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Application of high current enabled significantly higher recoveries than could otherwise be obtained at 100 μA. Sacrificial electrodes were also tested in μ-EME and were found beneficial by eliminating detrimental bubble formation. Thus, the sacrificial electrodes improved the stability of μ-EME systems. The findings of this paper are important for development of stable and robust systems for EME operated at high voltage/current and for EME performed in narrow channels/tubing where bubble formation is critical.Self-detoxifying fabrics are desirable forms for protection against chemical warfare agents (CWAs). Zirconium-based metal-organic frameworks (Zr-MOFs) have emerged as one of the fastest catalysts for nerve-agent hydrolysis, but there is still a lack of reliable methods to integrate them onto fibrous supports, and instantaneous detoxification remains challenging for MOF/fiber composites. Herein, we report a bio-inspired polydopamine (PDA)-mediated strategy for the preparation of Zr-MOF (UiO-66-NH2)-coated nanofiber membranes, which are capable of photothermally catalyzing the degradation of CWA simulants. UiO-66-NH2 nanocrystalline coating with high mass loading, perfect coverage, and good adhesion is readily formed on polyamide (PA)-6 nanofibers with the precoated PDA layer. The prepared PA-6@PDA@UiO-66-NH2 nanofibers display almost an order of magnitude higher turnover frequency (TOF) for the hydrolysis of the nerve agent simulant dimethyl 4-nitrophenylphosphate (DMNP) when irradiated under simulated solar light, with a half-life of only 0.5 min. Such a hydrolysis rate is significantly higher compared to that of the corresponding UiO-66-NH2 powder and UiO-66-NH2/fiber composites reported so far. This strategy may be easily generalized to other MOF/fiber pairs to achieve even higher performance and opens up new opportunities for solar photothermal catalysis in CWA protection.While there is ample evidence suggesting that carriers of heterozygous hemoglobin S and C are protected from life-threatening malaria, little is known about the underlying biochemical mechanisms at the single cell level. Using nanofocused scanning X-ray fluorescence microscopy, we quantify the spatial distribution of individual elements in subcellular compartments, including Fe, S, P, Zn, and Cu, in Plasmodium falciparum-infected (P. falciparum-infected) erythrocytes carrying the wild type or variant hemoglobins. Our data indicate that heterozygous hemoglobin S and C significantly modulate biochemical reactions in parasitized erythrocytes, such as aberrant hemozoin mineralization and a delay in hemoglobin degradation. The label-free scanning X-ray fluorescence imaging has great potential to quantify the spatial distribution of elements in subcellular compartments of P. falciparum-infected erythrocytes and unravel the biochemical mechanisms underpinning disease and protective traits.The present study demonstrates the use of highly stable single-molecule enzyme nanocapsules (SMENs) instead of traditional native enzyme as biorecognition element in enzyme-based biosensors. The main purpose of this study is to resolve the major obstacle and challenge in the biosensor field, i.e., the poor stability of enzyme-based biosensors, including thermal stability, organic solvent tolerance, long-term operational stability, etc. Highly active and robust SMENs of glucose oxidase (GOx, as a model enzyme) were synthesized (nGOx) using an in situ polymerization strategy in an aqueous environment. The particle-size distribution, transmission electron microscopic (TEM) images, and UV-vis spectral characterization revealed the formation of a thin polymer layer around each enzyme molecule. The polymer shell effectively stabilized the GOx enzyme core while enabling rapid substrate transportation, resulting in a new class of biocatalytic nanocapsules. Multiple covalent attachments between a thin polymer layer andevices, implantable equipment, and biofuel cells.Water, the major body fluid in humans, has four main naturally occurring isotopologues, H216O, H217O, H218O, and H2H16O (i.e., HD16O) with different masses. this website The underlying mechanisms of the isotope-specific water-metabolism in the human gastrointestinal (GI) tract and respiratory system are largely unknown and remained illusive for several decades. Here, a new strategy has been demonstrated that provides direct quantitative experimental evidence of triple-isotopic signatures of water-metabolism in the human body in response to the individual's water intake habit. The distribution of water isotopes has been monitored in drinking water (DW; δD = -36.59 ± 10.64‰ (SD), δ18O = -5.41 ± 1.47‰ (SD), and δ17O = -2.92 ± 0.79‰ (SD)), GI fluid (GF; δD = -35.91 ± 7.30‰ (SD), δ18O = -3.98 ± 1.29‰ (SD), and δ17O = -2.37 ± 0.57‰ (SD)), and human exhaled breath (EB; δD = -119.63 ± 7.27‰ (SD), δ18O = -13.69 ± 1.23‰ (SD), and δ17O = -8.77 ± 0.98‰ (SD)) using a laser-based off-axis integrated cavity output spectroscopy (OA-ICOS) technique. This study explored a new analytical method to disentangle the competing effects of isotopic fractionations of water during respiration in humans. In addition, our findings revealed that deuterium-enriched exhaled semiheavy water, i.e., HD16O is a new marker of the noninvasive assessment of the ulcer-causing H. pylori gastric pathogen. We also clearly showed that the water-metabolism-derived triple-isotopic compositions due to impaired water absorption in the GI tract can be used as unique tracers to track the onset of various GI dysfunctions. These findings are thus bringing a new analytical methodology to better understand the isotope-selective water-metabolism that will have enormous applications for clinical testing purposes.The irrational or excessive use of antibiotics causes the emergence of bacterial resistance, making antibiotics less effective or ineffective. As the number of resistant antibiotics increases, it is crucial to develop new strategies and innovative approaches to potentiate the efficacy of existing antibiotics. In this paper, we report that some existing antibiotics can produce reactive oxygen species (ROS) directly under light irradiation. Thus, a novel antibacterial photodynamic therapy (PDT) strategy is proposed by using existing antibiotics for which the activities are potentiated via light-activation. This antibiotic-based PDT strategy can achieve efficient bacteria killing with a low dosage of antibiotics, indicating that bacterial killing can be enhanced by the light-irradiated antibiotics. Moreover, the specific types of ROS produced by different antibiotics under light irradiation were studied for better elucidation of the antibacterial mechanism. The findings can extend the application of existing antibiotics and provide a promising strategy for treatment of bacterial infections and even cancers.