Project description:Full-Scale AOA Process for Advanced Nitrogen Removal from Low-Strength Municipal Wastewater under Ultra-Low Gas-Water Ratios

Project description:Advanced nitrogen removal from low-strength municipal sewage by partial nitritation/anammox process: Zeolite-driven nitritation mechanism and microbial community analysis

Project description:Synchronous achievement of advanced nitrogen removal and N2O reduction in the anoxic zone in the AOA process for low C/N municipal wastewater

Project description:Beyond Traditional Biological Nutrient Removal Limits: Achieving Ultra-Low Effluent Nitrogen via an Anaerobic/Oxic/Anoxic (AOA) Process in a Pilot-Scale System Treating Municipal Wastewater

Project description:Advanced nitrogen removal via anammox from municipal wastewater during the continuous flow anoxic/oxic process with an ultra-short hydraulic retention time

Project description:Novel PN-SHDA process for advance nitrogen removal from very low COD/TIN municipal wastewater

Project description:In response to the issues of low denitrification efficiency and high N₂O emissions in the biological nitrogen removal process of low C/N municipal wastewater, studies typically address these challenges by adding carbon sources. In this study, the addition of microorganisms enhanced the carbon flow and electron transport for nitrate reduction, significantly improving the denitrification performance of low C/N wastewater and reducing N₂O production. Proteomic analysis was employed to explore the mechanisms underlying this effect. The results revealed that the metabolites produced by the added microorganisms, S. oneidensis MR-1 and B. subtilis, including biosurfactants, heme, and cytochromes, altered the intracellular carbon redistribution in P. denitrificans, leading to an increased carbon flow directed towards nitrate reduction, thus enhancing total nitrogen removal efficiency.

Project description:Advanced nitrogen removal

Project description:Intracytoplasmic sperm injection (ICSI) has been an effective infertility treatment. Nevertheless, ICSI failures still occurred. One of the factors associated with ICSI failure is oocyte activation deficiency (AOD). The most commonly applied method of artificial oocyte activation (AOA) in humans includes ionophore. Although AOA is performed as a routine process in many assisted reproduction centers, up to date, there is no relevant study to expound whether AOA procedures increase developmental risks by disturbing subsequent gene expression during the embryonic development stages. Our results for the first time provide a profile of the changes in the global patterns of gene expression in AOA treatment versus ICSI generated mouse early embryos. In particular, we focus on the expression changes of imprinted genes. Another key observation in this study is that AOA treatment affects imprinted gene Igf2r expression and mehtylation, which is regulated by the imprinted Airn macro long non-coding (lnc) RNA.

Project description:Sulfide removal process