Chapter 1.3 Recent developments of nanocomposites and fabrications for biosensor applications
-
T. Senthamil Selvan
Abstract
A biosensor is a particular kind of sensor that recognizes biomaterials or biological entities. In recent, polymer composites have significantly increased their flexibility, sensitivity, and sensitivity for controlling biomolecules. Thus, plenty of desired qualities, a wide range of industries, including biomedicine and environmental analysis, are interested in creating biosensors using polymer composites. In this chapter, the types of composites, biosensors, and the fabrications of biosensors have discussed extensively. More specifically, the direct growth, coating, direct deposition, and printing technologies have been discussed with several informative illustrations. It has been observed that the deposition of thin films of nanoparticles controls a small number of the challenges. In order to create a variety of devices, including biosensors, energy storage devices, and photonics, the electrode’s surface is currently coated or modified using a variety of processes. In this context, proper deposition techniques can solve a number of problems with conventional techniques. Researchers interested in creating cost-effective biosensors will be benefited by this chapter.
Abstract
A biosensor is a particular kind of sensor that recognizes biomaterials or biological entities. In recent, polymer composites have significantly increased their flexibility, sensitivity, and sensitivity for controlling biomolecules. Thus, plenty of desired qualities, a wide range of industries, including biomedicine and environmental analysis, are interested in creating biosensors using polymer composites. In this chapter, the types of composites, biosensors, and the fabrications of biosensors have discussed extensively. More specifically, the direct growth, coating, direct deposition, and printing technologies have been discussed with several informative illustrations. It has been observed that the deposition of thin films of nanoparticles controls a small number of the challenges. In order to create a variety of devices, including biosensors, energy storage devices, and photonics, the electrode’s surface is currently coated or modified using a variety of processes. In this context, proper deposition techniques can solve a number of problems with conventional techniques. Researchers interested in creating cost-effective biosensors will be benefited by this chapter.
Chapters in this book
- Frontmatter I
- Preface V
- Contents VII
-
1 Materials
- Chapter 1.1 Introduction to biomaterials: advances in ceramic and polymer matrix composites 1
- Chapter 1.2 Advanced hydrogels for biomedical applications 23
- Chapter 1.3 Recent developments of nanocomposites and fabrications for biosensor applications 73
- Chapter 1.4 Evolution of metallic dental implants: historical perspective, needs, and application 89
- Chapter 1.5 Tribological behavior of specific implant materials for dental applications 107
-
2 Design
- Chapter 2.1 Patient-specific implant (PSI) design 127
- Chapter 2.2 Modeling techniques of bone tissue scaffolds 167
- Chapter 2.3 Fundamentals of computational modeling of biomechanics in the musculoskeletal system 195
- Chapter 2.4 Computational modeling of bone, muscles, soft tissues, and ligaments 205
- Chapter 2.5 Computational modeling of articular cartilage and cell mechanics 213
- Chapter 2.6 Experimental and computational analysis for osteoporotic fracture implant failure 233
- Chapter 2.7 Computational modeling of fracture implants 239
-
3 Manufacturing
- Chapter 3.1 Patient-specific implant (PSI) by additive manufacturing 249
- Chapter 3.2 Development of artificial skin using composites 273
- Chapter 3.3 Development of nerve tissue replacement using composites 297
- Chapter 3.4 Manufacturing of advanced prosthetic limbs using composites 343
- Index 357
Chapters in this book
- Frontmatter I
- Preface V
- Contents VII
-
1 Materials
- Chapter 1.1 Introduction to biomaterials: advances in ceramic and polymer matrix composites 1
- Chapter 1.2 Advanced hydrogels for biomedical applications 23
- Chapter 1.3 Recent developments of nanocomposites and fabrications for biosensor applications 73
- Chapter 1.4 Evolution of metallic dental implants: historical perspective, needs, and application 89
- Chapter 1.5 Tribological behavior of specific implant materials for dental applications 107
-
2 Design
- Chapter 2.1 Patient-specific implant (PSI) design 127
- Chapter 2.2 Modeling techniques of bone tissue scaffolds 167
- Chapter 2.3 Fundamentals of computational modeling of biomechanics in the musculoskeletal system 195
- Chapter 2.4 Computational modeling of bone, muscles, soft tissues, and ligaments 205
- Chapter 2.5 Computational modeling of articular cartilage and cell mechanics 213
- Chapter 2.6 Experimental and computational analysis for osteoporotic fracture implant failure 233
- Chapter 2.7 Computational modeling of fracture implants 239
-
3 Manufacturing
- Chapter 3.1 Patient-specific implant (PSI) by additive manufacturing 249
- Chapter 3.2 Development of artificial skin using composites 273
- Chapter 3.3 Development of nerve tissue replacement using composites 297
- Chapter 3.4 Manufacturing of advanced prosthetic limbs using composites 343
- Index 357
