manufacturing bioelectronic devices as it is easy to modify and form various structures
with high stability. However, nucleic acid–based bioelectronic devices have some func
tional limitations, such as low signal and electrical properties. Therefore, numerous novel
nanomaterials have been introduced to compensate for these limitations. Table 17.1 shows
representative biomaterials and their characteristics used for developing bioelectronic
devices.
17.3 Nanomaterials for Bioelectronic Devices
17.3.1 Metal Nanomaterials
Metal nanomaterials have received scientific attention for bioelectronic applications due
to their unique physical, optical, and electrical properties. The small size of the metal
nanomaterials (under 100 nm) provides excellent properties compared with bulk-scale
materials and has potential in many biological fields [16]. For example, metal NPs such as
Au, silver (Ag), and platinum (Pt) NPs have been studied due to their optical properties
called surface plasmon resonance (SPR) or localized SPR (LSPR). SPR is one of the unique
phenomena occurring at the nanoscale of noble metal NPs that emits the light combined
with the electron at the surface of the metal NPs to generate strong electron oscillations.
As shown in Figure 17.4a, Bintinger’s group developed a dual monitoring platform by
combining the SPR and electrolyte gate FET (EG-FET) [17]. For this, a 50 nm thin Au layer
was fabricated and was used for a gate electrode and the SPR active interface.
Furthermore, various types of metal nanomaterials have been studied for biosensors
based on the merits of metal nanomaterials such as the excellent catalytic properties, large
surface-to-volume ratio, and easy surface modification, which are also equally useful for
bioelectronics. Jiang’s group reported an easy fabrication strategy of porous noble metal
NPs for biosensing [18]. To fabricate the porous noble metal NPs, laser ablation toward
water (LATW) with dealloying was performed. The fabricated porous noble metal NPs
had 45 times higher local electric field intensity compared with pure noble metal NPs.
In addition, metal nanomaterials in the form of nanorods (NRs) have been hugely studied
[19]. The metal NRs have several exceptional properties such as the efficient surface
plasmon effect that depends on the aspect ratio of the NRs. Besides, numerous metal
TABLE 17.1
Representative Biomaterials and Their Characteristics Used for Developing Bioelectronic Devices
Types
Property
Type of bioelectronic
devices
Reference
Protein
• Redox properties from metal ions inside
metalloproteins
• Biological catalysts in metabolic processes
• Enzymatic reactions with certain substances
• Biomemory
• Biologic gate
• Biotransistor
[ 7– 9]
Nucleic acid • High stability
• Programmable sequences
• Various functionalities (ribozyme,
aptamer, etc.)
• Biomemory
• Biologic gate
• Biotransistor
• Bioprocessor
[ 11– 13], [ 14]
Nanomaterial-Assisted Devices
275