Learning Outcomes:
1. Understand the fundamental principles of tissue engineering, including the utilization of cells, biomaterials, and biochemical and physicochemical factors to restore, maintain, improve, or replace biological tissues.
2. Integrate knowledge from biology, chemistry, and engineering subjects to comprehend the multidisciplinary nature of tissue engineering.
3. Analyze current tissue engineering strategies and technologies, evaluating their efficacy and potential for the future of regenerative medicine.
4. Demonstrate proficiency in advanced techniques essential for tissue engineering and regenerative medicine, such as culturing cell lines and stem cells with emphasis on aseptic technique, biochemical analysis, and statistics.
5. Evaluate scaffold design and fabrication methods, as well as the role of growth factors and signaling pathways in tissue regeneration processes.
6. Critically assess the regenerative potential of tissue engineering products across various tissues, including skin, bone, heart, and cancer models.
7. Engage in active discussion and participation in class, analyzing and discussing experimental papers related to tissue engineering topics.
8. Develop scientific inquiry skills by critically evaluating experimental papers, identifying strengths, weaknesses, and potential areas for further investigation.
9. Cultivate a mindset of scientific inquiry and skepticism, thinking critically about tissue engineering concepts and research questions.
10. Apply learned knowledge and skills to identify unstudied areas in tissue engineering, develop grant proposals for funding, and present ideas to peers and a panel of "grant reviewers".
Overall, students will develop a comprehensive understanding of tissue engineering principles and techniques, as well as the ability to critically evaluate and contribute to advancements in the field.