Good manufacturing practice: manufacturing of a nerve agent antidote nanoparticle suspension.

We have established a current good manufacturing practice (GMP) manufacturing process to produce a nanoparticle suspension of 1,1'-methylenebis-4-[(hydroxyimino)methyl]pyridinium dimethanesulfonate (MMB4 DMS) in cottonseed oil (CSO) as a nerve agent antidote for a Phase 1 clinical trial. Bis-pyridinium oximes such as MMB4 were previously developed for emergency treatment of organophosphate nerve agent intoxication. Many of these compounds offer efficacy superior to monopyridinium oximes, but they have poor thermal stability due to hydrolytic cleavage in aqueous solution.

MMB4 DMS nanoparticle suspension formulation with enhanced stability for the treatment of nerve agent intoxication.

Various oximes are currently fielded or under investigation in the United States and other countries as a component of autoinjector emergency treatment systems for organophosphate nerve agent chemical weapons. Bis-pyridinium oximes in general have greater efficacy against a broad spectrum of nerve agents, but they have poor stability due to hydrolytic degradation at elevated temperatures. 1,1'-Methylenebis-4-[(hydroxyimino)methyl]pyridinium dimethanesulfonate (MMB4 DMS) is a leading candidate for next-generation nerve agent treatment systems, because it is more stable than other bis-pyridinium oximes, but it still degrades quickly at temperatures often encountered during storage and field use.

Self-assembling semiconducting polymers--rods and gels from electronic materials.

In an effort to favor the formation of straight polymer chains without crystalline grain boundaries, we have synthesized an amphiphilic conjugated polyelectrolyte, poly(fluorene-alt-thiophene) (PFT), which self-assembles in aqueous solutions to form cylindrical micelles. In contrast to many diblock copolymer assemblies, the semiconducting backbone runs parallel, not perpendicular, to the long axis of the cylindrical micelle. Solution-phase micelle formation is observed by X-ray and visible light scattering.

Synthesis and self-assembly of an amphiphilic poly(phenylene ethynylene) ionomer.

We have synthesized a conjugated amphiphilic polyelectrolyte, a poly(phenylene ethynylene) (PPE), and the structurally analogous neutral polymer. The solution-phase aggregation of the uncharged PPE can be reversibly controlled by varying the solvent polarity and concentration, while the charged polymer appears to self-assemble at any concentration in compatible solvents. These conclusions are based on a combination of absorption and photoluminescence spectroscopy and dynamic light scattering.

An amphiphilic poly(phenylene ethynylene) as the structure-directing agent for periodic nanoscale silica composite materials.

We have synthesized optically active nanostructured composite materials by using an amphiphilic semiconducting polymer, a poly(phenylene ethynylene) (PPE), and a conventional ammonium surfactant as the structure-directing agents. The PPE consists of phenylene units para-substituted with an octyloxy chain and a charged trimethylammoniumethoxy group, resulting in a surfactant-like structure that can assemble into cylindrical micelles. The resulting silica/organic composite material has a hexagonal honeycomb structure with a repeat distance of 45.