Compounds of Formula I and the pharmaceutically acceptable salts thereof are disclosed Formula I. The variables X.sup.1, X.sup.2, and R.sup.1-4 are disclosed herein. The compounds are useful for treating cancer and related proliferative diseases. Pharmaceutical compositions containing compounds of Formula I and methods of treatment comprising administering compounds of Formula I are also disclosed.

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Compounds of Formula I and the pharmaceutically acceptable salts thereof are disclosed Formula I. The variables X.sup.1, X.sup.2, and R.sup.1-4 are disclosed herein. The compounds are useful for treating cancer and related proliferative diseases. Pharmaceutical compositions containing compounds of Formula I and methods of treatment comprising administering compounds of Formula I are also disclosed.

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The invention discloses a composition comprising surface modified iron oxide nanoparticles with citric acid modified cyclodextrin with a hydrodynamic diameter of less than 10 nm and a hydrophobic molecule.

The composition finds use in targeted delivery of a hydrophobic drug and as contrast agent in imaging applications.

The present invention relates to the novel use of saponins having acetyl residues on one of their sugar residues. These saponins are able to enhance the transfection efficiency to a surprisingly much higher extent than already known saponins and even than Lipofectamin.

A gel type local anesthetic agent of the present invention is a local anesthetic agent consisting of a local anesthetic having a tertiary amine and glycyrrhizic acid in which the local anesthetic and glycyrrhizic acid are gelated to form a gel type.

A gel type local anesthetic agent of the present invention is a local anesthetic agent consisting of a local anesthetic having a tertiary amine and glycyrrhizic acid in which the local anesthetic and glycyrrhizic acid are gelated to form a gel type.

A multidimensional nanoconstruct includes a three-dimensional thiolated protein, gelatin or polymer nanoparticle and exposed metallic nanoparticles bonded to outer surfaces of the particle. In a method of formation, number of metallic nanoparticles that attach to the carrier nanoparticle is controlled via microfluidics or via controlling the reactivity of the metallic nanoparticle and carrier nanoparticle.

A multidimensional nanoconstruct includes a three-dimensional thiolated protein, gelatin or polymer nanoparticle and exposed metallic nanoparticles bonded to outer surfaces of the particle. In a method of formation, number of metallic nanoparticles that attach to the carrier nanoparticle is controlled via microfluidics or via controlling the reactivity of the metallic nanoparticle and carrier nanoparticle.

A multidimensional nanoconstruct includes a three-dimensional thiolated protein, gelatin or polymer nanoparticle and exposed metallic nanoparticles bonded to outer surfaces of the particle. In a method of formation, number of metallic nanoparticles that attach to the carrier nanoparticle is controlled via microfluidics or via controlling the reactivity of the metallic nanoparticle and carrier nanoparticle.

The present application relates to brush amphiphilic block copolymers comprising at least one block which is hydrophilic and at least another block which is hydrophobic. The block copolymers can be used to prepare nanoparticles for biomedical applications including delivery of pharmaceuticals and other bioactive agents