Mixtures more-than additive interactions

A recent study of Moser eoworkers (2005) Mo,ser et uL (2005), using a do.se-additive design with mixtures of five commonly used OP pesticides (chlorpyrifos, diazinon, dimeihoate, acephaic, and malathion), showed a more-than-additive interaction on multiple end points blood and brain cholinesterase inhibition, motor activity, and gait score (tail-pinch response did not. show a more-than-additive interaction). This study is noteworthy because (i) relatively sensitive end points were used to test the toxic interaction of the OP pesticides, such as cholinesterase inhibition or depression of motor activity (ii) more than two OP compounds were used in the mixture and (iii) comprehensive statistical analyses of the data were performed. The pharmacokinetic interaction of two of the aimpounds in the mixture, chlorpyrifos and diazinon, has been studied in rats (Timchalk et a ., 2004). The authors found that one compound did not affect the pharmacokinetics of the other unless high doses were given, concluding that a more-than-additive interaction is unlikely at environmentally relevant concentrations. 

In summary, CM/OP interactions arc not necessarily less than additive, a.s is the general expectation given the well-known antagonism between CMs and nerve agents. In fact, there are quite a few indications that in some. systems there is a more-than-addilive interaction between the two. Moreover, the type of interaction likely depends on the proponioti of each pesticide in the mixture. 

Copper-nickel mixtures have a beneficial effect on growth of terrestrial plants but are more-than-additive in toxic action to aquatic plants. Nickel interacts with iron in rat nutrition and metabolism, but the interaction depends on the form and level of the... 

Scott and Kucera [4] carried out some experiments that were designed to confirm that the two types of solute/stationary phase interaction, sorption and displacement, did, in fact, occur in chromatographic systems. They dispersed about 10 g of silica gel in a solvent mixture made up of 0.35 %w/v of ethyl acetate in n-heptane. It is seen from the adsorption isotherms shown in Figure 8 that at an ethyl acetate concentration of 0.35%w/v more than 95% of the first layer of ethyl acetate has been formed on the silica gel. In addition, at this solvent composition, very little of the second layer was formed. Consequently, this concentration was chosen to ensure that if significant amounts of ethyl acetate were displaced by the solute, it would be derived from the first layer on the silica and not the less strongly held second layer. 

The lattice gas has been used as a model for a variety of physical and chemical systems. Its application to simple mixtures is routinely treated in textbooks on statistical mechanics, so it is natural to use it as a starting point for the modeling of liquid-liquid interfaces. In the simplest case the system contains two kinds of solvent particles that occupy positions on a lattice, and with an appropriate choice of the interaction parameters it separates into two phases. This simple version is mainly of didactical value [1], since molecular dynamics allows the study of much more realistic models of the interface between two pure liquids [2,3]. However, even with the fastest computers available today, molecular dynamics is limited to comparatively small ensembles, too small to contain more than a few ions, so that the space-charge regions cannot be included. In contrast, Monte Carlo simulations for the lattice gas can be performed with 10 to 10 particles, so that modeling of the space charge poses no problem. In addition, analytical methods such as the quasichemical approximation allow the treatment of infinite ensembles. 

The difference in properties when the aliphatic chain of amine oxide contains more than 14 carbons is attributed to the mismatch of the hydrophobic chain with that of the SDS. The extra terminal segment results in a disruptive effect on the packing of the surface active molecules. The observed association behavior in the case of 0 2 C14-DAO with SDS is then also due to the maximum cohesive interaction between hydrocarbon chains in addition to the reduced electrostatic repulsion in the head groups. Solubilization of the 1 1 association is also determined by this chain length compatibility effect which may contribute to the absence of visible precipitation in C12/C12 and C2 2/ -14 mixtures. Chain length compatibility effects in different systems have been discussed by other investigators (24,25,26). 

Amine oxide pyrolysis occurs at temperatures of 100-150° C. The reaction can proceed at room temperature in DMSO.229 230 231 232 If more than one type of [> hydrogen can attain the eclipsed conformation of the cyclic transition state, a mixture of alkenes will be formed. The product ratio parallels the relative stability of the competing transition states. Usually, more of the E-alkene is formed because of the additional eclipsed interactions present in the transition state leading to the Z-alkene. The selectivity is usually not high,... 

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