The present disclosure provides dihydrazone compounds having high affinity to Aβ protein and Tau protein and derivatives thereof. The structure of the compounds is shown by formula (I)

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Provided herein are Myc-Max inhibitory compounds having the structure of Formula (I) and compositions thereof for use in the treatment of cancer. In particular, the Myc-Max inhibitory compounds may be useful for the treatment of cancers selected from one or more of: prostate cancer, breast cancer, colon cancer, cervical cancer, small-cell lung carcinomas, neuroblastomas, osteosarcomas, glioblastomas, melanoma and myeloid leukaemia.

##STR00001##

Provided herein are Myc-Max inhibitory compounds having the structure of Formula (I) and compositions thereof for use in the treatment of cancer. In particular, the Myc-Max inhibitory compounds may be useful for the treatment of cancers selected from one or more of: prostate cancer, breast cancer, colon cancer, cervical cancer, small-cell lung carcinomas, neuroblastomas, osteosarcomas, glioblastomas, melanoma and myeloid leukaemia.

##STR00001##

Embodiments are directed to a series of novel EPAC antagonists that are designed, synthesized and evaluated in an effort to develop diversified analogues based on the scaffold of the previously identified high-throughput (HTS) hit ESI-09.

The present invention provided a continuous flow process for the synthesis of phenylhydrazine salts and substituted phenylhydrazine salts. Diazotization, reduction, acidic hydrolysis and salifying with acids are innovatively integrated together. Using acidic liquids of aniline or substituted aniline, diazotization reagents, reductants and acids as raw materials, phenylhydrazine derivative salts is obtained through the synthesis process, which is a three-step continuous tandem reaction including diazotization, reduction, acidic hydrolysis and salifying. The described synthesis process is a kind of integrated solutions, which is carried out in an integrated reactor. The feed inlets of the integrated reactor are continuously filled with raw materials. In the integrated reactor, diazotization, reduction, acidic hydrolysis and salifying are carried out continuously and orderly, and phenylhydrazine salts or substituted phenylhydrazine salts is obtained in the outlet of the integrated reactor without interruption. The total reaction time is no more than 20 min.

The present invention provided a continuous flow process for the synthesis of phenylhydrazine salts and substituted phenylhydrazine salts. Diazotization, reduction, acidic hydrolysis and salifying with acids are innovatively integrated together. Using acidic liquids of aniline or substituted aniline, diazotization reagents, reductants and acids as raw materials, phenylhydrazine derivative salts is obtained through the synthesis process, which is a three-step continuous tandem reaction including diazotization, reduction, acidic hydrolysis and salifying. The described synthesis process is a kind of integrated solutions, which is carried out in an integrated reactor. The feed inlets of the integrated reactor are continuously filled with raw materials. In the integrated reactor, diazotization, reduction, acidic hydrolysis and salifying are carried out continuously and orderly, and phenylhydrazine salts or substituted phenylhydrazine salts is obtained in the outlet of the integrated reactor without interruption. The total reaction time is no more than 20 min.

Embodiments are directed to a series of novel EPAC antagonists that are designed, synthesized and evaluated in an effort to develop diversified analogues based on the scaffold of the previously identified high-throughput (HTS) hit ESI-09.

The present invention discloses an efficient preparation of 3-amino-1-((2,6-di-substituted)phenyl)pyrazoles.

The present invention discloses an efficient preparation of 3-amino-1-((2,6-di-substituted)phenyl)pyrazoles.

The present invention discloses an efficient preparation of 3-amino-1-((2,6-di-substituted)phenyl)pyrazoles.