MCP created by chelating single magnesium atom to two molecues of active pharmaceutical

The figure below shows an MCP created by chelating, or binding at multiple sites, a single magnesium atom to two molecules of an active pharmaceutical agent (API).

In its simplest application, metal coordination improves a drug's absorption and delivery without changing the way the drug works once delivered. Orally ingested drugs must typically pass through both a water-based environment (the intestinal tract) and an oil-based environment (the intestinal lining) in route to their intended targets. Most pharmaceutical compounds cannot pass efficiently through both of these environments, and traditional efforts to improve a compound's solubility in one environment typically diminish its solubility in the other. For example, creating a salt of a compound typically increases its water solubility but decreases its ability to pass through oils. Metal coordination, however, can improve solubility in water while maintaining the solubility in oils necessary to permit efficient passage from the digestive tract to the bloodstream and the target cell. The figure below shows the metal ion acting as a "chaperone" that helps the drug enter the bloodstream more quickly and efficiently than it otherwise would.

Metal ion acting as chaperone in MCP

Manipulation of a drug's pharmacokinetics through metal coordination can provide clinically significant benefits. With MCP we have demonstrated the following performance enhancements:

Torkel Gren on Metal Coordinated Pharmaceuticals


Metal coordinated pharmaceuticals (MCPs) can be used to overcome specific clinical deficiencies of currently marketed products as well as those in development. Our lead drug candidate, MCP-311, provides a new solution to extending the absorption phase of levodopa using the bioadhesive properties of a bismuth-levodopa co-polymer. This allows a reduction in pulsatility of levodopa plasma levels to achieve continuous dopaminergic stimulation for Parkinson's disease patients. Alterations of physicochemical properties that accompany the coordination of a metal to a drug can improve the drug's amphiphilicity (achieving improved solubility in both aqueous and lipid environments) and which can be applied to achieve a faster onset of action, minimize absorption variability and improve drug distribution from blood to target organs such as lungs. One drug Synthonics worked with could only be given intravenously in a solution with an uncomfortably high pH. Our chemistry was able to improve water solubility to allow dissolution at more neutral pH ranges. Thus, an orally administered drug could now be given parenterally. In other applications, metal coordination can enable two drugs to be delivered simultaneously to exploit synergistic activity and to prevent systemic absorption when the drug needs to remain in the lumen of the GI tract. As we expand our research, we continue to find new applications for MCPs to solve problems related to pharmacokinetic properties that lead to other clinical deficiencies.

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