Water-soluble core material

Solvent Evaporation. This encapsulation technology involves removing a volatile solvent from either an oil-in-water, oil-in-oil, or water-in-oH-in-water emulsion (19,20). In most cases, the shell material is dissolved in a volatile solvent such as methylene chloride or ethyl acetate. The active agent to be encapsulated is either dissolved, dispersed, or emulsified into this solution. Water-soluble core materials like hormonal polypeptides are dissolved in water that contains a thickening agent before dispersion in the volatile solvent phase that contains the shell material. This dispersed aqueous phase is gelled thermally to entrap the polypeptide in the dispersed aqueous phase before solvent evaporation occurs (21). 

In the last step, the core material is detached from the component blank. If a water-soluble core material was used, this can be done using water under pressure. With this process, longer hollow profiles, as well as geometrically complex cavities with undercuts, can be manufactured. 

Liquid food ingredients encapsulated are typically oil-soluble flavors, spices (see Flavors and spices), and vitamins (qv). Even food oils and fats are encapsulated (63). These core materials normally are encapsulated with a water-soluble shell material appHed by spray drying from water, but fat shell formulations are used occasionally. Preferred water-soluble shell materials are gum arabic, modified starch, or blends of these polymers with maltodextrins. Vitamins are encapsulated with 2ero bloom strength gelatin by spray drying. 

Tang, L. Schwartz, J.B. Porter, S.C. Schnaare, R.L. Wigent, R.J. Drug release from film-coated chlorpheniramine maleate nonpareil beads effect of water-soluble polymer, coating level, and soluble core material. Pharm. Dev. Technol. 2000, 5 (3), 383-390. 

Figure 4d represents in situ encapsulation processes (17,18), an example of which is presented in more detail in Figure 6 (18). The first step is to disperse a water-immiscible Hquid or soHd core material in an aqueous phase that contains urea, melamine, water-soluble urea—formaldehyde condensate, or water-soluble urea—melamine condensate. In many cases, the aqueous phase also contains a system modifier that enhances deposition of the aminoplast capsule sheU (18). This is an anionic polymer or copolymer (Fig. 6). SheU formation occurs once formaldehyde is added and the aqueous phase acidified, eg, pH 2—4.5. The system is heated for several hours at 40—60°C.

Spray Drying. Spray-dry encapsulation processes (Fig. 7) consist of spraying an intimate mixture of core and shell material into a heated chamber where rapid desolvation occurs to thereby produce microcapsules (24,25). The first step in such processes is to form a concentrated solution of the carrier or shell material in the solvent from which spray drying is to be done. Any water- or solvent-soluble film-forming shell material can, in principle, be used. Water-soluble polymers such as gum arable, modified starch, and hydrolyzed gelatin are used most often. Solutions of these shell materials at 50 wt % soHds have sufficiently low viscosities that they stiU can be atomized without difficulty. It is not unusual to blend gum arable and modified starch with maltodextrins, sucrose, or sorbitol. 

Using long-chain alkylsulfobetaines as the stabilizer, a number of highly water soluble nanometal colloids have been isolated in excellent yields (see Figure 8). The core particle size can be tailored between 1 and 10 nm. TEM examinations have shown that the resulting materials are generally mono-disperse. Further, a combination of spectroscopic methods confirmed the zerovalent nature of the metal cores [200]. 

Chromium occurs in both the Cr(lll) and Cr(VI) valence states. The rock and soil Cr reported in this study is dominantly insoluble and non-toxic Cr(lll), whereas the aqueous Cr reported in ground water is soluble and potentially toxic Cr(VI). We have analyzed core material (up to 30 m depth) from an area of the valley that exhibits elevated Cr(VI) concentrations in... 

The structure and properties of water soluble dendrimers, such as 46, is, in itself, a very promising area of research due to their similarity with natural micellar systems. As can be seen from the two-dimensional representation of 46 the structure contains a hydrophobic inner core surrounded by a hydrophilic layer of carboxylate groups (Fig. 12). However these dendritic micelles differ from traditional micelles in that they are static, covalently bound structures instead of dynamic associations of individual molecules. A number of studies have exploited this unique feature of dendritic micelles in the design of novel recyclable solubilization and extraction systems that may find great application in the recovery of organic materials from aqueous solutions [84,86-88]. These studies have also shown that dendritic micelles can solubilize hydrophobic molecules in aqueous solution to the same, if not greater, extent than traditional SDS micelles. The advantages of these dendritic micelles are that they do not suffer from a critical micelle concentration and therefore display solvation ability at nanomolar... 

Delivery systems that use a multicompartment core can theoretically deliver drugs of any solubility [48,49], A basic Push-Pull System consists of two layers the Lrst contains the drug, osmotically active hydrophilic polymer(s), and other pharmaceutical excipients the second layer, often called the push layer, contains a hydrophilic expansion polymer, other osmotically active agents, and the excipients, as shown in Figure 22.6. Poorly water-soluble compounds can be delivered using an ORO Push-Pull tlelivery system by incorporating drug as a micronized form, or as a hot-melt material suspended in a polymer matrix. 

Other formulation parameters that may be used to modulate the release include the ratio (relative concentrations) of polymers in the case of incorporation of a mix of two or more polymers as primary coating material, the properties of the core material, and the amount of plasticizers used, which affects the strength of the coat. Plasticizers with low water solubility such as dibutyl sebacate, diethyl phthalate, tri-acetin, triethyl citrate, and acetylated monoglyceride result in delaying... 

Coacervation phase separation. This technique is used to microencapsulate water-soluble drugs. The core material (drug) is suspended in a nonaqueous polymer solution (coating material), and the polymer is made to form a uniform coat by various approaches, such as temperature change, addition of an incompatible polymer, addition of a nonsolvent, or addition of a salt. 

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