Activity and Stability

Zoungrana T, FIndenegg G FI and Norde W 1997 Structure, stability and activity of adsorbed enzymes J. Colloid Interfaoe So/. 190 437-48... 

Olefin disproportionation 02/CH3C00H, caused a higher catalyst stability and activity. Catalysts based on Mo or W, especially 45... 

Lield stabilization and active optics are essentially based on VLT experience, with the added complexity of controlling not one but two actively de-... 

With respect to non-noble and non-Ru catalysts, transition metal chalcogenides with spinel and pyrite structures have been investigated and shown that these can also be active to oxygen reduction processes. The motivation in the present case is that chalcogen addition might enhance the stability and activity toward the ORR... 

Recently, rhodium and ruthenium-based carbon-supported sulfide electrocatalysts were synthesized by different established methods and evaluated as ODP cathodic catalysts in a chlorine-saturated hydrochloric acid environment with respect to both economic and industrial considerations [46]. In particular, patented E-TEK methods as well as a non-aqueous method were used to produce binary RhjcSy and Ru Sy in addition, some of the more popular Mo, Co, Rh, and Redoped RuxSy catalysts for acid electrolyte fuel cell ORR applications were also prepared. The roles of both crystallinity and morphology of the electrocatalysts were investigated. Their activity for ORR was compared to state-of-the-art Pt/C and Rh/C systems. The Rh Sy/C, CojcRuyS /C, and Ru Sy/C materials synthesized by the E-TEK methods exhibited appreciable stability and activity for ORR under these conditions. The Ru-based materials showed good depolarizing behavior. Considering that ruthenium is about seven times less expensive than rhodium, these Ru-based electrocatalysts may prove to be a viable low-cost alternative to Rh Sy systems for the ODC HCl electrolysis industry. 

Modes of attachment of functional groups to crosslinked polystyrene are discussed ( 1). Attention is drawn to improved stability and activity of polymer-bound reagents and catalysts incorporating dimethylene spacer between polystyrene aryl and functional group heteroatom, and the simplicity and versatility of their synthesis through high-conversion functional group modifications. 

Nishizawa, M., Okazaki, K., Furuno, N., Watanabe, N., and Sagata, N. (1992). The second-codon rule and autosphophorylation govern the stability and activity of Mos during the meiotic cell cycle in Xenopus oocytes. EMBO J. 11 2433-2446. 

Carbene ligands, especially the A-heterocyclic carbenes, are regarded as universal ligands in coordination and organometallic chemistry. They are able to bind to a wide variety of metal centers in various oxidation states, as well as to both stabilize and activate metal centers of key intermediates in the catalytic cycles of various organic... 

The following protocol for passive adsorption is based on methods reported for use with hydrophobic polymeric particles, such as polystyrene latex beads or copolymers of the same. Other polymer particle types also may be used in this process, provided they have the necessary hydrophobic character to promote adsorption. For particular proteins, conditions may need to be optimized to take into consideration maximal protein stability and activity after adsorption. Some proteins may undergo extensive denaturation after immobilization onto hydrophobic surfaces therefore, covalent methods of coupling onto more hydrophilic particle surfaces may be a better choice for maintaining native protein structure and long-term stability. 

Szleifer I (1997) Protein adsorption on surfaces with grafted polymers a theoretical approach. Biophys J 72 595-612 Tanford C (1973) The hydrophobic effect. John Wiley Sons, Inc., Hoboken Van Dulm P, Norde W, Lyklema J (1981) Ion participation in protein adsorption at solid surfaces. J Colloid Interf Sci 82 77-82 Zoungrana T, Findenegg GH, Norde W (1997) Structure, stability and activity of adsorbed ensymes. J Colloid Interf Sci 190 437-448 Zoungrana T, Norde W (1997) Thermal stability and enzymatic activity of a-chymotrypsin adsorbed on polystyrene surfaces. Colloid Surf B 9 157-167... 

The recent progress surveyed in this review shows the promise that late transition metal catalysts can provide in the production of new materials. We will continue our exploration of new catalyst design for the synthesis of new functional materials with unconventional topologies. Given the unique features of late transition-metal polymerization catalysts and further improvement in catalyst stability and activity for copolymerization with polar comonomers, the future of designing novel functional polymeric materials with late-transition-metal catalysts is very promising. 

Delmas et al. produced PVP-stabilized rhodium nanoparticles using the method reported by Hirai [32] to perform catalytic hydrogenation of oct-l-ene in a two-liquid-phase system [40]. These authors investigated the effect of various parameters on nanoparticle stability and activity under more or less severe conditions. It was also shown that PVP/Rh colloids could be reused twice or more, without any loss of activity. 

In the course of our investigations to develop new chiral catalysts and catalytic asymmetric reactions in water, we focused on several elements whose salts are stable and behave as Lewis acids in water. In addition to the findings of the stability and activity of Lewis adds in water related to hydration constants and exchange rate constants for substitution of inner-sphere water ligands of elements (cations) (see above), it was expected that undesired achiral side reactions would be suppressed in aqueous media and that desired enanti-oselective reactions would be accelerated in the presence of water. Moreover, besides metal chelations, other factors such as hydrogen bonds, specific solvation, and hydrophobic interactions are anticipated to increase enantioselectivities in such media. 

Early examples of the industrial application of this process (e.g. in the 1970s, General Electric [2] used first-generation ion-exchange membranes and SPE technologies) were not successful, mainly because of stability and activity/performance problems with the GDE. 

Right compromise of hydrogen pressure and temperature to fulfill stability and activity requirements for both catalyst systems. 

W. P. Skp2 regulates Myc protein stability and activity. Mol Gell 2003, 3 3, 1177-88. 

A practical enzymatic procedure using alcalase as biocatalyst has been developed for the synthesis of hydrophilic peptides.Alcalase is an industrial alkaline protease from Bacillus licheniformis produced by Novozymes that has been used as a detergent and for silk degumming. The major enzyme component of alcalase is the serine protease subtilisin Carlsberg, which is one of the fully characterized bacterial proteases. Alcalase has better stability and activity in polar organic solvents, such as alcohols, acetonitrile, dimethylformamide, etc., than other proteases. In addition, alcalase has wide specificity and both l- and o-amino acids that are accepted as nucleophiles at the p-1 subsite. Therefore, alcalase is a suitable biocatalyst to catalyse peptide bond formation in organic solvents under kinetic control without any racemization of the amino acids (Scheme 5.1). 

The chosen immobilization method must retain the stability and activity of the bound biological receptor. Generally, direct adsorption is not adequate and leads to significant losses in biological activity and random orientation of the receptors. Despite these difficulties, direct adsorption is widely employed since it is simple, fast and does not required special reagents. 

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