infrared (NIR) laser irradiation, FA-PEG-Lip@rGO/Res exhibits highly efficient combined chemotherapy and photothermal therapy to eradicate xenografted tumor with a single dose intratumoral (i.t.) injection. Thus, a facile, stable, biocompatible, and highly-effective Res delivery system has been developed, which may greatly advance the application of Res in biomedical research.