Abstract EN:

Diabetes II relate too million people in the world. The existing drugs show limits in their capacity to effectively control the disease and their side effects are one of the important concerns. Synthesis of (2S,3R,4S)-4-OH-Ile, whose antidiabetic activity was proven, and of its analogues is already developped by process which can’t be set up on an industrial scale. Three original synthetic approaches were developped. In a first part, we developped a racemic synthesis based on isoxazole, an intermediate key. The second strategy, adapted to an industrial application is based on the enantioselective reaction of Barbas III between an α--imino-ester and methyl ethyl ketone catalysed by L-proline. This way leads in 6 steps to the (2S,3R,4S)-4-OH-ILe with 22% over yield. The third approach rests on the reaction of hydrogenation of Noyori on (trichloromethyl)carbinol compounds. This pathway is still studied at the laboratory. Second, we investigated the synthesis of analogs of (2S,3R,4S)-4-OH-Ile. A racemic compound functionalized in 4 position by an aldehydic group is synthetised according to the Barbas III reaction. Then, we synthesized gem dimethyl analogs in 3 and 4 positions, whose synthesis is based on Barbier reaction and a diastereoselective iodolactonisation reaction. We synthesized bioisosteres compounds, particularly, synthesis of a mono fluorinated compound in 4 position, according to the reaction of Barbas III, then a gem dlifluorinated compound in 3 position based on the Reformatsky reaction and phosphonate and tetrazole, isosteric group of the acid function. The biological tests of these analogs are in hand and two patents are currently in the course of deposit.