Protein Engineering for Pharmaceutical Biotechnology Training Course: Understand How to Advance Therapeutic Development and Industrial Applications (Jan 21st - Jan 22nd, 2026) - ResearchAndMarkets.com

DUBLIN--(BUSINESS WIRE)--The "Protein Engineering for Pharmaceutical Biotechnology Training Course (Jan 21st - Jan 22nd, 2026)" training has been added to ResearchAndMarkets.com's offering.

Enhance your knowledge in protein engineering to understand how to advance therapeutic development and industrial applications.

Protein-based therapeutics have significantly advanced and created new paradigms in disease treatment. Half of the top ten selling drugs in 2023 were protein-based therapeutics.

Protein engineering, a field perfected by nature over billions of years, can now be replicated and customised in the laboratory within weeks. This course aims to equip professionals with the skills to develop more valuable and better-featured proteins, particularly enzymes, for a wide range of pharmaceutical applications.

By understanding and applying the latest advancements in molecular biology, protein chemistry, enzymology, and structural chemistry, attendees will be able to create practical solutions that meet the needs of the pharmaceutical sector. The significance and timelessness of this training are underscored by the 2018 Nobel Prize for Chemistry, awarded for groundbreaking work in protein engineering, highlighting its growing importance and potential to revolutionise various industries.

Benefits of attending

• Deepen your understanding of protein engineering concepts, enhancing your expertise in molecular biology, protein chemistry and enzymology
• Stay updated with the latest advancements in protein engineering, including CRISPR-Cas9 gene editing, phage display for protein-protein interactions, and mRNA therapeutics, keeping you at the forefront of the field
• Explore the development and application of protein-based therapeutics such as bispecific antibodies, antibody fragments, mRNA vaccines, antibody-drug conjugates, and antibody-directed enzyme pro-drug therapy
• Discover how protein engineering is used in biotechnology, including the development of genetically modified organisms (GMOs), biopharmaceuticals, directed evolution for enzyme production, and industrial enzymes

Who Should Attend:

This course is designed for professionals with a foundational understanding of biochemistry and molecular biology, seeking to deepen their knowledge and understanding in protein engineering, including:

• Biotechnology professionals
• Regulatory affairs professionals
• Pharmaceutical development specialists
• Quality assurance and control officers
• Clinical researchers
• Process development engineers
• Project managers

Certifications:

• CPD: 12 hours for your records
• Certificate of completion

Key Topics Covered:

Day 1

Introduction to protein engineering

• Definition and Overview: What is Protein engineering?
• Proteins and their structure-function relationship
• Historical Background: Milestones in Protein engineering and biotechnology in pharmaceuticals

Techniques and tools in genetic engineering

• CRISPR-Cas9
  • Mechanisms and applications in gene editing
• Recombinant DNA Technology
  • How genes are spliced and introduced into host organisms
  • Mutagenesis techniques, site-directed, random mutagenesis
• Gene cloning
  • Cloning vectors, host organisms, and production of recombinant proteins
• Gene expression systems
  • Bacterial, yeast, and mammalian cell expression systems for protein production
• RNA interference (RNAi)
  • Mechanisms and therapeutic use for gene silencing in diseases

Pharmaceutical applications of protein engineering

• Biopharmaceuticals
  • Production of therapeutic proteins (e.g., insulin, human growth hormone)
  • Monoclonal antibodies (mAbs) for cancer, autoimmune diseases, etc.
• Gene therapy
  • Correcting genetic disorders by inserting or modifying genes (e.g., treatments for hemophilia, cystic fibrosis)
  • CRISPR-based gene editing for inherited diseases
• Vaccines
  • Development of recombinant vaccines (e.g., hepatitis B vaccine)
  • mRNA vaccines (e.g., COVID-19 vaccines)

Production of biopharmaceuticals

• Bioreactors and fermentation
  • Use of genetically engineered microorganisms to produce drugs in large quantities
• Downstream processing
  • Purification and scaling up of genetically engineered drugs
• Quality control
  • Ensuring purity, potency, and safety of biopharmaceutical products

Day 2

Ethical and regulatory considerations

• Ethics of genetic and protein engineering
  • Ethical concerns surrounding genetic modifications in humans, animals, and microorganisms
• Regulatory frameworks
  • FDA, EMA, and other global regulatory bodies for approving genetically engineered drugs
• Intellectual property
  • Parenting genetically engineered products and processes

Advances in protein engineering for pharmaceuticals

• CRISPR-based therapies
  • Engineering proteins for diagnostics
  • Clinical trials and potential cures for genetic diseases
• Synthetic biology
  • Designing new biological systems for drug production and personalised medicine
• Personalised medicine
  • Tailoring treatments based on individual genetic profiles
• Biologics vs. small molecule drugs
  • Differences and advantages of biologics developed through genetic engineering

Challenges in protein engineering for pharmaceuticals

• Safety Concerns
  • Off-target effects in gene editing and immune responses to engineered proteins
• Cost and accessibility
  • High production costs and making therapies accessible to a wider population
• Scalability
  • Challenges in producing genetically engineered drugs on a large scale

Case studies and examples

• Insulin production
  • How genetically engineered bacteria produce human insulin
• Gene therapy success stories
  • Examples of successful gene therapies (e.g., Luxturna for inherited retinal disease)
• Monoclonal antibodies
  • Their role in treating cancers and autoimmune diseases

Engineering modern drugs and targeted cancer therapy

• Checkpoint inhibitors
• CAR-T cancer therapy
• Antibody-drug conjugates (ADC)
• Antibody Directed ProDrug Therapy (ADEP)

Engineering of superantigens for targeted cancer therapy

For more information about this training visit https://www.researchandmarkets.com/r/oc785t

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