Both pH control and complexation are widely used as solubilization techniques in drug formulation studies. Although these two techniques are often utilized in combination, few theoretical studies have shown why the combined approach would work better than either one alone. This study constructs a background in which both the pH effect and complexation constants are used to explain the synergism between these techniques. The total solubility is determined by the addition of the concentrations of the four components present in the solution: free un-ionized drug [Du], free ionized drug [Di], un-ionized drug complex [DuL], and ionized drug complex [DiL]. A detailed description of [Di] and [DiL] reveals that the complexation constants and the pH at which the drug may ionize are both critical. The weakly basic drug flavopiridol is used as a test compound to examine the validity of the equation. Although the complexation constant for ionized flavopiridol (Ki = 124 M(-1)) is less than one-third of that of the un-ionized species (Ku = 445 M(-1)), the solubility of the ionized drug complex [DiL] is 6-fold greater than that of the un-ionized drug complex [DuL]. This unexpected result is due to the 25-fold greater solubility of the ionized drug [Di] at pH 4.3 over that of the free un-ionized species [Du] at pH 8.4. The results of this and other complexation studies of several drugs taken from the literature lend the support to the following: If [Di]/[Du] >Ku/Ki, then [DiL] >[DuL].
This study investigates the roles of both ionized and un-ionized species of flavopiridol in solubilization by complexation, micellization, and cosolvency. Control of pH was used in combination with surfactants (polysorbate 20 and polysorbate 80), cosolvents (ethanol and propylene glycol), as well as uncharged and anionic complexing agents [hydroxypropyl beta-cyclodextrin (HPbetaCD) and sulfobutyl ether beta-cyclodextrin (SBEbetaCD)] to solubilize flavopiridol. These combined techniques increase not only the solubility of the un-ionized flavopiridol but also the solubility of the ionized drug. This study confirms that previously developed equations effectively characterize the roles of pH, pK(a), and either complexation constant, micelle partition coefficient, or cosolvent solubilizing power in determining drug total aqueous solubility.
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