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Factors Affecting Dissolution: Drug pKa, Lipophilicity and GI pH

JoVE Core
Pharmacokinetics and Pharmacodynamics
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JoVE Core Pharmacokinetics and Pharmacodynamics
Factors Affecting Dissolution: Drug pKa, Lipophilicity and GI pH

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01:21 min

October 10, 2024

Drug absorption within the gastrointestinal (GI) tract is a complex process influenced by several critical factors, including the site pH, the drug's dissociation constant (pKa), and the drug's lipophilicity. The GI tract exhibits a pH gradient, with an acidic environment in the stomach and a more alkaline environment in the small intestine. This pH variation directly affects the ionization state of drugs.

A drug's pKa and the pH of the gastrointestinal (GI) tract play crucial roles in drug dissolution by influencing the drug's ionization state, solubility, and absorption. Very weak acids with a pKa above 8 and very weak bases with a pKa below 5, such as phenytoin and caffeine, exist predominantly in their unionized form and exhibit rapid, pH-independent absorption. Conversely, drugs with acid pKa values between 2.5 and 7.5, including several nonsteroidal anti-inflammatory drugs (NSAIDs) and penicillin analogs, and those with basic pKa values between 5 and 11, like morphine analogs, are subject to pH-dependent absorption. These drugs absorb more efficiently in environments that favor their unionized state—acidic for acids and alkaline for bases. Drugs falling outside these pKa ranges, such as stronger acids (pKa < 2.5) and stronger bases (pKa > 11), remain ionized throughout the GI tract, culminating in poor absorption as their ionic forms hinder passive diffusion across lipid membranes. Understanding the relationship between pKa and pH helps optimize drug formulations for targeted dissolution and absorption.

The pharmacokinetic profile of a drug is significantly influenced by its pKa and resultant ionization at physiologically relevant pH levels. In environments where the pH is far from the drug's pKa, the drug becomes highly ionized, increasing its solubility but decreasing membrane permeability. Conversely, it remains largely unionized near the drug's pKa, favoring absorption across biological membranes. As a result, weak acids dissolve better in basic conditions, while weak bases dissolve better in acidic environments, impacting both drug dissolution and bioavailability in the GI tract.

Only non-ionized drugs with high lipid solubility are efficiently absorbed into the systemic circulation. A drug's absorption hinges on its hydrophilic-lipophilic balance (HLB). It implies that a drug needs adequate aqueous solubility to dissolve at the absorption site and sufficient lipid solubility to cross the lipid-rich biomembrane, facilitating entry into the systemic circulation. The lipid solubility is quantified as the partition coefficient (Kow), which is the extent to which a drug distributes between a lipophilic solvent, like n-octanol, and an aqueous phase. Empirically, an octanol/pH 7.4 buffer partition coefficient value between 1 and 2 is sufficient for passive membrane permeability and optimal bioavailability.