Kinetic Study on Degradation of Micro-organics by Different UV-based advanced oxidation processes in EfOM Matrix

Effluent Organic Matter (EfOM) contains a large number of substances that are harmful to both the environment and human health. To avoid the negative effects of organic matter in EfOM, advanced treatment of organic matter is an urgent task. Four typical oxidants (H2O2, PS, PMS, NaClO) and UV-combined treatments were used to treat micro-contaminants in the presence or absence of effluent organic matter (EfOM), because the active radical species produced in these UV-AOPs are highly reactive with organic contaminants. However, the removal efficiency of trace contaminants was greatly affected by the presence of EfOM. The degradation kinetics of two representative micro-contaminants (benzoic acid (BA) and para-chlorobenzoic acid(p-CBA)) was significantly reduced in the presence of EfOM, compared to the degradation kinetics in its absence. Using the method of competitive kinetics, with BA, p-CBA and 1,4-dimethoxybenzene (DMOB) as probes, the radicals (HO·, SO4-·, ClO·) proved to be the key to reaction species in advanced oxidation processes. UV irradiation on EfOM was not primarily responsible for the degradation of micro-contaminants. The second-order rate constants of the EfOM with radicals were determined to be (5.027±0.643)×102(SO4-·), (3.192±0.153)×104 (HO·) and 1.35×106 (ClO·) (mg-C/L)-1·s-1. In addition, this study evaluated the production of three radicals based on the concept of Rct, which can better analyze its reaction mechanism.

Deciphering the TLT-1 Fibrinogen Ligand Interaction

Background: Platelets, derived from megakaryocytes primarily play a central role in thrombosis and hemostasis, however, they extend beyond this role as immune cells that initiate and accelerate various vascular inflammatory conditions. Upon activation, platelets release TREM-Like Transcript-1 (TLT-1) from their a-granules onto their surface. Early studies by amino link columns preloaded with soluble TLT-1 followed by mass spectrometry and immunoblotting identified fibrinogen as a ligand for TLT-1. Fibrinogen is a plasma protein that is essential for clot formation, during inflammation and hypercoagulable states tissue deposition and plasma concentration of fibrinogen are increased, demonstrating a role of fibrinogen in both thrombosis and inflammation. TLT-1 binding fibrinogen was a surprising discovery since αIIbβ3, the most abundant platelet receptor, also binds fibrinogen and facilitates platelet aggregation. It is difficult to understand why there are two platelet specific receptors that have the same ligand, drawing us to question what the difference in function between the two is? Our studies suggest that although TLT-1 may assist in clot formation and hemostasis to arrest bleeding in a non-inflammatory setting like αIIbβ3, TLT-1's main association is with regulating inflammatory-derived bleeding. Very little is known about the TLT-1-Fibrinogen interaction, further studies would set the stage for a better understanding as to why two fibrinogen ligands exist on platelets and potentially outline a novel platelet therapeutic target during hypercoagulable and/or hyperinflammatory states. We set out to determine the binding affinity and localize the binding sites for the TLT-1 fibrinogen molecular interaction. Aims: Delineate the TLT-1 fibrinogen molecular interaction and elucidate the mechanism by which this interaction drives inflammation and thrombosis-hemostasis. Methods: To confirm the TLT-1 fibrinogen ligand interaction we carried out a kinetics assay using an Octet Qk e Bio-layer Interferometry (BLI) that measures biomolecular complex formation in real time. The TLT-1 Chimera was captured onto an Anti-Human Fc Capture (AHC) Biosensor, washed in kinetics buffer to limit nonspecific binding and submerged in a 96 well plate containing varying concentrations of Fibrinogen. To localize the exact binding sites for this molecular interaction, we digested fibrinogen using trypsin and carried out an immunoprecipitation (IP) followed by Liquid Chromatography-Mass Spectrometry (LC-MS/MS). Results: The curve (Figure 1) shows that the TLT-1 fibrinogen interaction has increasing bimolecular complex formation with increases in concentration of Fibrinogen (15.625nM - 250nM), with a concentration of 250nM showing the best bicomplex formation. In the control well with HIV01 4E10 capture, reference and sensor well, no bicomplex formation is shown, highlighting the specificity of the TLT-1 fibrinogen interaction. The curve illustrates a strong association with no dissociation, suggesting a strong interaction between the proteins. We isolated and identified four potential peptides (Alpha chain: GGSTSYGTGSETESPR, GSESGIFTNTK, Beta chain: QDGSVDFGR , QGFGNVATNTDGK) that bind TLT-1. We are currently performing BLI Competitive kinetics assays using biotinylated constructs of the peptides isolated from the Immunoprecipitation/ LC-MS/MS. The BLI competitive assays using the four peptides are suggestive of an interaction between TLT-1 and the four peptides as illustrated by increasing bimolecular complex formation with increasing concentration of soluble TLT-1 for all four peptides(data not shown). Conclusions: We obtained an equilibrium dissociation constant (KD) of 3.02 ± 0.20 nM for the TLT-1 fibrinogen interaction, suggesting a high affinity interaction between TLT-1 and fibrinogen. In our preliminary results from the BLI Competitive kinetics assays we obtained KD values within the nanomolar concentration range and are currently conducting experiments to optimize conditions to obtain our final bicomplex binding curve and KD values. We are currently assessing the identified peptides for potential of mediating the molecular interaction between TLT-1 and fibrinogen. Our poster will report the current state of these studies . Figure 1 Figure 1. Disclosures No relevant conflicts of interest to declare.

UV-activated permanganate process for micro-organic pollutant degradation: efficiency, mechanism and influencing factors

Ultraviolet-activated permanganate (UV/PM) process is a novel advanced oxidation process (AOP), but its application potential remains to be evaluated. This work investigates the degradation of refractory organic pollutant by UV/PM in terms of efficiency, mechanism, and influencing factors. The target compound benzoic acid (BA), which is a micro-organic pollutant and is resistant to PM and UV treatment, can be efficiently degraded by UV/PM. The electron paramagnetic resonance spectra directly supported the formation of hydroxyl radical (HO•) and superoxide radical from UV photolysis of PM. Competitive kinetics experiments verified that acted as precursor of HO• and the good degradation performance of BA was due to the involvement of HO• and manganese(V). The rate constants of BA degradation showed a positive linear relationship with PM dosage in the range of 0.5–20 mg·L−1, and the degradation process was significantly influenced by solution pH and natural organic matters but insensitive to chloride and bicarbonate at environmentally relevant concentrations. Compared to the typical UV-based AOP UV/hydrogen peroxide, UV/PM is a little inferior, indicating that optimization and enhancement is needed for this process before its possible practical application.