of the computer that conducts logical operations including AND, NOR, and OR logic
functions through the conversion of input signals to the one binary output signals. These
logical operations can be demonstrated by using enzymatic reactions for implementing
Boolean functions on biochips to develop a biologic gate. For instance, by combining
various enzymes (e.g., lactate dehydrogenase, LDH) and their reactions, output signals
from logic operations were determined by added input substances (e.g., lactate) to de
monstrate certain logic gates such as AND or NAND gates (Figure 17.2c) [9]. However, as
discussed previously, bioelectronic devices implemented using only proteins have lim
itations such as weak signals or difficulties in implementing into more complex electronic
devices and the inherent instability of biomaterials. Recently, a lot of research on the
fusion of protein-based electronic devices and nanomaterials has been conducted, which
will be the focus of later sections.
17.2.2 Nucleic Acid–Based Bioelectronic Devices
A transistor is one of the most essential electronic devices that can amplify or switch
current to operate a computing system. The increase of transistor density is an important
issue because Si-based electronic devices typically face physical limitations at sizes below
100 nm. Therefore, the demand for materials that can replace Si is increasing, and nucleic
acids are one of the most attractive candidates for replacing Si due to their unique
properties such as charge transfer and molecular rectification [10].
Gottarelli’s group developed the field-effect transistors (FETs) using guanosine
(Figure 17.3a) [11]. Guanosine has the lowest oxidation potential among the nucleobases
and a unique sequence of hydrogen bonding sites. The low oxidation potential of gua
nosine is suitable for charge carrier transport and forms long ribbon-shaped supramo
lecular assemblies via hydrogen bonding. In addition, a strong dipole moment can be
formed along the ribbon axis, which induces a commutation of the current for enhancing
the transistor density. Stefanović’s group developed an array of three ribozyme-based
biologic gates to realize an artificial decision-making network in a biocompatible and
autonomous manner (Figure 17.3b) [12]. A Boolean algebra was performed with a total of
three fluorescence dye–modified ribozymes by applying two ribozymes for the XOR gate
construction and another ribozyme for the AND gate construction to generate different
outputs. Two oligonucleotides were used as random two inputs, which allosterically
activate the ribozyme. The output was also an oligonucleotide, and two different col
orimetric fluorescence detection systems had applied to distinguish these two output
values. In addition, Lee’s group fabricated a global positioning system (GPS) using a
DNA bioprocessor that designated two physical locations, the current location of the
processor and the final destination, and specified the optimal or shortest route based on
the six routes stored in the database (Figure 17.3c) [13]. For simplicity, the map was
simplified into six main pieces of information. An indication that connected the physical
location with the connection route was made by utilizing the length of single-stranded
DNA, which represents the length of the linkage pathway.
In addition, Suyama’s group has developed a biomemory using DNA hybridization [15].
The memory strand was composed of DNA with a hairpin structure. The data strand
consisted of “address” and “content,” where the address was a linear DNA sequence that
can complementarily be hybridized with the memory strand, and the content was a DNA or
RNA sequence (state 1). “Writing” and “erasing” of the DNA-based biomemory were
performed by temperature control. The data strand was hybridized with the memory
strand as the hairpin structure of the memory strand changed by writing temperature (TW)
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