A process for preparing an iodinated fatty acid ethyl ester includes steps of subjecting a fatty acid ester to a protonation reaction with phosphoric acid to form a protonated fatty acid ester, and subjecting the protonated fatty acid ester to an iodination reaction with an alkali metal iodide to obtain an iodinated fatty acid ester.

A process includes forming a bio-derived crosslinking material from biorenewable aconitic acid. The process includes initiating a chemical reaction to form a bio-derived crosslinking material that includes multiple functional groups. The chemical reaction includes converting each carboxylic acid group of a biorenewable aconitic acid molecule to one of the multiple functional groups.

A process includes forming a bio-derived crosslinking material from biorenewable aconitic acid. The process includes initiating a chemical reaction to form a bio-derived crosslinking material that includes multiple functional groups. The chemical reaction includes converting each carboxylic acid group of a biorenewable aconitic acid molecule to one of the multiple functional groups.

Methods for mechanochemically synthesizing compositions comprising bridged bicyclic-based compounds such as iptycene-based compounds are generally provided. In some cases, two or more polycyclic aromatic hydrocarbons may be mechanochemically reacted such that the product comprises the bridged bicyclic-based compound. In some embodiments, the product (e.g., the bridged bicyclic compound) may comprise two or more [2.2.2] bicyclic cores. In certain embodiments, the mechanochemical reactions described herein may produce higher order bridged bicyclic-based compounds such as oligoiptcyenes or poly-iptycenes. In certain embodiments, the bridged bicyclic based compound comprises a molecular cage.

Methods for mechanochemically synthesizing compositions comprising bridged bicyclic-based compounds such as iptycene-based compounds are generally provided. In some cases, two or more polycyclic aromatic hydrocarbons may be mechanochemically reacted such that the product comprises the bridged bicyclic-based compound. In some embodiments, the product (e.g., the bridged bicyclic compound) may comprise two or more [2.2.2] bicyclic cores. In certain embodiments, the mechanochemical reactions described herein may produce higher order bridged bicyclic-based compounds such as oligoiptcyenes or poly-iptycenes. In certain embodiments, the bridged bicyclic based compound comprises a molecular cage.

A wetness-retaining ophthalmic lens material comprises an organic monomer, a cross-linking agent, an initiator, a salt, and a solvent. The salt dissolves in the water dissociates a plurality of anions and cations, which bind to water molecules and retard the evaporation of the water molecules, the ophthalmic lens material thus can keep wet for a long time. An ophthalmic lens made of the ophthalmic lens material is also provided.

A wetness-retaining ophthalmic lens material comprises an organic monomer, a cross-linking agent, an initiator, a salt, and a solvent. The salt dissolves in the water dissociates a plurality of anions and cations, which bind to water molecules and retard the evaporation of the water molecules, the ophthalmic lens material thus can keep wet for a long time. An ophthalmic lens made of the ophthalmic lens material is also provided.

A process includes forming a bio-derived crosslinking material from biorenewable aconitic acid. The process includes initiating a chemical reaction to form a bio-derived crosslinking material that includes multiple functional groups. The chemical reaction includes converting each carboxylic acid group of a biorenewable aconitic acid molecule to one of the multiple functional groups.

A process includes forming a bio-derived crosslinking material from biorenewable aconitic acid. The process includes initiating a chemical reaction to form a bio-derived crosslinking material that includes multiple functional groups. The chemical reaction includes converting each carboxylic acid group of a biorenewable aconitic acid molecule to one of the multiple functional groups.

The present invention provides multifunctional monomers, including, but not limited to include multifunctional methylene malonate and methylene beta-ketoester monomers; methods for producing the same; and compositions and products formed therefrom. The multifunctional monomers of the invention may be produced by transesterification or by direct synthesis from monofunctional methylene malonate monomers or methylene beta-ketoester monomers. The present invention further compositions and products formed from methylene beta-ketoester monomers of the invention, including monomer-based products (e.g., inks, adhesives, coatings, sealants or reactive molding) and polymer-based products (e.g., fibers, films, sheets, medical polymers, composite polymers and surfactants).