to convert brittle inorganic materials into flexible systems, maintaining their electronic
mobility and stability. In inorganic systems, flexibility may achieve by reducing the
thickness and elasticity through the design of undulating structures; moreover, flexible
inorganic systems are usually supported or encapsulated in polymeric materials [5]. On
the other hand, organic bioelectronics materials are those based on carbon, generally
conductive polymers or allotropes of carbon such as graphene or carbon nanotubes, these
materials tend to have higher biocompatibility due to their mechanical properties are
compatible with biological tissues; besides, they have greater versatility of manufacturing
than inorganic materials.
In the classification according to the application, bioelectronics materials may be grouped
into three areas; the electronic materials to solve medicine and biology problems, which
include the detection and characterization of biological materials at the cellular and sub
cellular level, some examples are materials for electroactive scaffolds, photostimulation, or
drug delivery; biological systems used in electronics application, i.e., new electronic com
ponents from biological systems; and materials to interface electronic devices with living
systems, such as neural interface electrodes, optical implants, and biosensors for monitoring
physiological functions, through the measurement of electrophysiological signals, biophy
sical signals (temperature, pressure) and signals biochemical (through body fluids) [6].
2.2 Classification of Bioelectronics Materials According to Their
Composition
According to their composition, bioelectronics materials can be classified into organic or
inorganic. Organic bioelectronics materials for technological applications are common
because of their high biocompatibility. For example, semiconductors and conductors in
electronics and microelectronics interact with biological tissues and usually require some
flexibility and moldability, as well as strength and long cycle life. Therefore, a polymer
matrix is the best option in delicate biological systems. On the other hand, inorganic
semiconductors and conductors provide unique mechanical and conduction properties as
supercapacitors used in bioelectronics tissues. Both inorganic and organic materials must
have biocompatibility as well as functionality for their implementation in bioelectronics
applications and subsequently in living tissue. This section shows the characteristics and
the progress in the bioelectronics application of each material.
2.2.1 Inorganic Bioelectronics Materials
Among the existing materials, such based on inorganics represent an emerging and re
levant area of research for application in bioelectronics. They can be configured to
harmlessly dissolve, resorb or just degrade at nanometric/molecular scale, as temporary
biomedical implants or environmental sensors. These kinds of materials have been pro
posed to manufacture deformable and flexible devices, with conductivity, semi-
conductivity, or at least with transduction and energy storage [5]. Inorganic bioelectronics
materials preparation is based on micro-fabrication (film deposition, lithography), and
their successful application depends basically on the type of transfer of the inorganic
function from the substrate to the desired target and a stable communication pathway
between the nervous system and electronic devices [7].
Materials and Their Classifications
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