9.2.1.1 Mimicking the SA Receptors – Static Force Transduction
Sensors are made up of a variety of materials such as polyurethane, polydimethylsiloxane
(PDMS), and poly (styrene-butadiene-styrene). The working of these sensors is based on
two phenomena, piezocapacitive, and piezoresistive. In capacitance sensors, a change in
capacitance occurs under the pressure because of the compression of the dielectric film.
The films can be the air gap, elastomer, and microfluidic channel [5]. The sensitivity of a
sensor has been reportedly improved by using the array of PDMS film as a dielectric
layer. The shaped and structured layer deformed under the pressure as compared to its
shapeless design. The structured film detected the pressure up to 3 Pa with enhanced
sensitivity of 0.55–1 kPa. The microstructuring of the biocompatible materials as sensor
show quick response time and excellent sensitivity. In piezoelectric sensors, resistance
change under pressure takes place due to two mechanisms. In the first, the gap between
conductive fillers changes by applying the pressure that results from the increase of the
number of conductive pathways. In the second mechanism, the microstructured dielectric
film contains an additional deposited film of a conductive layer that interfaces the elec
trode. An applied pressure deforms the microstructure hence leading to the increase of
contact area and decrease of contact resistance [6]. These resistive-based sensors are
simple, sensitive, and require only a readout circuit. The piezoelectric sensor made up of
poly(ethylene dioxythiophene)–poly(styrene sulfonate) with an aqueous polyurethane
dispersion elastomer layered on the micro-pyramid array shows a sensitivity up to
4.88 kPa−1 [7]. This sensor can detect an arterial pulse. A variety of microstructures such
as micropillars, microstructures, and interlocked structures has improved the sensitivity
and linearity of resistive-based sensors. In piezocapacitive sensors and piezoelectric
sensors, mechanical signals are transduced into electrical signals, while pressure values
correspond to the capacitance and resistance, respectively [8].
9.2.1.2 Mimicking the Rapid Adapting (RA) Receptors – Dynamic Force Transduction
RA receptors are more responsive toward the stimuli to detect the vibrations and move
ment of the body while triboelectric and piezoelectric sensors are more sensitive to rapid
dynamic motion. The piezoelectric sensor deals with the intrinsic properties of the material
in which applied force changes the lattice of the materials. A variety of inorganic and soft
materials has been used in energy systems and pressure sensors to enhance the response
time and sensitivity. In triboelectric sensors, the loss of electrons takes place in materials
through triboelectrification and electrostatic induction. In electrification, two surfaces
contact and separate by periodic force; hence, charges separate after induction and current
flows. The triboelectric sensor responds to the pressure, in which frequency, force, and
separation distance affect the output. Electrostatic induction can be improved by the ad
dition of ionic liquid, microstructural designs, and surface treatment of the materials [9].
Self-powered flexible devices developed by triboelectric effect can be used in wearable
electronics for the next generation. Recently, various kinds of tactile sensors as flexible
devices (Table 9.1) have been developed that demonstrate better sensing to human skin.
9.2.1.3 Biomimetic Sensors
Biomimetic sensors are kind of sensors that uses designated biomaterials and biomimetic
approaches similar to those of biological system. These sensors consist of voltammetric,
potentiometric, and impedance phenomena. The electronic skin, taste sensors (sweetness,
bitterness, sourness, saltiness, umami), odor sensor, cochlear amplifier, and cochlear
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Bioelectronics