This chapter presents an overview of bioelectronics’ underlying theory and practical
applications, focusing on fundamental concepts, materials, fabrication, and testing of
bioelectronic tools.
1.2 Fundamental Concepts of Bioelectronics
Multidisciplinary research fields including electrical engineering, biology, chemical, and
physical science, and material science are required to fully realize the promise of bioe
lectronics. Even though the field of bioelectronic medicine is still in its infancy, the op
portunities and hopes it inspires are vast. A revolution in medical practice, not an
innovation, is what bioelectronic medicine is all about. New bioelectronics disciplines
have the potential to have an enormous influence on a wide range of national priorities,
including healthcare and medicine, homeland security, forensics, and environmental and
food supply protection. The synergy between electronics and biology might be greatly
enhanced with the evolution of electronic technology to the atomic scale, as well as major
advances in system, cell, and molecular biology. A lab-on-a-chip for a clinic for medical
diagnosis, and real-time detection of biological agents would eliminate the need for a
laboratory in the next decades. This section will introduce the reader to the principles of
working with bio-interfaces, which are junctions between different materials and biolo
gical structures. The discussion of the size and time of interactions, material selection, and
the basic biophysical ideas is highlighted to explain how biological events happen and
how their signals can be interpreted in terms of bioelectronics.
1.2.1 Bioelectronics with a Size Scale
When designing the bio-interfaces, it is important to consider the length scale of the
interface to effectively address the relevant biological events. These can range from
the large area with non-specific modulation to micro-sensing and everything in between
(Figure 1.2a). Electrodes with a large surface area were the first such device developed
and still in use. There are many more frequently used advanced techniques available like
electroencephalography (EEG) to record brain activity through the scalp, electro
cardiography (ECG) to monitor cardiac activity, and electromyography (EMG) to record
skeletal muscle activity [2].
The advances in materials research have opened the door to the possibility of con
structing probes with higher resolution that can be placed closer to the active cells, en
abling the creation of smaller and less invasive devices to be built. The first phase was the
development of direct bio-interfaces with a single organ, which was completed in two
stages. The second step was the establishment of indirect bio-interfaces with a single
organ. Because of these efforts, artificial pacemakers, cochlear implants, and deep-brain
stimulation probes have all been produced, and they have helped millions of people live
longer, better lives. Probes have shortened in size and grown more adaptable, which has
resulted in an improvement in the biocompatibility of electrical devices [3–5]. They
opened up an entirely new viewpoint on the study of cell physiology since micron-sized
devices were able to detect local electric potential deep within tissues while also inter
acting with small groups of cells, making them an invaluable tool in the field. To operate
at this scale, it is required to consider major chemical interactions between the materials
Introduction to Bioelectronics
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