Facile synthesis of NiAl2O4/g-C3N4 composite for efficient photocatalytic degradation of tetracycline.

Designing high-efficiency photocatalysts responsive to visible light is important for the degradation of antibiotics in water. Heterojunction engineering is undoubtedly an effective strategy to improve the photocatalytic performance. In this work, spinel-type metal oxides (NiAl2O4, NAO) are synthesized by a simple sol-gel and calcination process. After compounding graphitic carbon nitride (g-C3N4), NAO/g-C3N4 heterojunction is obtained, which then is used as the photocatalyst for tetracycline hydrochloride (TC). The effects of photocatalyst dosage, the initial concentration of TC, and solution pH on photodegradation performance are systematically studied. The removal rate of TC on NAO/g-C3N4 reach up to ∼90% after visible light irradiation for 2 hr and the degradation rate constant is ∼7 times, and ∼32 times higher than that of pure NAO and g-C3N4. The significantly improved photocatalytic activity can be attributed to the synergistic effect between well matched energy levels in NAO/g-C3N4 heterojunctions, improvement of interfacial charge transfer, and enhancement of visible light absorption. This study provides a way for the synthesis of efficient photocatalysts and an economic strategy for removing antibiotics contamination in water.

Parameter Selection for a Microvolume Electrochemical Escherichia coli Detector for Pairing with a Concentration Device.

Waterborne infections are responsible for health problems worldwide and their prompt and sensitive detection in recreational and potable water is of great importance. Bacterial identification and enumeration in water samples ensures water is safe for its intended use. Culture-based methods can be time consuming and are usually performed offsite. There is a need to for automated and distributed at-source detectors for water quality monitoring. Herein we demonstrate a microvolume Escherichia coli (E. coli) detector based on a screen printed electrode (SPE) bioelectroanalytical system and explore to what extent performance can be improved by coupling it with a filtration device. To confidently benchmark detector performance, we applied a statistical assessment method to target optimal detection of a simulated concentrated sample. Our aim was to arrive at a holistic understanding of device performance and to demonstrate system improvements based on these insights. The best achievable detection time for a simulated 1 CFU mL-1 sample was 4.3 (±0.6) h assuming no loss of performance in the filtration step. The real filtered samples fell short of this, extending detection time to 16-18 h. The loss in performance is likely to arise from stress imposed by the filtration step which inhibited microbial growth rates.

Heat shock mediated labelling of Pseudomonas aeruginosa with quantum dots.

Biocompatible nanoparticles are good candidates to label bacteria for imaging and diagnosis purposes. A high labeling efficiency reduces the concentration of nanoparticles required for labeling and allows the labeled bacteria to be tracked for longer periods. This report explores the optimal labeling strategy for Pseudomonas aeruginosa, a common gram-negative opportunistic pathogen, with quantum dots. Three strategies including direct incubation, calcium chloride treatment, and heat shock are compared and the labeling efficiency is assessed through fluorescence microscopy and flow cytometry analysis. Of the three, heat shock is finally selected due to its comparable labeling efficiency and simplicity. Through the assay of the respiration rate of bacteria together with morphology analysis, the heat shock process does not show any negative effect over the cells activity even at sub-toxic concentrations.

Sub-toxic concentrations of volatile organic compounds inhibit extracellular respiration of Escherichia coli cells grown in anodic bioelectrochemical systems.

Low-cost and rapid detection of volatile organic compounds (VOCs) is important for the control of water quality of used water and protection of downstream used water treatment processes. In this work, the effect of sub-toxic concentration of VOCs on the current output of Escherichia coli in bioelectrochemical systems (BES) is shown, in light of environmental sensing applications for sewage and used water networks. E. coli cells were grown on carbon felt electrodes in artificial used water, to increase sensitivity and decrease response time for detection. Extracellular electron transfer was promoted by the addition of a biocompatible redox mediator, 2-hydroxy-1,4-naphthoquinone (HNQ). Among the eight VOCs investigated, toluene is the most toxic to E. coli, with a detection limit of 50±2mgL(-1) and current output of 32±1nAmg(-1)L(-1). This work offers a straightforward route to enhance the detection of organic contaminants in used water for environmental applications.

Facile preparation of partially functionalized gold nanoparticles via a surfactant-assisted solid phase approach.

Herein, we report a versatile solid phase synthesis approach for partial functionalization of gold nanoparticles (AuNPs) via the assistance of surfactant. Hexadecyl trimethyl ammonium bromide (CTAB) is used as the bifunctional ligand to link the solid substrate and the AuNPs. This brings at least two advantages comparing to other bifunctional ligands: first, the thickness of the CTAB bilayer is flexible. During the "catch" process, the bilayer bound on different sites of the AuNPs could shrink or extend to a total thickness difference of ~2.5 nm, which protects a spherical cap of the AuNPs with the height of ~2.5 nm from chemical modification; second, after chemical modification, the "release" of the AuNPs from the substrate is quite simple. Not any second ligand, but only sonication is enough to release the AuNPs. As a result, the proposed approach produces partially functionalized AuNPs with a large surface area (80-95%) covered with unreactive ligands, while keeps the other small spatially limited region of the surface unmodified. This small unmodified surface can be directly used for further chemistry. Finally, the partially modified AuNPs is demonstrated for a one-step synthesis of AuNP dimers.