Effect of Reactor Feeding Pattern on Performance of an Activated Sludge SBR

Cubas Suazo, Francisco Jose

06 December 2006

The possible effects of changes in the feeding pattern on activated sludge properties related to bioflocculation have been analyzed in lab scale sequencing batch reactors (SBR) in order to determine if these changes in effluent water quality and settling and dewatering properties are significant, so they can be considered in future studies or if they can be recommended as crucial when operating and designing wastewater treatment plants. The activated sludge process is widely used to treat wastewater from both industrial and municipal sources. Biomass from industrial facilities containing high monovalent to divalent ion content usually settles poorly, which leads to low quality effluents that fail to meet environmental requirements. Therefore, the combined effect of feeding pattern plus the addition of sodium to activated sludge reactors was studied in this experiment. A series of SBRs were operated at different sodium concentrations that ranged from 1.5 - 15 meq/L and different feeding times that ranged from 1 minute to 4 hours. Biomass samples were taken from each reactor to study the settling and dewatering properties and effluent samples were used to analyze the amount of organic matter and exocellular polymeric substances present due to deflocculation. As expected, the changes in feeding strategies affected all of the properties measured. When the feeding time was maintained low (pulse feed) the effluent quality and settling properties were the best. As the feeding time was increased the effluent quality, settling, and dewatering properties increased suggesting that the way in which the reactors were fed affected the overall bioflocculation process. The causes of the high deflocculation observed are not well understood, but data suggest that a microbial community change could have affected exocellular biopolymers which are believed to play an important role on bioflocculation. This research demonstrates the importance of the interaction between cation content and feeding pattern when operating a wastewater treatment plants and when reporting lab-scaled results related to settling and bioflocculation. / Master of Science

divalent cation bridging

biopolymers

feeding pattern

sodium

bioflocculation

settling

cations

Activated sludge

sequencing batch reactor

Irreversible Zinc Block of the Swelling-activated Chloride Current in DI TNC1 Astrocytes

Belkhayat, Noah

01 January 2016

The swelling-activated chloride current, commonly referred to as ICl,swell, is an outwardly-rectifying anion current that plays an important role in cell volume regulation, among other capacities. Despite several decades of research, the molecular identity of the channel responsible for this chloride current remains controversial. Recent indications that key endogenous sulfhydryl groups are capable of modifying the current led us to assess the effects of several divalent cations, including zinc, on ICl,swell. Zinc is known to tightly associate with sulfhydryl groups such as in zinc finger proteins. We found that extracellular zinc irreversibly inhibited ICl,swell at a site downstream in the signaling cascade. Moreover, zinc blocking kinetics were voltage dependent, suggesting interaction with a site within the electric field, across the pore of the channel responsible for ICl,swell. The importance of sulfhydryl groups was confirmed by demonstrating irreversible block by N-ethylmaleimide, a sulfhydryl alkylating reagent. In contrast, nickel failed to block ICl,swell, and as noted in previous studies, cadmium preferentially blocked the time-dependent component of ICl,swell. These data confirm the importance of sulfhydryl groups in the function of ICl,swell. Moreover, by demonstrating the voltage-dependence of block, the data strongly suggest the critical sulfhydryl group is within the channel pore. These biophysical characteristics of native ICl,swell are markers that should be recapitulated in expressed proteins claimed to be responsible for ICl,swell.

IClswell

zinc

Zn

divalent cation

swelling activated chloride current

VRAC

VSOAC

voltage dependence

irreversible

zinc block

Medicine and Health Sciences

Cell-protein-material Interactions on Bioceramics and Model Surfaces / Interaktioner mellan celler, proteiner och keramiska material

Rosengren, Åsa

January 2004

<p>The objective of this thesis was to investigate and characterize the interaction between blood proteins and different surfaces with emphasis on protein adsorption to bioceramics and model surfaces. Special effort was made to monitor the spontaneous and selective adsorption of proteins from human plasma and to examine the orientation, conformation and functional behavior of single proteins after adsorption. </p><p>Five different ceramic biomaterials: alumina (Al₂O₃), zirconia (ZrO₂), hydroxyapatite (Ca₁₀(PO₄)₆(OH)₂) and two glass-ceramics, AP40 (SiO₂-CaO-Na₂O-P₂O₅-MgO-K₂O-CaF₂) and RKKP (AP40 with Ta₂O₃-La₂O₃), were exposed to human plasma and their protein binding capacities and affinities for specific proteins were studied by chromatography, protein assays, two-dimensional gel electrophoresis and Western blotting. The studies showed that all materials adsorbed approximately the same high amount of plasma proteins and that they therefore should be fully covered by proteins in an <i>in vivo</i> setting. The adsorbed proteins were different for most materials which could explain their previously observed different levels of tissue integration <i>in vivo</i>. </p><p>Four of the proteins that behaved differently, ceruloplasmin, prothrombin, α₂-HS-glycoprotein and α₁-antichymotrypsin, were selected for characterization with atomic force microscopy and ellipsometry. The studies, which were performed on ultraflat silicon wafers (silica), showed that the proteins oriented themselves with their long axis parallel to the surface or as in case of ceruloplasmin with one of its larger sides towards the surface. All of them had globular shapes but other conformational details were not resolved. Furthermore, prothrombin (none of the others) formed multilayers at high proteins concentrations. </p><p>The functional behaviour of the adsorbed proteins, referring to their cell binding and cell spreading capacity on silica and a positive cell adhesion reference surface (Thermanox®), was affected by the underlying substrate. Ceruloplasmin, α₂-HS-glycoprotein and α₁-antichymotrypsin stimulated cell attachment to silica, but suppressed attachment to Thermanox®. Prothrombin stimulated cell attachment to both surfaces. The attachment was in most cases mediated both by cell membrane-receptors (integrins) and by non-specific interactions between the cell and the material. </p><p>This thesis showed that the compositional mixture, orientation, conformation and functional behavior of the adsorbed proteins are determined by the properties of the underlying surface and if these parameters are controlled very different cellular responses can be induced.</p>

Chemistry

protein adsorption

blood proteins

biomaterials

ceramics

glass-ceramics

two-dimensional gel electrophoresis

protein orientation

silicon wafers

atomic force microscopy

bone cell adhesion

divalent cation dependency

Kemi

Chemistry

Kemi

Cell-protein-material Interactions on Bioceramics and Model Surfaces / Interaktioner mellan celler, proteiner och keramiska material

Rosengren, Åsa

January 2004

The objective of this thesis was to investigate and characterize the interaction between blood proteins and different surfaces with emphasis on protein adsorption to bioceramics and model surfaces. Special effort was made to monitor the spontaneous and selective adsorption of proteins from human plasma and to examine the orientation, conformation and functional behavior of single proteins after adsorption. Five different ceramic biomaterials: alumina (Al2O3), zirconia (ZrO2), hydroxyapatite (Ca10(PO4)6(OH)2) and two glass-ceramics, AP40 (SiO2-CaO-Na2O-P2O5-MgO-K2O-CaF2) and RKKP (AP40 with Ta2O3-La2O3), were exposed to human plasma and their protein binding capacities and affinities for specific proteins were studied by chromatography, protein assays, two-dimensional gel electrophoresis and Western blotting. The studies showed that all materials adsorbed approximately the same high amount of plasma proteins and that they therefore should be fully covered by proteins in an in vivo setting. The adsorbed proteins were different for most materials which could explain their previously observed different levels of tissue integration in vivo. Four of the proteins that behaved differently, ceruloplasmin, prothrombin, α2-HS-glycoprotein and α1-antichymotrypsin, were selected for characterization with atomic force microscopy and ellipsometry. The studies, which were performed on ultraflat silicon wafers (silica), showed that the proteins oriented themselves with their long axis parallel to the surface or as in case of ceruloplasmin with one of its larger sides towards the surface. All of them had globular shapes but other conformational details were not resolved. Furthermore, prothrombin (none of the others) formed multilayers at high proteins concentrations. The functional behaviour of the adsorbed proteins, referring to their cell binding and cell spreading capacity on silica and a positive cell adhesion reference surface (Thermanox®), was affected by the underlying substrate. Ceruloplasmin, α2-HS-glycoprotein and α1-antichymotrypsin stimulated cell attachment to silica, but suppressed attachment to Thermanox®. Prothrombin stimulated cell attachment to both surfaces. The attachment was in most cases mediated both by cell membrane-receptors (integrins) and by non-specific interactions between the cell and the material. This thesis showed that the compositional mixture, orientation, conformation and functional behavior of the adsorbed proteins are determined by the properties of the underlying surface and if these parameters are controlled very different cellular responses can be induced.

Chemistry

protein adsorption

blood proteins

biomaterials

ceramics

glass-ceramics

two-dimensional gel electrophoresis

protein orientation

silicon wafers

atomic force microscopy

bone cell adhesion

divalent cation dependency

Kemi

Chemistry

Kemi