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Changes, hydrolytic

Commercial condensed phosphoric acids are mixtures of linear polyphosphoric acids made by the thermal process either direcdy or as a by-product of heat recovery. Wet-process acid may also be concentrated to - 70% P2O5 by evaporation. Liaear phosphoric acids are strongly hygroscopic and undergo viscosity changes and hydrolysis to less complex forms when exposed to moist air. Upon dissolution ia excess water, hydrolytic degradation to phosphoric acid occurs the hydrolysis rate is highly temperature-dependent. At 25°C, the half-life for the formation of phosphoric acid from the condensed forms is several days, whereas at 100°C the half-life is a matter of minutes. [Pg.330]

The glucosides are compounds, which, under the influence of hydrolytic agents are decomposed into glucose or an allied aldose or ketose, and one or more other bodies, which, in the cases under consideration, form constituents of essential oils. The hydrolytic agents which bring about these changes are soluble ferments, such as diastases, enzymes and similar... [Pg.13]

Poly(L-malate) decomposes spontaneously to L-ma-late by ester hydrolysis [2,4,5]. Hydrolytic degradation of the polymer sodium salt at pH 7.0 and 37°C results in a random cleavage of the polymer, the molecular mass decreasing by 50% after a period of 10 h [2]. The rate of hydrolysis is accelerated in acidic and alkaline solutions. This was first noted by changes in the activity of the polymer to inhibit DNA polymerase a of P. polycephalum [4]. The explanation of this phenomenon was that the degradation was slowest between pH 5-9 (Fig. 2) as would be expected if it were acid/base-catalyzed. In choosing a buffer, one should be aware of specific buffer catalysis. We found that the polymer was more stable in phosphate buffer than in Tris/HCl-buffer. [Pg.100]

The polyether imides show much better hydrolytic stability with little change in tensile strength after exposure to water at 100°C for 1 year. These materials also show exceptional resistance to mineral acids, and are unharmed by most hydrocarbons including gasoline (petrol) and oils. [Pg.936]

The main polymerization method is by hydrolytic polymerization or a combination of ring opening as in (3.11) and hydrolytic polymerization as in (3.12).5,7 9 11 28 The reaction of a carboxylic group with an amino group can be noncatalyzed and acid catalyzed. This is illustrated in the reaction scheme shown in Fig. 3.13. The kinetics of the hydrolytic polyamidation-type reaction has die form shown in (3.13). In aqueous solutions, die polycondensation can be described by second-order kinetics.29 Equation (3.13) can also be expressed as (3.14) in which B is die temperature-independent equilibrium constant and AHa the endialpy change of die reaction5 6 812 28 29 ... [Pg.150]

The hydrolytic behavior of sulfosuccinates as such and in formulations is depicted in the following pictures (Figs. 4-7). Two substances-DLAS and DLSS—were chosen to illustrate these properties. The tests were performed at room temperature and 40°C at various pH values (pH = 5, 6, 8) and—in the case of DLSS—without adjusting pH in a long-term run (24 weeks). Changes were evaluated by determination of pH and active matter. [Pg.520]

However, more-rigorous treatment (5% acetic acid, 100°C, 17 hours) opened the imidazole ring and produced /V -cyclohexyl-a-formylaminoacetamidine (57), characterized as the crystalline picrate. Amidine 57 produced no dye in the Bratton-Marshall assay. The same behavior can be expected from AIR (46), although the product of hydrolytic ring-opening was not actually isolated. On the other hand, it was observed that a solution of AIRs (0.2 mM in 0.01-M ammonium hydroxide) prepared by biosynthesis, when stored at 4°C, did not change appreciably within a day. A decrease in the concentration of AIRs of about 30% occurred within a month. [Pg.300]

As discussed earlier the whole process is a redox reaction. Selenium is reduced using sodium borohydride to give selenide ions. In the above reaction, the metal ion reacts with the polymer (PVP or PVA) solution to form the polymer-metal ion solution. Addition of the selenide ion solution to the polymer-metal ion solutions resulted in instantaneous change in the colour of the solutions from colourless to orange (PVA) and orange red (PVP). This indicates the formation of CdSe nanoparticles. The addition of the selenide solution to the polymer - metal ion solution resulted in gradual release of selenide ion (Se -) upon hydrolytic decomposition in alkaline media (equation 4). The released selenide ions then react with metal ion to form seed particles (nucleation). [Pg.174]

More definitive evidence of enzymatic attack was obtained with 1 1 copolymers of e-caprolactone and 6-valerolactone crosslinked with varying amounts of a dilactone (98,99). The use of a 1 1 mixture of comonomers suppressed crystallization and, together with the crosslinks, resulted in a low-modulus elastomer. Under in vitro conditions, random hydrolytic chain cleavage, measured by the change in tensile properties, occurred throughout the bulk of the samples at a rate comparable to that experienced by the other polyesters no weight loss was observed. However, when these elastomers were implanted in rabbits, the bulk hydrolytic process was accompanied by very rapid surface erosion. Weight loss was continuous, confined to the... [Pg.105]

The purpose of this chapter is to introduce a new class of polymers for both types of biomedical uses a polymer system in which the hydrolytic stability or instability is determined not by changes in the backbone structure, but by changes in the side groups attached to an unconventional macromolecular backbone. These polymers are polyphosphazenes, with the general molecular structure shown in structure 1. [Pg.163]

A method for the direct spectrophotometric determination of dinucleoside monophosphates has been developed which relies on changes in u.v. absorbance after enzymic hydrolysis. - Hydrolytic fission of the dinucleoside monophosphate with a phosphodiesterase causes a change in the u.v. absorbance of the solution allowing the 5 -nucleoside to be estimated. Addition of a phosphomonoesterase to the hydrolysate causes a further change in u.v. absorbance, allowing the 3-nucleoside to be estimated. [Pg.134]

During food processing, interactions of antioxidants with proteins and other food constituents take place, and the activity of some antioxidants may change as a result of hydrolytical processes because glycosides and esters are converted... [Pg.298]

SHIN T, GODBER s J, MARTIN D E, WELLS H J (1997) Hydrolytic Stability and changes in vitamers and oryzanol of extruded rice bran during storage. JFood Sci, 62(4) 704-29. [Pg.375]

Besides, it is known that the culture medium acts as a common external sink like a lamella (15) or a vacuole (19), in which polysaccharides, enzymes and other metabolites are secreted during growth. Consequently, the growth of plant cell suspensions is a complex process, connected with structural and metabolite changes both in the cell wall and in the culture medium, involving a complex of hydrolytic enzymes. [Pg.871]

A number of publications have discussed the characterization of the substituted polymers (4.5,7,8,9). However, because of the poor hydrolytic stability of the chloropolymer, characterization of it has been rather difficult and slow to develop, and the literature is rather scant in this regard (10,ip. Conclusions about the struct are and polymerization mechanism of the chloropolymer have sometimes been drawn from the analysis of the substituted polymers. These conclusions, of course, assume that there is very little, if any, change of the chloropol pier chain structure during the substitution reaction. It was felt that a direct analysis of the chloropolymer may lead to a more accurate understanding of both the polymer structure and the polymerization mechanism. [Pg.255]

The use of the term leuco dye is a common paradox. Leuco color formers are materials that undergo controlled chemical or physical changes resulting in a shift from a colorless state to an intense color. The preparation of leuco color formers takes advantage of the very nature of colored materials themselves. The existence of extended conjugated -system in dyes is responsible for the absorption in the visible region. The chemistry of such rc-system is noted for facile reactivity, particularly to reactions such as reduction, oxidation, and hydrolysis (not hydrolytic cleavage). When n-... [Pg.312]

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See also in sourсe #XX -- [ Pg.209 ]



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Hydrolytic

Structural and Property Changes During Hydrolytic Degradation

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