Learning Outcomes

Introduction to Tissue Engineering and Regenerative Medicine (3 Hours)

• Define tissue engineering and explain its role within regenerative medicine
• Understand the historical evolution and interdisciplinary nature of the field
• Identify the core components of tissue engineering: cells, scaffolds, and signalling molecules
• Explore the current scope, challenges, and future potential of tissue-based medical solutions
• Recognise how tissue engineering contributes to personalised and regenerative therapies

Cell Biology and Sources of Cells for Tissue Engineering (3 Hours)

• Understand the basic structure, function, and behaviour of cells used in tissue engineering
• Identify key cell sources including autologous, allogeneic, and xenogeneic cells
• Explore criteria for selecting appropriate cell types for specific tissues and applications
• Learn fundamental techniques for cell isolation, expansion, and maintenance
• Understand the importance of cell viability, purity, and functionality in tissue development

Scaffold Design and Biomaterial Selection (4 Hours)

• Understand the structural and biological roles of scaffolds in tissue engineering
• Identify commonly used biomaterials, including natural and synthetic polymers
• Explore essential properties such as biocompatibility, biodegradability, and mechanical strength
• Learn how scaffold architecture influences cell attachment and tissue formation
• Recognise the role of material selection in clinical performance and safety

Principles of Cell-Scaffold Interaction (5 Hours)

• Understand molecular and cellular mechanisms of cell–scaffold interactions
• Explore factors influencing cell adhesion, proliferation, and differentiation
• Learn techniques to enhance integration, including surface modification methods
• Evaluate how scaffold porosity, topography, and mechanical cues affect cell behaviour
• Examine experimental methods used to assess cell responses within scaffold environments

Stem Cells and Their Role in Tissue Regeneration (6 Hours)

• Define embryonic, adult, and induced pluripotent stem cells
• Understand stem cell differentiation pathways and regenerative potential
• Explore advantages, limitations, and risks associated with stem cell use
• Learn methods for stem cell sourcing, expansion, and lineage control
• Examine ethical, regulatory, and safety considerations in stem cell research
• Identify clinical examples of stem cell–based tissue engineering applications

Bioreactors and Tissue Culture Techniques (3 Hours)

• Understand the function and design of bioreactors for engineered tissue growth
• Explore different bioreactor systems used for various tissue types
• Learn how culture parameters such as oxygen, flow, and mechanical forces influence development
• Gain familiarity with aseptic techniques and standard tissue culture practices
• Recognise the role of controlled environments in producing functional tissues

Vascularisation and Integration of Engineered Tissues (3 Hours)

• Understand the importance of vascularisation for tissue survival and functionality
• Explore strategies to promote blood vessel formation in engineered constructs
• Learn about host–graft integration and immune response challenges
• Evaluate how growth factors and scaffold design support vascular development
• Recognise current limitations and emerging solutions in tissue integration

Clinical Applications and Case Studies in Tissue Repair (3 Hours)

• Identify current clinical applications in orthopaedics, cardiology, dermatology, and other fields
• Analyse real-world case studies demonstrating successful tissue regeneration
• Understand the pathway of clinical translation from laboratory research to patient care
• Explore barriers to clinical adoption, including scalability, regulation, and cost
• Recognise future trends shaping the clinical impact of tissue engineering