This book provides a comprehensive overview of analytical techniques for applications in biomedical nanotechnology, at both the fundamental and applied level. It includes a discussion of how fundamental knowledge of techniques can be translated to applications, coverage of state-of-art analytical techniques, and the prospects and challenges of each technique.

Nanotechnology is essential in the development of advanced technologies for medicine and healthcare. Advances depend on the ability to study these materials and nano-biotechnologies using advanced analytical techniques. Providing a comprehensive overview of analytical techniques for applications in biomedical nanotechnology at both the fundamental and applied level, this book provides a broad perspective of the development of analytical methods involved in materials science and electronics. It highlights the fundamentals and systematic developments of techniques to achieve better characterisation, rapid diagnostics, cost-effective and user-friendly approaches, and state-of-art methodologies for personalised health management, and explains how this fundamental knowledge can be translated into applications in nano-enabled biomedical research. The multidisciplinary readership includes chemists, biologists, physicists, materials scientists, engineers and information technologists.

Key Features

• Provides a comprehensive overview of analytical techniques for applications in biomedical nanotechnology at both the fundamental and applied level
• Explains how fundamental knowledge of the techniques can be translated to applications in nano-enabled biomedical research
• Covers state-of-art analytical techniques for biomedical nanotechnology
• Includes the prospects and challenges with each technique, including potential solutions
• Provides a multidisciplinary view of interest to chemists, biologists, physicists, materials scientists, engineers and information technologists

1 Emergence of analytical techniques

2 Electrochemical techniques for biomedical nanotechnology

3 UV–visible spectroscopy in biomedical nanotechnology

4 FTIR spectroscopy and microscopy in biomedical nanotechnology

5 Raman spectroscopy and microscopy in biomedical nanotechnology

6 Quartz crystal microbalance for biomedical nanotechnology

7 Application of nuclear magnetic resonance spectroscopy in biomedical nanotechnology

8 Mass spectroscopy in biomedical nanotechnology

9 Magnetic measurement systems for biomedical nanotechnology

10 Application of x-ray diffraction for biomedical nanotechnologies: current insights and perspectives

11 Scanning electron microscopy for biomedical nanotechnology

12 Transmission electron microscopy for biomedical nanotechnology

13 Energy dispersive spectroscopy for biomedical nanotechnology

14 Atomic force microscopy for biomedical nanotechnology

15 Microfluidics system for biomedical nanotechnology

16 Dynamic light scattering (DLS) particle size analysis for biomedical nanotechnology

17 Zeta potential measurements and analysis for biomedical nanotechnology

18 Electron paramagnetic (spin) resonance spectroscopy for biomedical nanotechnology

19 X-ray photoelectron spectroscopy for biomedical applications

20 AI and IOT for biomedical smart applications

21 Summary and aspects of techniques for biotechnology report