Unlock Your Health Potential with Ademetionine Disulfate Tosylate
Discover the scientifically backed benefits for liver health, mood, and neurological support.
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Ademetionine Disulfate Tosylate
Ademetionine Disulfate Tosylate, also known as SAMe Tosylate, stands as a highly stable and biologically active derivative of S-Adenosylmethionine. It is an essential co-substrate fundamental to numerous critical biochemical processes within the body, primarily functioning as a vital methyl donor. Its significance extends deeply into pharmaceutical research, where it is instrumental in exploring the intricate mechanisms of liver function, the complexities of neurological disorders, and developing effective treatments for depression.
- Researching depression mechanism involves understanding how Ademetionine Disulfate Tosylate influences neurotransmitter pathways.
- Explore neurological studies to uncover the compound's role in supporting brain health and function.
- The stable S-adenosylmethionine form ensures reliability in various scientific applications.
- Investigating hepatoprotective effects is a key area where this compound demonstrates considerable promise.
Key Advantages
Enhanced Stability
The tosylate salt form of Ademetionine provides superior stability, crucial for reliable research applications in cellular metabolism and age-related disease studies.
Multi-Pathway Involvement
This compound plays significant roles in transmethylation, transsulfuration, and aminopropylation pathways, offering broad utility in biochemical research.
High Purity Assurance
Ensuring high purity means Ademetionine Disulfate Tosylate delivers dependable performance in sensitive cell culture studies and enzymatic assays.
Key Applications
Liver Function Research
Aiding in the understanding of liver disease and potential therapeutic avenues through detailed investigation of its biochemical role.
Neurological Studies
Investigating its impact on brain chemistry and function, offering insights into treatments for various neurological conditions.
Depression Mechanism Research
Exploring its influence on mood regulation and its potential as a component in future mood disorder treatments.
Epigenetic Modifications
Studying its role in epigenetic processes, which are vital for gene expression regulation and cellular health.