Enhanced removal of chemical oxygen demand, nitrogen and phosphorus using the ameliorative anoxic/anaerobic/oxic process and micro-electrolysis.

Synthetic wastewater was treated using a novel system integrating the reversed anoxic/anaerobic/oxic (RAAO) process, a micro-electrolysis (ME) bed and complex biological media. The system showed superior chemical oxygen demand (COD), total nitrogen (TN) and total phosphorus (TP) removal rates. Performance of the system was optimised by considering the influences of three major controlling factors, namely, hydraulic retention time (HRT), organic loading rate (OLR) and mixed liquor recirculation (MLR). TP removal efficiencies were 69, 87, 87 and 83% under the HRTs of 4, 8, 12 and 16 h. In contrast, HRT had negligible effects on the COD and TN removal efficiencies. COD, TN and TP removal efficiencies from synthetic wastewater were 95, 63 and 87%, respectively, at an OLR of 1.9 g/(L·d). The concentrations of COD, TN and TP in the effluent were less than 50, 15 and 1 mg/L, respectively, at the controlled MLR range of 75-100%. In this system, organics, TN and TP were primarily removed from anoxic tank regardless of the operational conditions.

Effects of nutrient addition on phenol biodegradation rate in biofilm reactors for hypersaline wastewater treatment.

Hypersaline wastewater, generated by many industrial activities, is difficult to treat through conventional biological processes. In this kind of hypersaline environment, complex nutrients are needed for the normal growth of many microorganisms. For this paper, the organisms were taken from a municipal wastewater treatment plant and acclimated to 15% salinity in a biofilm treatment process (Sequencing Batch Biofilm Reactor) during the treatment of phenol-containing synthetic wastewater. They are used to evaluate the effects of nutrient addition on the phenol biodegradation rate. Adding yeast extract, glucose, KCl and four mineral nutrients into the shaking flasks containing wastewater and cultivating organisms, revealed phosphate as the crucial nutrient stimulating phenol biodegradation at 15% salinity. The operation results of the sequencing batch biofilm reactor indicates that phosphate content increased up to five times the original level can increase the phenol removal rate by 150%. A 99% phenol removal efficiency could be achieved by shortening the reaction time in the biofilm reactor from 40 h to 16 h, compared with basic nutrients added. In this article we applied an applicable and effective shaking-culture method to determine nutrient requirements in biotreatment processes without stopping the running reactors.

[Repeated arterial infusion of zinostatin stimalamer using port for advanced hepatocellular carcinoma].

Four patients with advanced hepatocellular carcinoma were treated by repeated arterial infusion of zinostatin stimalamer (SMANCS). Every 4 weeks, 4 mg of SMANCS and 4 ml of Lipiodol were administered via the proper hepatic artery using an implantable arterial port. Three patients with advanced liver cirrhosis (Child B or C) could no longer be treated after 2 or 3 courses of SMANCS infusion because of hepatic failure. In the remaining patient also with compensated liver cirrhosis (Child A), a partial response was observed after 5 courses of chemo-infusion, but we discontinued infusion of SMANCS because of hepatic failure. To assess the usefulness of SMANCS for repeated arterial chemo-infusion by the port, we evaluated 103 patients with advanced HCC treated by Lipiodol emulsion mixed with 70 mg of epirubicin (EPI) using a port. An average course was 11 arterial infusions, and the overall response rate was 40%. One-year survival rates were 62% in Child A, 59% in Child B, and 53% in Child C. Compared with Child A and B patients, both elevation of serum total bilirubin levels and decrease of serum albumin levels were observed after 9 months in Child C patients. In conclusion, SMANCS may have more severe hepatic toxicity in comparison with Lipiodol emulsion mixed with EPI.