Provided is a method for producing glycine, in which on synthesizing glycine from glycinonitrile, glycine can be obtained in a higher yield than that in the conventional method. The present invention relates to a method for producing glycine, including allowing glycinonitrile and water to react with each other in the presence of a cerium compound, optionally adding ammonia thereto, to obtain glycine.

Provided is a method for producing glycine, in which on synthesizing glycine from glycinonitrile, glycine can be obtained in a higher yield than that in the conventional method. The present invention relates to a method for producing glycine, including allowing glycinonitrile and water to react with each other in the presence of a cerium compound, optionally adding ammonia thereto, to obtain glycine.

The present disclosure discloses salts formed by 2-(1-acyloxy-n-pentyl)benzoic acid and basic amino acid or aminoguanidine, a preparation method thereof, pharmaceutical preparations containing these salts, and application thereof in preparation of drugs for preventing or treating ischemic cardiovascular and cerebrovascular diseases, resisting thrombosis and improving cardio-cerebral circulation disorders. The compound of the present disclosure has excellent water solubility, aqueous solution stability and pharmacokinetic properties, also has significant anti-platelet aggregation, anti-thrombosis, anti-cerebral ischemia and neuroprotective activity. The compound of the present disclosure has significantly better effects than those of (S)-butylphthalide and potassium (R/S)-2-(1-hydroxy-n-pentyl) benzoate (PHPB), has significantly lower acute toxicity to mice by intravenous injection than that of butylphthalide and PHPB, has a lower inhibition rate of the hERG potassium channel in CHO-hERG cells than that of (S)-butylphthalide, and has a negative result in Bacterial Reverse Mutation Test (Ames test).

The present disclosure discloses salts formed by 2-(1-acyloxy-n-pentyl)benzoic acid and basic amino acid or aminoguanidine, a preparation method thereof, pharmaceutical preparations containing these salts, and application thereof in preparation of drugs for preventing or treating ischemic cardiovascular and cerebrovascular diseases, resisting thrombosis and improving cardio-cerebral circulation disorders. The compound of the present disclosure has excellent water solubility, aqueous solution stability and pharmacokinetic properties, also has significant anti-platelet aggregation, anti-thrombosis, anti-cerebral ischemia and neuroprotective activity. The compound of the present disclosure has significantly better effects than those of (S)-butylphthalide and potassium (R/S)-2-(1-hydroxy-n-pentyl) benzoate (PHPB), has significantly lower acute toxicity to mice by intravenous injection than that of butylphthalide and PHPB, has a lower inhibition rate of the hERG potassium channel in CHO-hERG cells than that of (S)-butylphthalide, and has a negative result in Bacterial Reverse Mutation Test (Ames test).

The present disclosures are directed to processes for synthesizing (S)-2-(((S)-6,8-difluoro-1,2,3,4-tetrahydronaphthalen-2-yl)amino)-N-(1-(2-methyl-1-(neopentylamino)propan-2-yl)-1H-imidazol-4-yl)pentanamide (“nirogacestat”).

The present disclosure discloses salts formed by 2-(1-acyloxy-n-pentyl)benzoic acid and basic amino acid or aminoguanidine, a preparation method thereof, pharmaceutical preparations containing these salts, and application thereof in preparation of drugs for preventing or treating ischemic cardiovascular and cerebrovascular diseases, resisting thrombosis and improving cardio-cerebral circulation disorders. The compound of the present disclosure has excellent water solubility, aqueous solution stability and pharmacokinetic properties, also has significant anti-platelet aggregation, anti-thrombosis, anti-cerebral ischemia and neuroprotective activity. The compound of the present disclosure has significantly better effects than those of (S)-butylphthalide and potassium (R/S)-2-(1-hydroxy-n-pentyl) benzoate (PHPB), has significantly lower acute toxicity to mice by intravenous injection than that of butylphthalide and PHPB, has a lower inhibition rate of the hERG potassium channel in CHO-hERG cells than that of (S)-butylphthalide, and has a negative result in Bacterial Reverse Mutation Test (Ames test).

The present disclosure discloses salts formed by 2-(1-acyloxy-n-pentyl)benzoic acid and basic amino acid or aminoguanidine, a preparation method thereof, pharmaceutical preparations containing these salts, and application thereof in preparation of drugs for preventing or treating ischemic cardiovascular and cerebrovascular diseases, resisting thrombosis and improving cardio-cerebral circulation disorders. The compound of the present disclosure has excellent water solubility, aqueous solution stability and pharmacokinetic properties, also has significant anti-platelet aggregation, anti-thrombosis, anti-cerebral ischemia and neuroprotective activity. The compound of the present disclosure has significantly better effects than those of (S)-butylphthalide and potassium (R/S)-2-(1-hydroxy-n-pentyl) benzoate (PHPB), has significantly lower acute toxicity to mice by intravenous injection than that of butylphthalide and PHPB, has a lower inhibition rate of the hERG potassium channel in CHO-hERG cells than that of (S)-butylphthalide, and has a negative result in Bacterial Reverse Mutation Test (Ames test).

The present disclosures are directed to processes for synthesizing (S)-2-(((S)-6,8-difluoro-1,2,3,4-tetrahydronaphthalen-2-yl)amino)-N-(1-(2-methyl-1-(neopentylamino)propan-2-yl)-1H-imidazol-4-yl)pentanamide (“nirogacestat”).

The present disclosures are directed to processes for synthesizing (S)-2-(((S)-6,8-difluoro-1,2,3,4-tetrahydronaphthalen-2-yl)amino)-N-(1-(2-methyl-1-(neopentylamino)propan-2-yl)-1H-imidazol-4-yl)pentanamide (“nirogacestat”).

Provided is a method for producing glycine, in which on synthesizing glycine from glycinonitrile, glycine can be obtained in a higher yield than that in the conventional method. The present invention relates to a method for producing glycine, including allowing glycinonitrile and water to react with each other in the presence of a cerium compound, optionally adding ammonia thereto, to obtain glycine.