An artificial aquatic food web (AAFW) system was designed to remove the non-point source pollutants in eutrophic Jiyu river. A certain amount of Scenedesmus obliquus and Daphnia pulex was cultured in the system for th...An artificial aquatic food web (AAFW) system was designed to remove the non-point source pollutants in eutrophic Jiyu river. A certain amount of Scenedesmus obliquus and Daphnia pulex was cultured in the system for the control of serious cyanobacterial bloom. The AAFW system was a continuous-flow system including one storage basin of 3 m<sup>3</sup> capacity with polluted river water (the total nitrogen-TN: 4.49 mg⋅l<sup>-1</sup><sup></sup>;the total phosphorus-TP: 0.192 mg⋅l-1</sup></sup><sup></sup>), one phytoplankton tank of 3 m<sup>3</sup> capacity with an initial concentrations of S. obliquus about 5.8 × 10<sup>3</sup> ind⋅l-1</sup><sup></sup>, and one zooplankton growth chamber of 1.5 m<sup>3</sup> capacity with an initial abundance of D. pulex about 22.5 ind⋅l-1</sup></sup>. The system was optimized by setting hydraulic retention time of phytoplankton tank as 5 days and the experiments were operated for 45 days. Compared with the polluted river, TN and TP were removed about 28% and 47% by the AAFW system, respectively. The biomass of phytoplankton decrease from 6.33 mg⋅l-1<sup></sup> to 1.48 mg⋅l-1</sup><sup></sup> and the percentage of cyanobacteria decrease from 43.93% to 2.36%, the biomass of Crustacean zooplankton increase from 0.34 mg⋅l-1</sup></sup><sup></sup> to 1.53 mg⋅l-1</sup></sup><sup></sup> and the percentage of D. pulex increase from 19.19% to 57.62%. Our results indicated that the AAFW system not only is an efficient, flexible system for reducing nutrient levels in tributary rivers, but also has an ability to control the cyanobacteria bloom and rebuilding the aquatic ecosystem from the polluted river water.展开更多
BACKGROUND: Microglia function as the immune surveyors of the brain under normal physiologica conditions. However, microglia become activated in response to brain injuries and immunological OBJECTIVE: To explore the...BACKGROUND: Microglia function as the immune surveyors of the brain under normal physiologica conditions. However, microglia become activated in response to brain injuries and immunological OBJECTIVE: To explore the influence of scorpion venom (SV) heat-resistant protein on frontal cortex and hippocampal microglia cells in a mice model of Parkinson's disease. DESIGN, TIME AND SETTING: Randomized, controlled, cellular immunity study. The experiment was performed at the Physiology Department Laboratory in Dalian Medical University between June 2005 and July 2008. MATERIALS: Ninety-six healthy, C57B1/6 mice; 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) from Sigma, USA; SV heat-resistant protein (Experimental Base Institute in Dalian Medical University). The mice were randomly divided into four groups (n = 24): normal control, negative control, model, and SV heat-resistant protein. METHODS: Mice in the model and SV heat-resistant protein groups were subcutaneously injected with MPTP (20 mg/kg) to model Parkinson's disease, while the normal control and negative control groups were injected with physiological saline in the neck for 8 successive days. In addition, mice in the model and normal control groups were intraperitoneally injected with physiological saline 2 hours following administration, while SV heat-resistant protein and negative control groups were injected SV heat-resistant protein (0.01 mg/kg). MAIN OUTCOME MEASURES: lmmunoreactivity of microglia cells in MPTP-treated mice. RESULTS: Compared with normal control mice, MPTP-treated mice displayed increased OX-42 expression in the brain. However, in the SV heat-resistant protein-treated mice, OX-42 expression was decreased, compared to the model group. In the model mouse group, the number of OX-42-positive microglia was increased in the frontal cortex, caudatum, and hippocampal hilus, compared to the normal control mice (P 〈 0.01). However, in the SV heat-resistant protein-treated mice, the number of OX-42-positive microglia significantly decreased in the frontal cortex, caudatum, and hippocampal hilus, compared to the model group (P 〈 0.01). CONCLUSION: SV heat-resistant protein inhibited MPTP-induced microglial activation in the mouse frontal cortex and hippocampus, resulting in reduced microglial activation in the brain.展开更多
文摘An artificial aquatic food web (AAFW) system was designed to remove the non-point source pollutants in eutrophic Jiyu river. A certain amount of Scenedesmus obliquus and Daphnia pulex was cultured in the system for the control of serious cyanobacterial bloom. The AAFW system was a continuous-flow system including one storage basin of 3 m<sup>3</sup> capacity with polluted river water (the total nitrogen-TN: 4.49 mg⋅l<sup>-1</sup><sup></sup>;the total phosphorus-TP: 0.192 mg⋅l-1</sup></sup><sup></sup>), one phytoplankton tank of 3 m<sup>3</sup> capacity with an initial concentrations of S. obliquus about 5.8 × 10<sup>3</sup> ind⋅l-1</sup><sup></sup>, and one zooplankton growth chamber of 1.5 m<sup>3</sup> capacity with an initial abundance of D. pulex about 22.5 ind⋅l-1</sup></sup>. The system was optimized by setting hydraulic retention time of phytoplankton tank as 5 days and the experiments were operated for 45 days. Compared with the polluted river, TN and TP were removed about 28% and 47% by the AAFW system, respectively. The biomass of phytoplankton decrease from 6.33 mg⋅l-1<sup></sup> to 1.48 mg⋅l-1</sup><sup></sup> and the percentage of cyanobacteria decrease from 43.93% to 2.36%, the biomass of Crustacean zooplankton increase from 0.34 mg⋅l-1</sup></sup><sup></sup> to 1.53 mg⋅l-1</sup></sup><sup></sup> and the percentage of D. pulex increase from 19.19% to 57.62%. Our results indicated that the AAFW system not only is an efficient, flexible system for reducing nutrient levels in tributary rivers, but also has an ability to control the cyanobacteria bloom and rebuilding the aquatic ecosystem from the polluted river water.
基金National Natural Science Foundation of China, No.30770737
文摘BACKGROUND: Microglia function as the immune surveyors of the brain under normal physiologica conditions. However, microglia become activated in response to brain injuries and immunological OBJECTIVE: To explore the influence of scorpion venom (SV) heat-resistant protein on frontal cortex and hippocampal microglia cells in a mice model of Parkinson's disease. DESIGN, TIME AND SETTING: Randomized, controlled, cellular immunity study. The experiment was performed at the Physiology Department Laboratory in Dalian Medical University between June 2005 and July 2008. MATERIALS: Ninety-six healthy, C57B1/6 mice; 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) from Sigma, USA; SV heat-resistant protein (Experimental Base Institute in Dalian Medical University). The mice were randomly divided into four groups (n = 24): normal control, negative control, model, and SV heat-resistant protein. METHODS: Mice in the model and SV heat-resistant protein groups were subcutaneously injected with MPTP (20 mg/kg) to model Parkinson's disease, while the normal control and negative control groups were injected with physiological saline in the neck for 8 successive days. In addition, mice in the model and normal control groups were intraperitoneally injected with physiological saline 2 hours following administration, while SV heat-resistant protein and negative control groups were injected SV heat-resistant protein (0.01 mg/kg). MAIN OUTCOME MEASURES: lmmunoreactivity of microglia cells in MPTP-treated mice. RESULTS: Compared with normal control mice, MPTP-treated mice displayed increased OX-42 expression in the brain. However, in the SV heat-resistant protein-treated mice, OX-42 expression was decreased, compared to the model group. In the model mouse group, the number of OX-42-positive microglia was increased in the frontal cortex, caudatum, and hippocampal hilus, compared to the normal control mice (P 〈 0.01). However, in the SV heat-resistant protein-treated mice, the number of OX-42-positive microglia significantly decreased in the frontal cortex, caudatum, and hippocampal hilus, compared to the model group (P 〈 0.01). CONCLUSION: SV heat-resistant protein inhibited MPTP-induced microglial activation in the mouse frontal cortex and hippocampus, resulting in reduced microglial activation in the brain.
