Diffusion, facilitated poisoning

Changes in plasma pH may also affect the distribution of toxic compounds by altering the proportion of the substance in the nonionized form, which will cause movement of the compound into or out of tissues. This may be of particular importance in the treatment of salicylate poisoning (see chap. 7) and barbiturate poisoning, for instance. Thus, the distribution of phenobarbital, a weak acid (pKa 7.2), shifts between the brain and other tissues and the plasma, with changes in plasma pH (Fig. 3.22). Consequently, the depth of anesthesia varies depending on the amount of phenobarbital in the brain. Alkalosis, which increases plasma pH, causes plasma phenobarbital to become more ionized, alters the equilibrium between plasma and brain, and causes phenobarbital to diffuse back into the plasma (Fig. 3.22). Acidosis will cause the opposite shift in distribution. Administration of bicarbonate is therefore used to treat overdoses of phenobarbital. This treatment will also cause alkaline diuresis and therefore facilitate excretion of phenobarbital into the urine (see below). 

With TS-1 as the catalyst, the oxidation products of phenol are hydro-quinone and catechol (para- and ort/to-hydroxyphenol), with minor yields of water and tar formed as by-products. Numerous early papers are concerned with this reaction (218), and patents (219) have been iiled. In the reaction catalyzed by TS-1, the conversion of phenol and the selectivity to dihydroxy products are significandy higher than achievable by either radical-initiated oxidation or acidic catalysts. The catechol/hydroquinone molar ratio is within the range of 0.5—1.3 and depends on the solvent. When the reaction occurs in aqueous acetone, the ratio is close to 1.3. It is believed that the product ratio is the result of restricted transition-state selectivity as well as mass transport shape selectivity associated with the different diffusivities of the ortho and para products. Hydroxylation at the para-position of phenol should be less hindered relative to that at the ortho-position, and hydroqui-none has a smaller kinetic diameter than catechol, facilitating diffusion. Tuel and Taarit (220) proposed that catechol is mainly produced at the external surface of TS-1 crystals. Thus, the different catechol/hydroquinone ratios obtained when methanol or acetone is used as a solvent could be explained by either rapid or very slow poisoning of external sites by organic deposits, respectively. Accordingly, the authors were able to show that tars were easily dissolved by acetone (i.e., external sites for catechol formation remained available in this solvent) while they were insoluble in methanol. 

Inhibitor substances which often act as enzyme poisons and are chemically different from the permeant may reduce the rate of penetration. Different inhibitors will "poison" various facilitated diffusion systems specifically. This criterion also applies to active transport systems. 

Example 1.3-6 Facilitated transport across membranes Some membranes contain a mobile carrier, a reactive species that reacts with diffusing solutes, facilitating their transport across the membrane. Such membranes can be used to concentrate copper ions from industrial waste and to remove carbon dioxide from coal gas. Diffusion across these membranes does not vary linearly with the concentration difference across them. The diffusion can be highly selective, but it is often easily poisoned. Should this diffusion be described with mass transfer coefficients or with diffusion coefficients ... 

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