Nanorobotics: Advancing Molecular Engineering Through Structural DNA Design

Chapters Brief Overview:

1: Nanorobotics: An introduction to the revolutionary field of nanorobotics and its connection to DNA Origami, highlighting the potential for nanoscale machines.

2: K. Eric Drexler: A deep dive into Drexler’s pioneering work in molecular nanotechnology and how his vision influences the realm of nanorobotics.

3: Simone SchürleFinke: Exploration of SchürleFinke’s contributions to bioengineering and her work with nanorobots in medical applications.

4: Robert Freitas: An overview of Freitas' research on nanomedicine and his proposals for nanorobots within the human body for therapeutic purposes.

5: Nanobiotechnology: The intersection of nanotechnology and biotechnology, emphasizing the role of DNA Origami in creating nanostructures for biomedical applications.

6: Nanomotor: A study of molecular motors at the nanoscale, their construction using DNA Origami, and their potential to power nanobots.

7: Joseph Wang: Insights into Joseph Wang’s work on nanomotors, sensors, and their integration into medical diagnostics and treatment.

8: Ambarish Ghosh: Examination of Ghosh’s contributions to micro and nanorobotics, particularly in the context of biohybrids.

9: Nanocapsule: An overview of nanocapsules for drug delivery, discussing how DNA Origami can be used to create precise drug delivery systems.

10: Nanotechnology: A broad look at the fundamentals of nanotechnology and its various applications, connecting theory to practical implementations in nanorobotics.

11: Molecular machine: A focused discussion on molecular machines, exploring their design, function, and future applications in fields like medicine and manufacturing.

12: Nanoscale plasmonic motor: Exploration of the role of plasmonics in powering nanoscale motors and how DNAbased systems can enable their functionality.

13: DNA nanotechnology: A detailed look at the principles of DNA nanotechnology and its pivotal role in building nanorobots and other nanoscale devices.

14: Biohybrid microswimmer: The concept of biohybrids, combining living cells with synthetic materials, and their potential in medical diagnostics and treatments.

15: Applications of nanotechnology: Examining the realworld applications of nanotechnology in sectors like healthcare, energy, and materials science.

16: Nanomedicine: Focusing on the cuttingedge use of nanotechnology in medicine, including targeted drug delivery and diagnostics, leveraging DNA Origami structures.

17: DNA origami: A comprehensive analysis of DNA Origami as a tool for building nanoscale structures and its significance in the development of nanorobots.

18: Molecular nanotechnology: A discussion on the promises and challenges of molecular nanotechnology, particularly in the context of building machines at the atomic scale.

19: Nanoelectronics: How DNA Origami and nanotechnology can revolutionize electronics, from creating smaller components to enabling new types of devices.

20: Nanotechnology in fiction: A look at how nanotechnology has been portrayed in fiction, offering insights into how these ideas are shaping public perception and future innovations.

21: Microswimmer: The future of microrobots, particularly those that can move through liquids, and how DNA Origami is used to construct these intelligent swimmers.