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The chemical compound N-BOC-M-PHENYLENEDIAMINE, commonly referred to as N-Boc-Me-Ph, is a synthetic amino acid used in the pharmaceutical and chemical industries.
Its unique properties make it a versatile building block for the synthesis of various compounds, including antibiotics, anticancer drugs, and other chemicals.
N-Boc-Me-Ph is a derivate of phenylenediamine, which is a synthetic amino acid with a wide range of applications in various fields.
The N-BOC group is a protecting group that is used to protect the amino nitrogen during chemical reactions.
The Boc stands for "tert-Butyl- protected" which is a protecting group used to protect the amino nitrogen atom from undesired chemical reactions, whereas the M-Ph refers to the modification of the para- position of the phenyl ring with a benzyl group.
The production process of N-Boc-Me-Ph involves several steps, including the synthesis of phenylalanine, the addition of the Boc group, and the modification of the para-position of the phenyl ring with a benzyl group.
The synthesis of phenylalanine, which is a basic building block for the production of N-Boc-Me-Ph, can be done through different methods, but the most common one is the hydrolysis of toluene diamine.
Once the phenylalanine is synthesized, the next step is the addition of the Boc group.
This is done by treating phenylalanine with dicyclohexylcarbodiimide (DCC) and hydroxybenzene sulfonate (HBS) in the presence of a catalyst.
The Boc group is then released by treating the compound with a base, such as sodium hydroxide.
The final step in the production of N-Boc-Me-Ph is the modification of the para-position of the phenyl ring with a benzyl group.
This is done by treating the compound with benzyl chloride in the presence of a catalyst, such as aluminum chloride.
Once N-Boc-Me-Ph is synthesized, it can be used as a building block for the synthesis of various compounds.
It can be used to produce antibiotics, anticancer drugs, and other chemicals.
It can also be used in the production of research chemicals and intermediates for the pharmaceutical industry.
One of the main advantages of N-Boc-Me-Ph is its stability and ease of handling.
The Boc group is a protecting group that is easily removed under mild conditions, making it a versatile building block for the synthesis of various compounds.
Additionally, the para-benzyl modification of the phenyl ring provides additional stability and protection to the compound during chemical reactions.
Another advantage of N-Boc-Me-Ph is its wide range of applications.
It can be used in the production of antibiotics, anticancer drugs, and other chemicals, making it a versatile building block for the pharmaceutical and chemical industries.
In conclusion, N-Boc-Me-Ph is a versatile building block in the pharmaceutical and chemical industries.
Its unique properties make it a useful building block for the synthesis of various compounds, including antibiotics, anticancer drugs, and other chemicals.
The production process of N-Boc-Me-Ph is relatively simple and straightforward, and can be performed on a large scale.
Additionally, the stability and ease of handling of N-Boc-Me-Ph make it an ideal building block for various chemical reactions.
