Fate of micropollutants in struvite production from swine wastewater with sacrificial magnesium anode.

Struvite recovery shows significant potential for simultaneously recovering nitrogen (N) and phosphorus (P) from swine wastewater but is challenged by the occurrence and transformation of antibiotic residuals. Electrochemically mediated struvite precipitation with sacrificial magnesium anode (EMSP-Mg) is promising due to its automation and chemical-free merits. However, the fate of antibiotics remains underexplored.

Importance of iron complexation and floc formation towards phosphonate removal with Fe-electrocoagulation.

Phosphonates are widely used scale inhibitors, but the residual phosphonates in drainage are challenging to remove because of their chelating capacity and resistance to biodegradation. Here, we reported a highly efficient and robust Fe-electrocoagulation (Fe-EC) system for phosphonate removal. Surprisingly, we found for the first time that phosphonates like NTMP were more efficiently removed under anoxic conditions (80% of total soluble phosphorus (TSP) in 4 min) than oxic conditions (0% of TSP within 6 min) in NaCl solution.

Electrochemical route outperforms chemical struvite precipitation in mitigating heavy metal contamination.

Electrochemically mediated struvite precipitation (EMSP) offers a robust, chemical-free process towards phosphate and ammonium reclamation from nutrients-rich wastewater, i.e., swine wastewater.

Interaction of calcium, phosphorus and natural organic matter in electrochemical recovery of phosphate.

To address the issues of eutrophication and the potential risk of phosphorus (P) shortage, it is essential to remove and recover P from P-containing streams to close this nutrient cycle. Electrochemical induced calcium phosphate (CaP) precipitation was shown to be an efficient method for P recovery. However, the influence of natural organic matter (NOM) is not known for this treatment.

Electrochemical Induced Calcium Phosphate Precipitation: Importance of Local pH.

Phosphorus (P) is an essential nutrient for living organisms and cannot be replaced or substituted. In this paper, we present a simple yet efficient membrane free electrochemical system for P removal and recovery as calcium phosphate (CaP). This method relies on in situ formation of hydroxide ions by electro mediated water reduction at a titanium cathode surface.

Multicomponent covalent dye assembly for tight binding and sensitive sensing of L-DOPA.

A mixture of two simple perylene-containing receptors was found to bind bifunctional L-DOPA synergistically and tightly via orthogonal boronate ester and imine bond formation in neutral aqueous solutions, the resulting three-component assembly forming optically active long fibrous aggregates.

Direct sensing of fluoride in aqueous solutions using a boronic acid based sensor.

Binding of the fluoride ion triggers aggregation of a pyreneboronic acid-catechol ensemble in acidic aqueous solutions, giving rise to intense excimer emission, allowing for sensitive fluoride ion sensing at ppm levels, with an apparent fluoride binding constant higher than 10(3) M(-1) which is unprecedented for boronic acid sensors in water.

Induced helical chirality of perylenebisimide aggregates allows for enantiopurity determination and differentiation of α-hydroxy carboxylates by using circular dichroism.

We have developed a working strategy for accurate enantiomeric excess (ee) determination based on induced helical aggregation of achiral perylenebisimide (PBI) dyes. PBI dyes functionalized with boronic acid moieties were shown to be effective chirality sensors for α-hydroxy carboxylates. Seven α-hydroxy carboxylates tested showed strong induced Cotton effects in the perylene absorption region around λ=500 nm, which were utilized for enantiomeric excess determination and chemo-discrimination of the analytes, with an average absolute error of 2 % in ee determination and 100 % correctness in analyte classification.

[Anatomical study of auditory brainstem implantation through retrosigmoid approach].

Objective: To provide anatomic data for auditory brainstem implantation (ABI) through the retrosigmoid approach.

Methods: Simulated operations were performed on 30 web adult head specimens and the structure around the foramen of luschka was observed. Both microscope and endoscope were employed.

Effects of delayed brain-derived neurotrophic factor application on cochlear pathology and auditory physiology in rats.

Background: The development and maintenance of spiral ganglion cells (SGCs) appear to be supported by neurotrophins. Removal of this support leads to their gradual degeneration. Intracochlear infusion with neurotrophins can provide trophic support to SGCs in animal deafness models if given shortly after deafening.

Delayed electrical stimulation and BDNF application following induced deafness in rats.

Conclusion: Under the condition of delayed intervention (30 days after deafening) following gentamicin+furosemide deafening in rats, we conclude that chronic intracochlear electrical stimulation (ES) and continuous intracochlear administration of brain-derived neurotrophic factor (BDNF) enhance spiral ganglion cell (SGC) body and peripheral process survival and improve auditory sensitivity. Moreover, the combination of ES and BDNF has a synergistic protective effect rather than an additive effect. Both SGC body and peripheral process influence the auditory sensitivity, and the latter appears to be more important.