1. Health Biotechnology Stem Cell Therapeutics; Tissue Engineering LECTURE 21: Biotechnology; 3 Credit hours Atta-ur-Rahman School of Applied Biosciences (ASAB) National University of Sciences and Technology (NUST)

2. In vitro fertilization (IVF) is a process by which an egg is fertilized by sperm outside the body Those embryos that can't be used clinically are a reliable source for embryonic stem cell derivation

6. Applications of Human pluripotent stem Cells Basic Knowledge of Human Development Models of Human Disease Transplantation-Cell Replacement Drug Development Organogenesis

7. Tissue Engineering Tissue engineering is an emerging interdisciplinary field that applies the principles of biology and engineering to the development of viable substitutes that restore, maintain, or improve the function of human tissues.

8. Tissue Engineering Tissue Engineering is the study of the growth of new connective tissues, or organs, from cells to produce a fully functional organ for implantation back into the donor host. For transplantation, to reduce the rejection it can remain isolated from host tissue Hence it’s a substitute for damaged tissues and organs

9. Cells Signals Scaffold Tissue Engineering Requires Three Things

10. Cells for Tissue Engineering Stem Cells an unspecialized cell that gives rise to differentiated cells  Two basic types:  Embryonic – pluripotential  Adult – multipotential

11. Signals Molecule The signals refer to molecular signaling molecules, also known as growth factors Tissue inducing compounds such as growth factors can serve as signals to simulate the growth and development of different tissue Interleukins Interferons Cytotoxins Colony Stimulating Factors Growth Factors Suppressor, Inhibitory Factors

12. Signals Molecule Stimulate or inhibit – Cell proliferation – Differentiation – Migration – Adhesion – Gene expression – Secretion and action of other growth factors

13. Scaffold Isolated cells can be grown on extra cellular matrix, collagen or synthetic polymer Cell growth and differentiation in 2D cell culture and 3D organ culture, requires presence of structured environment with which cells can interact Tissue along with polymer can be implanted into the patient Polymers may either be non-degradable and remain in the patent permanently or disappear over the period of time

14. Scaffold Various textures and materials Encourage cells to grow Allow nutrients to permeate Won’t harm the patient

15. Tissue Engineering Using well designed scaffolds and optimized cell growth, we can create tissues such as: – Skin – Bone – Cartilage – Intestine These have been successfully engineered to some extent

16. More complex organs Not very far in development Complex metabolic functions Require multiple types of cells and intricate scaffolds – Liver – Heart – Lung – Kidney

17. To make a bladder one need a scaffold and several different type of cells

18. Tissue Engineering for Polio A virus attacks cells in the spinal cord – Signal no longer sent to muscles in the leg – Muscle wasting occurs Stem cell treatment could – encourage new spinal neurons to grow – help new muscle to grow

19. Tissue Engineering for Diabetes

20. Usually for by-pass operation Tissue Engineering for Artificial Vessels