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Developing agents buffers

Developing agents must also be soluble in the aqueous alkaline processing solutions. Typically such solutions are maintained at about pH 10 by the presence of a carbonate buffer. Other buffers used include borate and, less frequendy, phosphate. Developer solubiUty can be enhanced by the presence of hydroxyl or sulfonamide groups, usually in the A/-alkyl substituent. The solubilization also serves to reduce developer allergenicity by reducing partitioning into the lipophilic phase of the skin (46). [Pg.473]

Sodium bisulfite is often preferred in pyro developers and in Phenidone concentrates (Appendix 3 Pharmacopoeia Phenidone). Sodium bisulfite3 is often used in formulas that are divided into two solutions, as its weak acidity helps to inhibit the oxidation of the concentrated developing agent. When carbonate, contained in the B solution, is added to make a working solution, the bisulfite is immediately broken down into sulfite and bicarbonate, producing a useful buffering effect. [Pg.22]

In practical developers there is usually an excess of the reduced form of the developing agent with a small and variable amount of the oxidized form. Except for certain cases, such as in Lith development, the oxidation products are not allowed to accumulate. This means that the redox potentials are uncertain because the system is not in equilibrium. Redox buffers are solutions which are in equilibrium and contain definite amounts of oxidized and reduced forms. Many organic developing agents have oxidized forms which undergo side reactions, particularly in alkaline solution, which prevent them from being used as redox buffers for that reason, metal ion couples are used instead. [Pg.3491]

Early in Section 1.2.2 it was shown that if the potential of a developing agent is more negative than the silver ion potential, then development or silver ion reduction is thermodynamically possible. The difference between the equilibrium silver potential and the developer or redox buffer potential Ejev is ... [Pg.3492]

Quake and coworkers [16] developed a PDMS microfluidic device (shown in Fig. 4c) for nucleic acid purification from a small number of bacterial or mammalian cells. This multilayer device contained fluidic channels and a system of membrane-actuated pneumatic valves and pumps, which enabled precise control of buffers, lysis agents, and cell solution and also allowed for parallel processing. Bacterial cells, dilution buffer, and lysis buffer are first introduced into the chip and then transferred into the rotary mixer. Once mixed, the lysate is flushed over a DNA affinity column and drained. The DNA... [Pg.3024]

Wa.terBa.la.nce Chemicals. Water balance chemicals include muriatic acid, sodium bisulfate, and soda ash for pH control, sodium bicarbonate for alkalinity adjustment, and calcium chloride for hardness adjustment. A recent development is use of buffering agents for pH control. One of these products, sodium tetraborate, hydrolyzes to boric acid and a small amount of orthoborate (50) which provides significantly less buffering than carbonate and cyanurate alkalinity in the recommended pool pH range of 7.2—7.8 even at 100 ppm. [Pg.301]

G. Levy, J. R. Leonards, and J. A. Procknal, Development of in vitro dissolution tests which correlate quantitatively with dissolution rate-limited drug absorption in man, J. Pharm. Sci., 54, 1719-1722 (1966). K. A. Javaid and D. E. Cadwallader, Dissolution of aspirin from tablets containing various buffering agents, J. Pharm. Sci., 61, 1370-1373 (1972). [Pg.125]

Electroless Ni-Ge-P was studied as a model system for ternary alloy deposition [112], A chloride-free solution with GeC>2 as a source of Ge, hypophosphite as reducing agent, aspartic acid as a selective complexant for Ni2+ ions, which was operated at 80 °C in the pH range of 5-5.8, was developed for depositing Ni-Ge-P films with a tunable Ge content from 0 to 25+ at%. The use of a complexant such as citric acid, which complexed Ge(IY) ions as well as Ni2+ ions, resulted in a much lower Ge content in the electroless deposit, and a more complicated solution to study for the reasons discussed above. The aspartate-containing electroless solution, with its non-complexing pH buffer (succinic acid), approximated a modular system, and, with the exception of the aspartic acid - Ni2+ complexation reaction, exhibited a minimum level of interactions in solution. [Pg.257]


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