Suspensions heterogeneous systems

Suspensions Heterogeneous systems containing coarsely dispersed material that settles. A wide variety of pharmaceutical preparations have been used as suspensions, for example. White Lotion, Magma of Bismuth, and Compound Mixture of Opium and Glycyrrhiza (Brown Mixture). In addition, several official ointments are suspensions of solids in a semisolid base. A large number of suspensions are categorized as mixtures in the United States Pharmacopeia and the National Formulary ... 

There are a large number of processes in the chemical industries that handle a variety of suspensions of solid particles in liquids. The application of filtration techniques for the separation of these heterogeneous systems is sometimes very costly. If, however, the discrete phase of the suspension largely contains settleable particles, the separation can be effected by the operation of sedimentation. The process of sedimentation involves the removal of suspended solid particles from a liquid stream by gravitational settling. This unit operation is divided into thickening,... 

The present chapter deals with calculations involving oral liquid dosage forms including homogenous systems such as syrups and elixirs, and heterogenous systems such as suspensions. 

The CSTR is particularly useful for reaction schemes that require low concentration, such as selectivity between multiple reactions or substrate inhibition in a chemostat (see Section IV). The reactor also has applications for heterogeneous systems where high mixing gives high contact time between phases. Liquid-liquid CSTRs are used for the saponification of fats and for suspension and emulsion polymerizations. Gas-liquid mixers are used for the oxidation of cyclohexane. Gas homogeneous CSTRs are extremely rare. 

In effect, such a multi-scale analysis resolves a macro-scale heterogeneous system into three meso- to micro-scale subsystems—dense-phase, dilute-phase and inter-phase. Thus, modeling a heterogeneous particle-fluid two-phase system is reduced to calculations for the three lower-scale subsystems, making possible the application of the much simpler theory of particulate fluidization to aggregative fluidization and the formulation of energy consumptions with respect to phases (dense, dilute and inter) and processes (transport, suspension and dissipation). 

The initial reaction medium comprises several phases and polymerization occurs in a heterogeneous system, as in emulsion and suspension reactions. 

Heterogeneous systems comprising (a) heterogeneous bulk polymerizations, (b) heterogeneous solution polymerizations, (c) suspension systems, (d) emulsion systems, (e) dispersion polymerization, (0 gas phase polymerization, and (g) interfacial polymerizations. 

Many pharmaceutical preparations containing oil-water systems (creams, ointments, or suspensions) are subject to microbial contamination. Bacteria in these heterogenous systems are usually grown in the aqueous phase and at the oil-water interface. To preserve the shelf-life of these preparations, benzoic acid or other organic acids are added as preservatives. Because the microbial cell membrane is lipophilic in nature, the bacteriostatic actions of the acidic preservative are attributable almost entirely to the undissociated acid and not to the ionized form. A good understanding of the partition coefficient and the degree of ionization allows accurate calculation of the free un-ionized acid in the aqueous phase, which provides the bacteriostatic concentration. 

Suspension, Dispersion, and Emulsion Polymerizations in Water (Heterogeneous System) 5. Other Special Solvents 3710... 

Another problem involves the classification of these metal-based heterogeneous systems into suspension, dispersion, and emulsion polymerizations similarly to conventional systems. This is due to not only a lack of detailed analysis of reaction mechanisms and particle sizes but also fundamental differences in several aspects such as the locus of initiation and the molecular weight of polymers in comparison with the conventional counterparts. The terms suspension and emulsion will be used in the following sections for simple classification but are not based on the strict definition for conventional free radical systems. 

Impinging streams [73] is a unique and multipurpose configuration of a two-phase suspension for intensifying heat and mass transfer processes in the following heterogeneous systems gas-solid, gas-liquid, liquid-liquid and solid-liquid. 

S. S. Komblum and M. A. Zoglio, Pharmaceutical heterogeneous systems I. Hydrolysis of aspirin in combination with tablet lubricant in an aqueous suspension, J. Pharm. Sci. 56, 1569-1575(1967). 

The use of a heterogeneous system under nitrogen consisting of a stirred suspension of silica gel with adsorbed ferric-catechol complex in benzene treated with 35% hydrogen peroxide has been reported to result after 2.5 hours in a 60% yield of phenol (ref. 14). The formation of phenol in 56% yield resulted from a mixture of benzene and vanadium(V) catalyst in acetonitrile under nitrogen when reacted for 2 hours at ambient temperature (ref. 15). More recent studies have involved the conversion of benzene in trifluoromethanesulphonic acid to phenol by the electroreduction of dioxygen (ref. 16) and from generation... 

As compressed carbon dioxide is a nonpolar molecule with weak van der Waals forces (low polarizability per volume), it is a relatively weak solvent [1], Thus, many interesting separations and chemical reactions involving insoluble substances in CO2 can be expected to take place in heterogeneous systems, for example, microemulsions, emulsions, latexes and suspensions. Microemulsion droplets 2-10 nm in diameter are optically transparent and thermodynamically stable, whereas kinetically stable emulsions and latexes in the range from 200 nm to 10 pm are opaque and thermodynamically unstable. 

On the other hand, when dealing with heterogeneous systems (e.g., suspension or emulsion polymerizations), it is important not to confuse thermodynamic effects of monomer partitioning among phases with variations in reactivity ratios. For the calculation of these, the concentrations of the monomers at the reaction site should be considered (at the particles) instead of global concentrations in the system. 

Polymerization reactors are a specific kind of chemical reactors in which polymerization reactions take place therefore, in principle, they can be analyzed following the same general rules applicable to any other chemical reactor. The basic components of a mathematical model for a chemical reactor are a reactor model and rate expressions for the chemical species that participate in the reactions. If the system is homogeneous (only one phase), these two basic components are pretty much what is needed on the other hand, for heterogeneous systems formed by several phases (emulsion or suspension polymerizations, systems with gaseous monomers, slurry reactors or fluidized bed reactors with solid catalysts, etc.), additional transport and/or thermodynamic models may be necessary to build a realistic mathematical representation of the system. In this section, to illustrate the basic principles and components needed, we restrict ourselves to the simplest case, that of homogeneous reactors in other sections, additional components and more complex cases are discussed. 

Complex fluids composed of several pseudophases with a liquid-liquid interface (emulsions, macroemul-sions, cells, liposomes) or liquid-solid interface (suspensions of silica, carbon black, latex, etc.) can, from a dielectric point of view, be considered as classical heterogeneous systems. Several basic theoretical approaches have been developed in order to describe the dielectric behavior of such systems. Depending on the concentration, the shape of the dispersed phase, and the conductivity of both the media and disperse phase, different mixture formulas can be applied to describe the electric property of the complex liquids (11-15). 

An emulsion has been defined above as a thermodynamically unstable heterogeneous system of two immiscible liquids where one is dispersed in the other. There are two principal possibilities for preparing emulsions the destruction of a larger volume into smaller sub-units (comminution method) or the construction of emulsion droplets from smaller units (condensation method). Both methods are of technical importance for the preparation of emulsions for polymerization processes and will be discussed in more detail below. To impart a certain degree of kinetic stability to emulsions, different additives are employed which have to fulfil special demands in the particular applications. The most important class of such additives, which are also called emulsifying agents, are surface-active and hence influence the interfacial properties. In particular, they have to counteract the rapid coalescence of the droplets caused by the van der Waals attraction forces. In the polymerization sense, these additives can be roughly subdivided into surfactants for emulsion polymerization, polymers for suspension and dispersion polymerization, finely dispersed insoluble particles (also for suspension polymerization), and combinations thereof (cf. below). 

Dilute and concentrated micellar solutions Reversed micellar solutions Microemulsions Heterogeneous systems Emulsions Suspensions Vesicles, liposomes Foams... 

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