"It's due to an equilibrium between 'bound' hydrocodone sulphonate salt and 'free' hydrocodone hydrochloride formed by the action of stomach acids. It
will reach a dynamic equilibrium based on the pKa (effectively how 'strong' an acid is) of the two acids.
So say at equilibrium, for every 3 molecules in the bound sulphonate form, there will 2 molecules as the hydrochloride salt; on to pf that, consider
that the 'free' hydrochloride form is also being absorbed into the bloodstream. This reduces the number of molecules in the hydrochloride form, and to
keep the equilibrium, some of the hydrocodone in the sulphonate salt form are released to form the hydrochoride salt. This process keeps on going
until the all of the hydrocodone is released from the sulphonate polymer.
To get an instant release, the beads can be placed in a solution of a string alkali ion such as sodium hydroxide. As sodium hydroxide in solution is
much more basic/alkaline than a soln of hydrocodone freebase in water, the sodium ions will displace the hydrocodone in a very short space of time
(the difference in alkalinity between sodium hydroxide and hydrocodone freebase is a hell of a lot more than the difference in acidity between
sulphonic acids and hydrochloric acid).
If the compound to be released isn't very soluble in freebase form, it may be necessary to use a sodium salt of a weak acid (such as sodium acetate -
formed by the reaction between sodium bicarbonate and acetic acid), so that the compound released into solution forms the (soluble) acetate salt.
As sodium acetate isn't as alkaline in solution as sodium hydroxide, the exchange will take a bit longer to complete.
Absolute times for say 90 percent release depend upon a lot of factors such as temp., concentration of sodium salt and the pH of solution."
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