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Synthesis of complex molecules displaying potential biological and catalytic activity

Research team at Nagoya Institute of Technology enables access to complex chiral materials with biological and catalytic activities

Nagoya Institute of Technology

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IMAGE: Authors successfully synthesized high yields of chiral 2-imidazolines (α,β-Tetra-substituted imidazolines) from Ketimins and isocyanides via direct catalytic Mannich reaction. This approach can be a clue to develop novel and effective... view more

Credit: NITech

Nagoya, Japan - Chiral molecules possess asymmetry; like left and right hands, their mirror images cannot be superposed. Molecules with identical chemical makeup but different chirality can display different activity. Therefore, chirality is an important factor in areas such as biology, chemistry, and pharmacology. Synthesis of molecules with specific chirality can be difficult; however, it is an important target of many chemists as they seek to obtain desired materials.

A trio of researchers at the Nagoya Institute of Technology has now synthesized a variety of chiral molecules using the catalytic Mannich reaction. The findings, reported in the Royal Society of Chemistry's ChemComm, show that the synthesized chiral molecules contain imidazoline rings--five-membered rings containing two nitrogen and three carbon atoms. Materials containing these rings are potentially useful as catalysts and pharmaceutical agents.

The researchers found that the catalytic Mannich reaction is an effective method to synthesize chiral imidazolines from α-isocyanoacetates and ketimines. This is an important finding because ketimines are generally considered poor starting materials because of their low reactivity and weak ability to form selected chiral molecules.

In their synthetic approach, the researchers first determined the optimal conditions to achieve high yields of imidazolines with specific types of chirality.

"Performing the Mannich reaction with a certain cinchona alkaloid catalyst gave a product with high stereoselectivity, so molecules with a desired specific configuration were generated," lead author Shuichi Nakamura explains. "Using a different catalyst gave the corresponding product with the opposite chirality."

Through investigation of the optimal reaction conditions, the team then performed the catalytic Mannich reaction using a variety of different isocyanoacetates and ketimines. They found that the reaction progressed well for many of these materials to provide chiral products with high yield and stereoselectivity. The products were then converted into chiral imidazolines by removing a protecting group.

"Until now, no method had successfully synthesized vicinal tetrasubstituted imidazolines effectively and efficiently. This is the first example of highly stereoselective synthesis of imidazolines through reaction of non-activated ketimines with isocyanides," Nakamura says.

The group's findings reveal a new route to obtain complex, versatile materials from starting materials with low reactivity.

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This research was conducted at the Frontier Research Institute for Materials Science (FRIMS), which was launched in 2015. FRIMS focuses on synthesizing novel functional materials useful in green, energy, and health sciences. FRIMS promotes international collaboration by inviting international researchers to participate in research activity.

The article "Enantioselective construction of imidazolines having vicinal tetra-substituted stereocenters by direct Mannich reaction of α-substituted α-isocyanoacetates with ketimines" was published in ChemComm at DOI: 10.1039/c6cc02911f

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