Here we demonstrate a novel and facile strategy of highly luminescent water-soluble Zn-doped AgIn5S8 (ZAIS) nanocrystals and ZAIS/ZnS core/shell structures, which were based on hydrothermal reaction between the acetate salts of the corresponding metals and sulfide precursor in the presence of l-cysteine at 110 °C in a Teflon-lined autoclave. The photoluminescent (PL) emission wavelength can be conveniently tuned from 560 to 650 nm by tailoring the stoichiometric ratio of [Ag]/[Zn]. The as prepared nanocrystals were characterized systematically and exhibit long PL lifetimes more than 100 ns. The influence of experimental conditions, including concentration of l-cysteine and reaction temperature, was investigated. In addition, we performed a coating procedure with the ZnS shell outside the ZAIS core and showed excellent PL quantum yields up to 35%. The in vitro experiment exhibited quite low cytotoxicity and marvelous biocompatibility, revealing their promising prospect in bioscience. Furthermore, the obtained ZAIS/ZnS nanocompounds (NCs) were covalently conjugated to alpha-fetoprotein antibodies and targeted fluorescent imaging for hepatocellular carcinoma cells was realized.
Crystalline (E)-4-fluoro-cinnamaldehyde malononitrile undergoes a [2+2] photocycloaddition, leading to a robust photomechanical response and improved force generation by nanowire ceramic composites.
Porous anodic aluminum oxide (AAO) membranes template the growth of photochromic crystalline nanowires. The resulting organic–inorganic composite can function as a photomechanical bending actuator. In order to investigate how the nanostructural properties of both the organic and inorganic components affect the photomechanical response, the composite mechanical properties are characterized using a variety of methods. There is a significant variation in both morphology and elastic modulus for two commercially available AAO templates with nominally identical pore diameters of 200 nm. After these templates are filled with diarylethene molecules that undergo a ring‐open to ring‐closed photoisomerization, the light‐generated curvature and mechanical work are evaluated using two different methods. The templates with a lower average elastic modulus (16 GPa vs 68 GPa) generate almost an order of magnitude more photomechanical work. The dependence of the photomechanical response on the chemical structure of the photochrome is assessed by comparing the performance of a diarylethene that undergoes a crystal expansion to that of one that undergoes a contraction, which leads to a decrease in curvature. Both the inorganic template and the organic active component play important roles in the overall photomechanical response, with substantial room to improve the performance.
Wastewater analysis of pathogens, particularly SARS-CoV-2,
is instrumental
in tracking and monitoring infectious diseases in a population. This
method can be used to generate early warnings regarding the onset
of an infectious disease and predict the associated infection trends.
Currently, wastewater analysis of SARS-CoV-2 is almost exclusively
performed using polymerase chain reaction for the amplification-based
detection of viral RNA at centralized laboratories. Despite the development
of several biosensing technologies offering point-of-care solutions
for analyzing SARS-CoV-2 in clinical samples, these remain elusive
for wastewater analysis due to the low levels of the virus and the
interference caused by the wastewater matrix. Herein, we integrate
an aptamer-based electrochemical chip with a filtration, purification,
and extraction (FPE) system for developing an alternate in-field solution
for wastewater analysis. The sensing chip employs a dimeric aptamer,
which is universally applicable to the wild-type, alpha, delta, and
omicron variants of SARS-CoV-2. We demonstrate that the aptamer is
stable in the wastewater matrix (diluted to 50%) and its binding affinity
is not significantly impacted. The sensing chip demonstrates a limit
of detection of 1000 copies/L (1 copy/mL), enabled by the amplification
provided by the FPE system. This allows the integrated system to detect
trace amounts of the virus in native wastewater and categorize the
amount of contamination into trace (<10 copies/mL), medium (10–1000
copies/mL), or high (>1000 copies/mL) levels, providing a viable
wastewater
analysis solution for in-field use.
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