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BOC Sciences is one of the world's leading biotechnology companies, dedicated to providing high-quality biomimetic peptide synthesis and manufacturing services. With years of experience and advanced technology, we offer comprehensive peptide synthesis solutions for scientific research, pharmaceuticals, clinical studies, and industrial applications. Whether it's small-scale custom synthesis or large-scale production, BOC Sciences can meet customer needs and provide tailored services. Our biomimetic peptide synthesis services combine innovative technologies, stringent quality control, and excellent customer support to ensure product efficiency, purity, and stability.
At least two rounds of lyophilization to achieve complete sterility.
Strict endotoxin control standards, generally below 2 IU.
No residual solvents are allowed.
A biomimetic peptide is a synthetic peptide designed by mimicking the structure and function of natural peptides or proteins. These peptides can replicate specific biological functions or characteristics observed in natural peptides, such as cell signaling, tissue regeneration, antimicrobial activity, or skin regeneration. Currently, biomimetic peptides can be prepared through chemical synthesis or plant extracts. Chemical synthesis methods include solid-phase peptide synthesis (SPPS) and liquid-phase peptide synthesis, while plant extracts utilize peptides from natural sources. Biomimetic peptides have high biological activity, good cell compatibility, and permeability, allowing them to act quickly and effectively on target sites with minimal irritation. Therefore, biomimetic peptides have wide applications in medicine, cosmetics, and materials science, including drug delivery systems, wound healing therapies, anti-aging skincare products, and tissue engineering biomaterials.
Biomimetic peptides are small molecules synthesized through chemical or biotechnological methods that mimic the structure and function of natural peptides. They offer advantages such as high biological activity, strong stability, and low immunogenicity. BOC Sciences provides a full range of biomimetic peptide synthesis and manufacturing services, from design to production. Our services cover all stages, including initial peptide sequence design, synthesis optimization, and large-scale production, ensuring customers receive high-quality biomimetic peptide products.
In the medical aesthetics field, BOC Sciences' core competitiveness lies in GMP-compliant production and the development of innovative therapies:
Custom amino acid sequences are designed according to customer needs, optimizing hydrophobicity, charge distribution, and secondary structure to enhance transdermal absorption or targeting specificity.
Using automated solid-phase synthesis platforms, we support rapid scale-up from laboratory (milligram) to industrial (kilogram) levels, shortening the R&D cycle.
These include PEGylation (polyethylene glycolylation), bioconjugation (e.g., binding with liposomes or nanoparticles), and isotope labeling, enhancing the drug's long-acting properties or tracking capabilities.
We provide solutions for co-formulation with ingredients such as polysaccharides, hyaluronic acid, etc., to enhance transdermal absorption. For example, our curcumin (Turmerone) complex peptide formulation offers both anti-inflammatory and anti-aging effects.
Our products are GMP, ISO 9001, and FDA certified, ensuring sterility and batch consistency.
By leveraging the synergistic effects of stem cell molecules and biomimetic peptides, we develop biomaterials that promote epidermal repair. For example, biomimetic collagen peptide scaffolds can accelerate wound healing and reduce scar formation.
BOC Sciences provides professional quality testing services for biomimetic peptides, ensuring compliance with industry standards. In quality control, we utilize HPLC, LC-MS, and GC-MS for purity analysis, ensuring a purity >95% and compliance with ICH Q3C standards. MS and NMR are used for structural confirmation, covering molecular weight, peptide sequence, 3D structure, and conformation analysis. Our GMP facilities feature clean rooms ranging from Class 100 to 100,000, supporting preclinical to commercial production and meeting FDA inspection requirements. In functional testing, we conduct bioactivity assays to evaluate properties such as the cytotoxicity of anticancer peptides and the antimicrobial activity of antimicrobial peptides. Additionally, stability studies simulate various conditions (temperature, pH, light, etc.) to assess chemical and biological stability, providing data for storage and application. Pharmacokinetics studies evaluate absorption, distribution, metabolism, and excretion (ADME) through in vitro and in vivo experiments, offering essential insights for drug development.
Demand Analysis and Consultation
Peptide Synthesis Design
Synthesis and Modification
Purification and Characterization
Quality Control and Testing
Delivery and Ongoing Support
Rich Project ExperienceBOC Sciences has years of peptide synthesis experience, accumulating extensive technical knowledge and practical expertise to tackle a variety of complex synthesis challenges.
Advanced EquipmentBOC Sciences is equipped with advanced synthesis and analytical equipment, such as automated peptide synthesizers, high-resolution mass spectrometers, and NMR instruments, ensuring the efficiency and precision of the synthesis process.
Strict Quality ControlBOC Sciences has established a stringent quality control system, with rigorous quality checks at every stage, from raw material procurement to final product delivery, ensuring high quality and consistency of the products.
Flexible Service ModelsBOC Sciences offers flexible service models, allowing customers to select services such as custom synthesis, large-scale production, and quality control, to meet the research and production needs at different stages.
Biomimetic peptides excel in anti-aging and wrinkle reduction. They stimulate the synthesis of collagen and elastin, enhancing skin elasticity and reducing wrinkles and fine lines. For example, Palmitoyl Pentapeptide-4 can mimic collagen fragments, activating skin repair mechanisms; Acetyl Hexapeptide-8 reduces muscle contractions by inhibiting neurotransmitter release, alleviating dynamic wrinkles. These biomimetic peptides are safe and effective, significantly improving skin aging issues and becoming core ingredients in anti-aging products.
Biomimetic peptides play an important role in skin repair and barrier enhancement. They promote epidermal cell regeneration, accelerate the healing of damaged skin, and strengthen the skin barrier to reduce moisture loss. For example, copper peptides repair damaged tissues and improve skin health through antioxidant and anti-inflammatory effects. Biomimetic peptides are also suitable for sensitive and damaged skin, helping restore the skin's natural defense mechanisms and improving overall skin quality.
Biomimetic peptides demonstrate unique advantages in whitening and evening skin tone. They inhibit the activity of tyrosinase, reducing melanin production, thereby brightening the complexion and fading spots. For example, Oligopeptide-1 regulates melanogenesis, improving uneven skin tone. The whitening mechanism of biomimetic peptides is gentle yet effective, making them suitable for long-term use to achieve a clear and even skin tone without the irritation often caused by traditional whitening ingredients.
Biomimetic peptides are gaining attention in hair care and scalp health. They stimulate follicle cell activity, promote hair growth, repair damaged hair, and enhance hair elasticity. For example, bioactive peptides can penetrate deep into the scalp, improving blood circulation and delaying hair loss. Additionally, biomimetic peptides have anti-inflammatory and antioxidant properties, soothing scalp sensitivity and reducing dandruff, providing comprehensive care for both hair and scalp.
Biomimetic peptides play a crucial role in minimally invasive anti-wrinkle treatments. They are commonly used in post-treatment care for procedures like microneedling and laser treatments, promoting collagen synthesis and cell regeneration to enhance treatment effects. For example, Acetyl Hexapeptide-8 reduces dynamic wrinkles, while copper peptides accelerate skin repair, reducing redness and dryness after treatment. The efficacy and safety of biomimetic peptides make them an ideal auxiliary ingredient for minimally invasive anti-wrinkle treatments.
Biomimetic peptides show excellent results in post-surgical recovery. They accelerate wound healing, reduce post-surgical inflammation, and prevent pigmentation. For example, copper peptides promote cell proliferation and angiogenesis, significantly shortening recovery time. Biomimetic peptides also have strong anti-inflammatory and antioxidant properties, relieving post-surgical redness and discomfort, helping the skin quickly recover to a healthy state, and becoming a key ingredient in post-medical aesthetic care.
Biomimetic peptides are highly effective in scar repair. They stimulate collagen remodeling and cell regeneration, improving the appearance of scars. For example, copper peptides promote tissue repair and reduce scar hyperplasia. Biomimetic peptides are also effective for treating acne scars, surgical scars, and other types of scars, helping restore skin smoothness. Their gentle nature makes them a safe and effective solution for scar repair.
Injectable peptide-based hydrogels represent a cutting-edge application of biomimetic peptides in medical aesthetics. These hydrogels self-assemble from biomimetic peptides, offering excellent biocompatibility and biodegradability. They can be used to fill wrinkles, repair tissue defects, or serve as drug delivery carriers, gradually releasing active ingredients. For example, peptide-based hydrogels can mimic the extracellular matrix, promoting tissue regeneration while providing long-lasting repair effects, making them an important development direction in future cosmetic and medical repair applications.
Biomimetic peptides are produced through a combination of bioengineering and chemical synthesis. Scientists first identify natural peptides with specific biological functions, such as collagen or elastin, and then use SPPS to replicate their sequences. This method involves gradually building the peptide chain on a solid resin, allowing precise control over the amino acid sequence. Alternatively, recombinant DNA technology can be used to insert the gene encoding the target peptide into bacteria or yeast, which then produce the peptide in large quantities. After synthesis, the peptide is purified and modified to enhance stability and functionality, ensuring it effectively mimics natural biological processes.
Biomimetic peptides are designed to mimic the structure and function of natural peptides in the body. They perform various functions, such as promoting tissue repair, stimulating collagen production, enhancing skin elasticity, and supporting wound healing. In skincare products, they work by simulating the effects of proteins like collagen and elastin to reduce wrinkles and improve skin texture. In the medical field, they can act as antimicrobial agents, anti-inflammatory compounds, or even targeted drug delivery systems. By replicating natural biological processes, they hold significant value in both cosmetic and therapeutic applications, providing solutions for aging, disease, and tissue regeneration.
Biomimetic peptides are generally considered safe when used appropriately. Since they are designed to mimic naturally occurring peptides in the body, they are typically well-tolerated and have low toxicity. However, safety depends on factors such as the peptide's structure, concentration, and method of use. Extensive in vitro and in vivo studies are conducted to ensure their biocompatibility and effectiveness. In skincare products, they are usually included in formulations at low concentrations to minimize the risk of irritation. While adverse reactions are rare, individuals with sensitive skin or allergies should perform a patch test before use. Overall, biomimetic peptides represent a promising and safe option in both cosmetic and medical applications.
