Immersed membrane bioreactor (IMBR) for treatment of combined domestic and dairy wastewater in an isolated farm.

In many regions dairy farms and milk processing industries discharge large quantities of their wastes to the surroundings posing serious environmental risks. This problem is mostly faced in small dairy farms and isolated communities lacking both central collection and conventional wastewater treatment systems. Dairy wastewater is characterized by high concentrations of organic matter, solids, nutrients, as well as fractions of dissolved inorganic pollutants, exceeding those levels considered typical for high strength domestic wastewaters. With the purpose of treating the combined dairy and domestic wastewater from a small dairy farm in the Negev Desert of Israel, the use of a recent emerging technology of Immersed Membrane BioReactor (IMBR) was evaluated over the course of 500 test hours, under a variety of wastewater feed quality conditions (during the test periods, the feed BOD5 ranged from 315 ppm up to 4,170 ppm). The overall performance of a pilot-scale Ultrafiltration (UF) IMBR process for a combined domestic and dairy wastewater was analyzed based on the Data Envelopment Analysis (DEA) method. The IMBR performance in terms of membrane performance (permeate flux, transmembrane pressure, and organic removal) and DEA model (Technical Efficiency) was acceptable. DEA is an empirically based methodology and the research approach has been found to be effective in the depiction and analysis for complex systems, where a large number of mutual interacting variables are involved.

Glyburide-reversible cardioprotective effects of calcium-independent phospholipase A2 inhibition in ischemic rat hearts.

OBJECTIVES: A myocardial calcium-independent PLA2 has been described that is activated during myocardial ischemia and this enzyme may modulate ATP-sensitive potassium channels (KATP). The aim of this study was to determine the effect of an inhibitor of this enzyme, a bromoenol lactone, in isolated globally ischemic rat hearts. METHODS: Isolated rat hearts were treated for 10 min with 0.3-6 microM bromoenol lactone and then subjected to 25 min ischemia and 30 min reperfusion. RESULTS: The bromoenol lactone significantly increased coronary flow in nonischemic myocardium, and slightly reduced cardiac function at 6 microM. During global ischemia, time to contracture was significantly increased from vehicle group values in the presence of the bromoenol lactone (EC50 = 1.2 microM). During reperfusion, a concentration-dependent increase in function and a reduction in LDH release were observed for the PLA2 inhibitor. The concentrations of the PLA2 inhibitor which were significantly cardioprotective, inhibited this enzyme in membrane fractions of rat myocardium (IC50 = 0.87 microM). The KATP blocker sodium 5-hydroxydecanoate (5-HD) inhibited the increase in time to contracture observed for the bromoenol lactone. During reperfusion, 5-HD abolished the protective effects of the bromoenol lactone on cardiac function and LDH release. Glyburide had similar effects on the cardioprotective activity of the bromoenol lactone, although it only partially abolished the LDH reducing effect of this agent. CONCLUSIONS: The bromoenol lactone protects ischemic myocardium at concentrations which also inhibit calcium-independent PLA2. This cardioprotection can be attenuated by blockers of KATP, suggesting a potential mechanism for modulation of myocardial KATP.

Thrombin receptor activation by thrombin and receptor-derived peptides in platelet and CHRF-288 cell membranes: receptor-stimulated GTPase and evaluation of agonists and partial agonists.

Thrombin receptor activation, by thrombin or SFLLR-containing peptides, stimulates GTPase activity in platelet and CHRF-288 membranes. Polyclonal antibodies to peptides derived from the thrombin receptor (anti-TR52-69 and anti-TR36-49), which block many of thrombin's actions on platelets and endothelial cells, also block thrombin activation of membrane GTPase (as does thrombin active site and anion-binding exosite inhibitors). Most of the receptor-activated GTPase, stimulated by both thrombin and SFLLRNP in platelet membranes, was inhibited by prior treatment with pertussis toxin or N-ethylmaleimide, suggesting that under these conditions much of the thrombin receptor-stimulated GTPase in platelet membranes is a member of the pertussis toxin-sensitive G alpha i family. In platelet membrane preparations, the peptide agonists stimulated approximately twice as much GTPase activity as stimulated by alpha-thrombin. In contrast, the membranes prepared from CHRF-288 cells showed similar maximal SFLLRNP- and alpha-thrombin-stimulated GTPase activity. Stimulation of the platelet membrane GTPase by a variety of different peptide agonists correlated with their ability to stimulate platelet aggregation. Several peptide-based agonists were more potent than the wild-type sequence. The most potent was Ser-(p-fluoro-Phe)-(2-Napthyl-Ala)-Leu-Arg-NH2, which stimulated platelet aggregation (EC50 = 80 nM) and GTPase activity (EC50 = 110 nM). The peptide YFLLRN stimulated GTPase activity but only to approximately 40% of the activity observed with optimal concentrations of other receptor agonists. YFLLRN also limited the stimulation observed with SFLLRNP in a competitive fashion, indicating that YFLLRN is a competitive partial agonist at the thrombin receptor. These studies show that the tethered-ligand receptor mediates the GTPase activation by thrombin in platelet and CHRF-288 cell membranes, and this provides a specific, reliable, and convenient cell-free assay system with which one can evaluate agonists and partial agonists.

Isolation and identification of lysophosphatidylcholines as endogenous modulators of thromboxane receptors.

Inhibition of thromboxane receptor radioligand binding to human platelet membranes has been employed as the basis for a radioreceptor assay designed to measure thromboxane receptor binding activity in samples of biological fluids. This method was used during phase 1 clinical evaluation of the thromboxane receptor antagonist SQ 30,741. Frequently, baseline plasma samples as well as plasma samples from placebo-treated subjects showed significant inhibition of radioligand binding in the radioreceptor assay, suggesting the presence of endogenous thromboxane receptor ligands. This receptor binding activity was stable and could be monitored in blood from normal volunteers using a modification of the radioreceptor assay. In order to identify the substance responsible for the observed activity, the activity present in pooled bovine blood was isolated and evaluated by a combination of FAB/MS, 1H-NMR, 13C-NMR and co-injection with reference standards on HPLC. Several endogenous thromboxane receptor ligands were identified as L-alpha-lysophosphatidylcholine (LPC) species. One major species, palmitoyl-LPC, contracted isolated rat aortic spirals, and these contractions could be delayed or prevented, but not reversed by the thromboxane receptor antagonist SQ 29,548. Palmitoyl-LPC slightly potentiated aortic contractions induced by the thromboxane receptor agonist, U-46,619, and diminished in a concentration-dependent manner the antagonism by SQ 29,548 of contractile responses to U-46,619. These findings are consistent with a potential for LPC species to bind and activate thromboxane receptors.