RESUMO
A one-target-many-trigger signal model sensing strategy is proposed for quickly, sensitive and on-site detection of the environmental pollutant p-aminophenol (PAP) by use of a commercial personal glucose meter (PGM) for signal readout with the core-shell "loading-type" nanomaterial MSNs@MnO2 as amplifiable nanoprobes. In this design, the mesoporous silica nanoparticles (MSNs) nanocontainer with entrapped signal molecule glucose is coated with redoxable manganese dioxide (MnO2) nanosheets to form the amplifiable nanoprobes (Glu-MSNs@MnO2). When encountered with PAP, the redox reaction between the MnO2 and PAP can induce the degradation of the outer layer of MSNs@MnO2, liberating multiple copies of the loaded glucose to light up the PGM signal. Owing to the high loading capability of nanocarriers, a "one-to-many" relationship exists between the target and the signal molecule glucose, which can generate adequate signal outputs to achieve the requirement of on-site determination of environmental pollutants. Taking advantage of this amplification mode, the developed PAP assay owns a dynamic linear range of 10.0-400 µM with a detection limit of 2.78 µM and provides good practical application performance with above 96.7 ± 4.83% recovery in environmental water and soil samples. Therefore, the PGM-based amplifiable sensor for PAP proposed can accommodate these requirements of environment monitoring and has promising potential for evaluating pollutants in real environmental samples.
Assuntos
Aminofenóis , Nanoestruturas , Óxidos , Compostos de Manganês , Glucose , Dióxido de SilícioRESUMO
The leaves of Vernonia amygdalina Delile of the family Asteraceae(also known as "bitter leaf"), rich in biological activities, are used as both medicine and food for a long time in West tropical Africa. They have been introduced into Southeast Asia and Fujian and Guangdong provinces of China in recent years. However, little is known about the properties of the plant in traditional Chinese medicine(TCM), which limits its combination with other Chinese medicinal herbs. In this study, 473 articles on V. amygdalina leaves were selected from PubMed, Web of Science, CNKI, Wanfang Data and VIP to summarize their components, pharmacological effects and clinical research. V. amygdalina leaves presented anti-microbial, hypoglycemic, anti-hypertensive, lipid-lowering, anti-tumor, anti-inflammatory, antioxidant, and other pharmacological effects. On the basis of the theory of TCM properties, the leaves were inferred to be cold in property and bitter and sweet in flavor, acting on spleen, liver, stomach and large intestine and with the functions of clearing heat, drying dampness, purging fire, removing toxin, killing insects and preventing attack of malaria. They can be used to treat dampness-heat diarrhea, interior heat and diabetes, malaria, insect accumulation and eczema(5-10 g dry leaves by decoction per day and an appropriate amount of crushed fresh leaves applying to the affected area for external use). Due to the lack of TCM properties, V. amygdalina leaves are rarely used medicinally in China. The determination of medicinal properties of the leaves is conducive to the introduction of new exotic medicinal herbs and the development of new TCM resources, which facilitated further clinical application and research and development of Chinese medicinal herbs.
Assuntos
Plantas Medicinais , Vernonia , Antioxidantes , Medicina Tradicional Chinesa , Extratos Vegetais/farmacologia , Folhas de PlantaRESUMO
3-Fluorooxindole has been shown to be a biologically active structural unit, novel derivative containing 3-fluorooxindole unit has been successfully constructed using 3-fluorooxindole as a substrate in previous work. Here, the interactions between novel 3-fluorooxindole derivatives and ctDNA were explored through molecular docking, multi-spectral and NMR methods, and the dependence of the binding mechanism on the structure was revealed by combined physical chemistry and organic chemistry. Firstly, molecular docking indicated that the planarity of the molecule enhances the binding strength to ctDNA. UV absorption result showed a weak binding effect. Fluorescence spectroscopy suggested the binding mechanism of 3-fluorooxindoles and ctDNA via groove binding. Moreover, the binding mechanism of 3-fluorooxindoles to ctDNA was further confirmed by 1H NMR spectroscopy, viscometry, and CD spectroscopy as groove binding. FT-IR spectroscopy reflected a more obvious disturbance of the phosphate group in the groove region of ctDNA. Electrochemistry was also used to probe the binding strength of 3-fluorooxindoles to ctDNA, and it showed a weak binding strength. From the above study, we concluded that 3-fluorooxindoles bind mainly in the groove region of ctDNA with weak binding strength. This study provides an idea for the activity screening aspect of 3-fluorooxindole derivatives from molecular planarity consideration and relevant information on biophysical and bioorganic aspects for drug development.
Assuntos
DNA , DNA/química , Simulação de Acoplamento Molecular , Conformação de Ácido Nucleico , Oxindóis , Espectrometria de Fluorescência , Espectroscopia de Infravermelho com Transformada de Fourier , TermodinâmicaRESUMO
P-Aminophenol (PAP), a potentially toxic and mutagenic compound, is widely distributed in water and soil and has serious side effects on human health. This study presents a convenient, sensitive, and effective dual-signal assay for the detection of PAP in the environment. Two-dimensional manganese dioxide (MnO2) nanosheets were used as the carrier and quencher for fluorophore-labelled DNA to form a dual-signal nanoprobe, MnO2-DNA. Based on a specific redox reaction between the MnO2 nanosheets and target PAP, the corresponding absorption intensity of the product and the fluorescence intensity were both "turn-on" and also exhibited excellent correlation with the concentration of PAP. This strategy not only remarkably simplifies the detection process but also improves the reliability of results due to the dual-signal response, which has promising applications in environmental, clinical, and industrial research fields.