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Synthetic peptides are short chains of amino acids carefully engineered in the laboratory to aid in various fields of research and development. In the body, peptides play many roles - as hormones, enzymes, signaling molecules, immune modulators, etc. Advances in synthetic peptide technology have greatly facilitated the study of these biomolecules, allowing scientists to explore their structures, functions, and potential uses. In addition, synthetic peptides allow scientists to precisely mimic the functions of natural proteins and peptides, making them useful in many applications, especially in pharmaceuticals and cosmetics.
At Creative Enzymes, we provide high quality synthetic peptides for pharmaceutical and cosmetic needs. Our peptides support everything from drug discovery to the development of skincare products such as anti-aging solutions. We focus on consistent quality so that each product works effectively. Partner with us to achieve reliable results and meet your specific goals.
A peptide is a chemical molecule consisting of two or more amino acids linked by peptide bonds. Peptides are shorter and simpler than proteins, which are complex macromolecules with specific three-dimensional structures that perform specific physiological functions.
The term "synthetic peptides" refers specifically to peptides that are artificially synthesized, allowing their properties to be studied in isolation from other cellular components. Unlike naturally occurring peptides, synthetic peptides can be modified to study specific interactions, processes, and functions. That's why they are widely used as probes, drugs, diagnostic tools and in vaccine development.
The synthesis of synthetic peptides involves the sequential addition of amino acids, typically using a process known as solid-phase peptide synthesis (SPPS). This method, developed by Robert Bruce Merrifield in 1963, revolutionized peptide synthesis, making it faster, more accurate, and widely accessible.
In SPPS, the peptide chain is attached to an insoluble resin, allowing easy separation of the growing peptide from soluble reagents and by-products. The basic steps of SPPS include:
SPPS is unique in its ability to automate and efficiently generate peptides with precise sequences. Techniques such as Fmoc (fluorenylmethyloxycarbonyl) and Boc (t-butyloxycarbonyl) provide selective deprotection steps that minimize the risk of unwanted reactions.
Fig. 1: Scheme of solid-phase peptides synthesis (SPPS) on a resin as solid support with protected amino acids. The deprotection is usually done using a base such as piperidine. This is followed by a coupling step (a protected amino acid is added) to the growing peptide chain. Coupling reagents (e.g. HBTU, HATU, or DIC) are employed to help form the peptide bond. The final deprotection is followed by a cleavage.
This approach is less common than SPPS, but works well for synthesizing very short peptides or peptides with difficult sequences. Instead of building peptides on a solid support, the process takes place in solution. It is limited in that separating the intermediates and purifying the final product can be tricky and time-consuming compared to solid-phase synthesis.
Based on their purpose, structure and functional modifications, synthetic peptides can be categorized:
Synthetic peptides are becoming increasingly popular in the pharmaceutical world, due to their precision, effectiveness, and ability to be tailored for specific purposes. Here's how they're commonly used:
In the cosmetic industry, synthetic peptides are widely used in skincare and anti-aging products due to their bioactivity and ability to penetrate the skin. Key applications include:
In summary, synthetic peptides have had a major impact on research and industry by providing precise control over biological and chemical processes. Using methods such as solid-phase peptide synthesis, researchers can create peptides in almost any sequence or structure. They can even modify them to increase stability, binding affinity, and specificity.
With years of experience and state-of-the-art facilities, Creative Enzymes delivers synthetic peptides that meet the highest standards of purity, stability, and bioactivity. Contact us today to explore how our synthetic peptides can enhance your research and product development initiatives!
/images/7-5-synthetic-peptide-2.jpgCatalog | Product Name | EC No. | CAS No. | Source | Price |
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CECP-016 | Trifluoroacetyl Tripeptide-2 | 64577-63-5 | Inquiry | ||
CECP-015 | Palmitoyl Tripeptide-38 | 1447824-23-8 | Inquiry | ||
CECP-014 | Palmitoyl Hexapeptide-12 | 171263-26-6 | Inquiry | ||
CECP-013 | Palmitoyl Tripeptide-5 | 623172-56-5 | Inquiry | ||
CECP-012 | Palmitoyl Tripeptide-1 | 147732-56-7 | Inquiry | ||
CECP-011 | Palmitoyl Tetrapeptide-7 | 221227-05-0 | Inquiry | ||
CECP-010 | Palmitoyl Pentapeptide-4 | 214047-00-4 | Inquiry | ||
CECP-009 | Anti-Wrinkle Complex Peptide | Inquiry | |||
CECP-008 | Firming Peptide Complex | Inquiry | |||
CECP-007 | Melittin | 31014-78-5 | Inquiry | ||
CECP-006 | Decarboxy Carnosine | 57022-38-5 | Inquiry | ||
CECP-005 | Arginine Lysine Polypeptide | 31014-78-5 | Inquiry | ||
CECP-004 | Acetylhexapeptide-8 | 616204-22-9 | Inquiry | ||
CECP-003 | Dipeptide Diaminobutyroyl Benzylamide Diacetate | 823202-99-9 | Inquiry | ||
CECP-002 | Acetyl Octopeptide-3 | 868844-74-0 | Inquiry | ||
CECP-001 | Acetyl Hexapeptide-8 | 616204-22-9 | Inquiry |