1. Therapeutic Peptides

Therapeutic peptides are one of the most exciting areas of innovation, with significant progress in drug development and clinical applications.

Key Advances:

Cancer Therapy:

Peptide-based cancer vaccines (e.g., targeting tumor-specific antigens).

Peptide-drug conjugates (PDCs) for targeted drug delivery.

Examples: LHRH agonists for prostate cancer, somatostatin analogs for neuroendocrine tumors.

Diabetes and Obesity:

GLP-1 receptor agonists (e.g., semaglutide, liraglutide) for diabetes and weight management.

Dual-agonist peptides targeting multiple metabolic pathways.

Infectious Diseases:

Antimicrobial peptides (AMPs) as alternatives to traditional antibiotics.

Peptides targeting viral proteins (e.g., HIV, SARS-CoV-2).

Cardiovascular Diseases:

Peptides targeting blood pressure regulation (e.g., angiotensin-converting enzyme inhibitors).

Neurological Disorders:

Peptides for Alzheimer’s disease, Parkinson’s disease, and pain management.

Innovations:

Oral Peptide Drugs: Overcoming bioavailability challenges through chemical modifications and advanced delivery systems.

Peptide Mimetics: Designing non-peptide molecules that mimic peptide structure and function.

Multifunctional Peptides: Combining therapeutic and diagnostic capabilities (theranostics).

2. Peptide Engineering and Design

Advances in peptide engineering have enabled the creation of peptides with enhanced stability, specificity, and functionality.

Key Technologies:

Computational Design:

Using AI and machine learning to predict peptide structures and interactions.

Examples: AlphaFold for protein structure prediction, peptide docking algorithms.

Chemical Modifications:

Cyclization, PEGylation, and incorporation of non-natural amino acids to improve stability and bioavailability.

Peptide Libraries:

High-throughput screening of peptide libraries to identify bioactive sequences.

Applications:

Drug Discovery: Identifying novel peptide leads for therapeutic targets.

Biomaterials: Designing peptides for tissue engineering and regenerative medicine.

Catalysis: Developing peptide-based enzymes (pepzymes) for industrial applications.

3. Peptide Delivery Systems

Effective delivery of peptides remains a challenge due to their susceptibility to degradation and poor absorption. Innovations in delivery systems are addressing these issues.

Key Advances:

Nanoparticles: Encapsulating peptides in nanocarriers for targeted delivery.

Oral Delivery: Developing formulations that protect peptides from digestive enzymes and enhance intestinal absorption.

Transdermal Delivery: Using microneedles or patches for peptide delivery through the skin.

Cell-Penetrating Peptides (CPPs): Enhancing the cellular uptake of therapeutic peptides.

4. Peptides in Diagnostics and Imaging

Peptides are being used as tools for disease detection and imaging.

Applications:

Biomarkers: Identifying peptide biomarkers for early disease detection.

Imaging Agents: Developing peptide-based probes for MRI, PET, and fluorescence imaging.

Biosensors: Using peptides in biosensors for real-time monitoring of biological processes.

Why work with us

☆ Customer service

We offer high-quality products and stand for trusting and long-term partnerships. Our customers value our broad knowledge, our experience and our expertise in the field of peptide development and production.

☆ Reliability

Quality Manager ensures that production remains at the highest level through development, quality control and regulatory processes

☆ Sustainability

We believe that ethical behavior and integrity are essential to long-term corporate success. That's why we continually monitor and improve our social, economic and environmental performance.