Synthesis of arylboronate esters and biaryl compounds

Technology Overview: 

Aryl boronate esters and biaryls are of interest for certain pharmaceutical and electronic material applications. Penn scientists have developed a chemical methodology for the sequential Ni-catalyzed borylation with a novel in-situ prepared reagent and Ni-catalyzed cross-coupling to form biaryls. This process is useful for the production of aryl boronate esters and biaryl compounds, key chemical building blocks and intermediates for the Sukuzi cross-coupling process. 

Early results suggest that the process can be implemented as a three-step one-pot methodology comprising two-stages, one-pot in-situ preparation of neopentylglycolborane coupled with Ni-catalyzed borylation of aryl halides followed by complementary Ni/Pd-catalyzed cross-coupling with aryl bromides, iodides, chlorides mesylates, and tosylates. The latter two aryls are inexpensive coupling partners with arylboronic acids and provide a desirable method of carbon-carbon bond formation starting from phenols. 

This complementary approach gives rise to the rapid synthesis of biaryls, and demonstrates the synthetic competitiveness of in situ prepared neopentylglycolborane versus that of tetra(alkoxy)diboron derivatives.

Advantages: 

• The use of Ni-based catalyst, neopentylglycolborane, and simple dppe and dppp ligands, reduce the cost compared to diboron or Pd-based catalyst methods.
• Novel reagent, neopentylglycolborane, has potential or broad applicability, including metal-catalyzed borylation as well as uncatalyzed hydroboration.
• One pot method reduces time required and processing demands to reach the end product.

Applications: 

• Novel boronic acids and boronic esters for the synthesis of pharmaceuticals and other fine chemicals, in particular those with sensitive functionality.
• Processing of biaryls and potentially heterobiaryls for liquid crystalline systems, organic and polymer light emitting diodes (O/PLEDS) and other organic electronic materials.
• The stability of neopentylglycolborane in solution should allow for its production, storage, and likely purification and commercialization of the reagent.

Stage of Development: 

Demonstrated in laboratory conditions with a wide array of substrates as well as various bases, catalysts, and ligands, showing range of applicability.

Intellectual Property: 

US  8,530,689 

Reference Media: 

• Rosen, BM et al.; Org Lett; 2008 May 17; 10(12): 2597.
• Wilson, DA et al.; Org Lett, 2008 Nov 6 10(21): 4879.

Desired Partnerships: 

• License
• Co-development

Docket # U4807