Beta Alanine CAS 107-95-9 Pharma Powder Raw Materials

CAS: 107-95-9

MF:  C3H7NO2

EINECS:  203-536-5

Specification​: 99% min Beta Alanine

Sample: Beta Alanine Powder

Brand: Henrikang

Appearance: White Powder

Storage: Cool Dry Place

Shelf Life: 2 Years

Test Method: HPLC

Portal:https://henrikang.en.made-in-china.com/

Beta Alanine Powder Usage and Synthesis.

Beta Alanine Powder is a non-essential amino acid and a neurotransmitter. It plays an important role in muscle tissue and can improve muscle endurance and It plays an important role in muscle tissue and can improve muscle endurance and exercise capacity. In addition, Beta Alanine CAS 107-95-9 promotes the secretion of human growth hormone, which helps enhance muscle growth and repair.
Beta Alanine Raw Materials can be consumed through foods such as meat, fish, dairy products and legumes. Beta Alanine Raw Materials is mainly used as a raw material for the synthesis of calcium pantothenate, and is also used as an electroplating corrosion inhibitor and biochemical reagent.

Application/Function of Beta Alanine Powder.

Beta Alanine Powder is mainly used as a raw material for the synthesis of calcium pantothenate for pharmaceutical and feed additives, and is also used as an electroplating corrosion inhibitor and biochemical reagent.

Beta Alanine Powder is mainly used in the synthesis of pantothenic acid and calcium pantothenate, myostatin, pamidronate sodium, balsalazide, etc. It is widely used in the fields of medicine, feed and food. It is also used as electroplating corrosion inhibitor and biochemical reagent.

Beta Alanine Powder is used as endogenous beta-amino acid for food and health product additive use, non-selective glycine receptor agonist, G-protein coupled orphan receptor (TGR7, MrgD) ligand. Relying on supporting the osmotic stabilization of marine organisms, the

Beta Alanine efflux exerts a cytoprotective effect.

Mechanism of action of Beta Alanine Powder:

Beta-alanine is a non-essential amino acid that can be synthesized through food or metabolic pathways in the body. Its mechanism of action in human body is mainly as follows:

• 1. Promote muscle growth and repair: Beta-alanine is an important muscle growth and repair factor, which can promote the synthesis and repair of muscle cells, and also increase muscle strength and endurance.
• 2. Reduce fatigue and improve exercise capacity: β-alanine can reduce muscle fatigue and soreness, improve exercise capacity and endurance, and also promote muscle recovery and repair.
• 3. Promote protein synthesis: β-alanine can promote protein synthesis, thus increasing muscle mass and physical performance.
• 4. Lower blood sugar and cholesterol: Beta-alanine can lower blood sugar and cholesterol levels, thereby preventing and treating related diseases.

In conclusion, beta-alanine has a wide range of effects in the human body, the main effects are to promote muscle growth and repair, reduce fatigue and improve exercise capacity, promote protein synthesis, lower blood sugar and cholesterol levels, etc.

Preparation process of Beta Alanine Powder.

Beta Alanine can be prepared in a variety of ways, the most common of which is through microbial fermentation. The specific steps are as follows:

• 1. Select a suitable microbial strain, such as bacteria belonging to the genera Corynebacterium, Bacillus, Pseudomonas, etc.
• 2. Establish the strain and pre-culture it.
• 3. Prepare fermentation medium, including carbon source, nitrogen source, minerals, etc.
• 4. Inoculate the precultured strains into the fermentation medium and carry out fermentation.
• 5. Adjust the fermentation conditions, such as temperature, pH, oxygen supply, etc., to promote the production of β-alanine.
• 6. Monitor and control during the fermentation process to ensure the yield and quality of β-alanine.
• 7. After fermentation, bacterial isolation and extraction and purification of β-alanine are carried out.

In addition to microbial fermentation, there are also chemical synthesis and enzymatic methods for the preparation of β-alanine.

Acrylonitrile is reacted with ammonia in diphenylamine and tert-butanol solution to produce β-aminopropionitrile, which is then subjected to alkaline digestion. Add acrylonitrile, diphenylamine and tert-butanol in turn in a dry autoclave, stir for 5min, add liquid ammonia, control temperature 100-109℃, pressure about 1MPa, keep warm and stir for 4h. Cool to below 10℃, stop stirring when the pressure drops to atmospheric pressure.
At 65-70℃/(8.0-14.7kPa), recover tert-butanol under reduced pressure to obtain crude β-aminopropionitrile, and then distill the crude product under reduced pressure and collect 66-105℃/(1.33-4.0kPa) fraction to obtain β-aminopropionitrile.
The operation of alkaline decomposition is carried out in the reaction tank, the first input liquid alkali, control temperature 90-95 ℃ - stirring slowly add β-aminopropionitrile drop by drop, after addition, holding time 1h. evaporate under reduced pressure for half an hour to drive off the ammonia in the reaction solution, add appropriate amount of water, add hydrochloric acid drop by drop to pH 7-7.2. filter, remove a small amount of insoluble impurities.
The filtrate is concentrated under reduced pressure until a large number of solids are precipitated, discharged while hot, cooled to below 10℃, filtered and dried under vacuum to obtain β-alanine. The method consumes 982kg of β-aminopropionitrile per ton of product, and the yield of alkaline solution stage is 90%.