Modeling and Fabrication of a Piezoelectric Artificial Cochlea Electrode Array With Longitudinal Coupling

Saadatzi, Mohammadsadegh; Saadatzi, Mohammad Nasser; Banerjee, Sourav

doi:10.1109/jsen.2020.2996192

Cited by 12 publications

(9 citation statements)

References 26 publications

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“…In addition, we compared our ABM with the existing literatures on ABM development using PVDF. Saadatzi et al (2020) developed the ABM with PVDF plates and gold electrodes mounted on the PDMS elastomer matrix. This ABM showed five channels of frequency separation characteristics within the frequency range of 3 to 8 kHz.…”

Section: Discussionmentioning

confidence: 99%

“…The basal membrane in the cochlear has a trapezoid structure, which is narrow and thick in the base, and wide and thin in the apex. Due to its physical and structural features, the basal membrane acts as a frequency analyzer that shows frequency selectivity (Saadatzi et al, 2020). On the base, the maximal displacement of BM is shown for the high frequency sound, and the maximal displacement at the apex is shown for the low frequency sound.…”

Section: Introductionmentioning

confidence: 99%

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Development and Characterization of a Biomimetic Totally Implantable Artificial Basilar Membrane System

Chung

Jung

Hur

et al. 2021

Front. Bioeng. Biotechnol.

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Cochlear implants (CIs) have become the standard treatment for severe-to-profound sensorineural hearing loss. Conventional CIs have some challenges, such as the use of extracorporeal devices, and high power consumption for frequency analysis. To overcome these, artificial basilar membranes (ABMs) made of piezoelectric materials have been studied. This study aimed to verify the conceptual idea of a totally implantable ABM system. A prototype of the totally implantable system composed of the ABM developed in previous research, an electronic module (EM) for the amplification of electrical output from the ABM, and electrode was developed. We investigated the feasibility of the ABM system and obtained meaningful auditory brainstem responses of deafened guinea pigs by implanting the electrode of the ABM system. Also, an optimal method of coupling the ABM system to the human ossicle for transducing sound waves into electrical signals using the middle ear vibration was studied and the electrical signal output according to the sound stimuli was measured successfully. Although the overall power output from the ABM system is still less than the conventional CIs and further improvements to the ABM system are needed, we found a possibility of the developed ABM system as a totally implantable CIs in the future.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Development and Characterization of a Biomimetic Totally Implantable Artificial Basilar Membrane System

Chung

Jung

Hur

et al. 2021

Front. Bioeng. Biotechnol.

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“…For example, the hemispherical retina structure with high-density photoreceptors fabricated by Gu et al realizes imaging resolutions as high as those of the naked eye . Saadatzi et al designed a spiral-shaped basilar membrane based on the human cochlea, which can generate a localized deflection for different frequency inputs for voice recognition …”

Section: Emulating the Biological Sensesmentioning

confidence: 99%

“…16 Saadatzi et al designed a spiral-shaped basilar membrane based on the human cochlea, which can generate a localized deflection for different frequency inputs for voice recognition. 20 Artificial Nerve Systems for Signal Transmission. In biological sensory pathways, signals are first collected and filtered from multiple sources by the peripheral systems before being sent to the nervous centralis for perception.…”

Section: Nanotechnology For Biomimetic Architecturesmentioning

confidence: 99%

Artificial Sense Technology: Emulating and Extending Biological Senses

Wang

Cai

et al. 2021

ACS Nano

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Biological senses are critical for the survival of organisms. A great deal of attention has focused on elucidating the underlying physiological mechanisms of the senses, inspiring various sensing techniques. Despite progress in this area, gaps remain between the biological senses and conventional sensing techniques. In this Perspective, we propose the concept of artificial sense technology, which mimics the biological senses but differs in terms of objective sensing and intelligent feedback capabilities. We first summarize recent progress in the use of nanotechnologies to emulate the biological senses and then outline the advantages of artificial sense technology, which extend the capabilities of its biological counterparts. We envision artificial sense technology as a powerful perceptual interface that will play key roles in sensation substitution, digital healthcare, animal interactions, plant electronics, smart robots, and other areas that enrich the connections of the physical and virtual worlds.

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“…As a specific hearing impairment caused by damaged sensory hair cells located at the basilar membrane of cochlea, sensorineural hearing loss (SNHL) has disturbed numerous individuals, such as the elderly population, congenitally deaf children, and hearing-damaged patients caused by drugs, strikes, or high-intensity noise. − Hair cells are crucial tissues that convert acoustic vibrations to electrical signals and stimulate auditory nerves along with underlying neurons, whose dysfunction cannot be treated by biological or pharmaceutical strategies. − Existing cochlear implants or hearing aids have intrinsic defects that are inconvenient with an external power supply and low speech recognition. ,− Implanting flexible sound-driven piezo-triboelectric nanogenerators (sound-driven PTNGs) as acoustic sensors to substitute the damaged hair cells of the human cochlea and provide an electrical response of the artificial auditory system is a promising solution. − However, the performance of sound-driven nanogenerators is generally limited by weaknesses, such as relatively low output power density, high structure complexity, and impracticable maintenance, which can be improved to a certain extent by utilizing resonant cavities, whereas effective volume and portability are restrained. − Moreover, most of the presented devices generally only perform well at the resonant frequency whose regulation can barely be achieved as of now, which extensively obstructs the application of sound-driven nanogenerators as artificial cochlea. − Therefore, proposing a reasonable harvesting principle and ingenious structure for fabricating an acoustic harvester device with good practicability and high performance remains a challenge. − …”

mentioning

confidence: 99%

Acoustic Core–Shell Resonance Harvester for Application of Artificial Cochlea Based on the Piezo-Triboelectric Effect

Zheng

Wang

et al. 2021

ACS Nano

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The demand for flexible, efficient, and self-powered cochlear implants applied to remedy sensorineural hearing loss caused by dysfunctional hair cells remains urgent. Herein, we report an acoustic core–shell resonance harvester for the application of artificial cochleae based on the piezo-triboelectric effect. Integrating dispersed BaTiO3 particles as cores and porous PVDF-TrFE as shells, the acoustic harvest devices with ingenious core–shell structures exhibit outstanding piezo-triboelectric properties (V oc = 15.24 V, DA sc = 9.22 mA/m2). The acoustic harvest principle reveals that BaTiO3 nanocores resonate with sound waves and bounce against porous PVDF-TrFE microshells, thereby generating piezo-triboelectric signals. By experimental measurement and numerical modeling, the vibration process and resonance regulation of acoustic harvest devices were intensively investigated to regulate the influential parameters. Furthermore, the acoustic harvesters exhibit admirable feasibility and sensitivity for sound recording and show potential application for artificial cochlea.

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Modeling and Fabrication of a Piezoelectric Artificial Cochlea Electrode Array With Longitudinal Coupling

Cited by 12 publications

References 26 publications

Development and Characterization of a Biomimetic Totally Implantable Artificial Basilar Membrane System

Development and Characterization of a Biomimetic Totally Implantable Artificial Basilar Membrane System

Artificial Sense Technology: Emulating and Extending Biological Senses

Acoustic Core–Shell Resonance Harvester for Application of Artificial Cochlea Based on the Piezo-Triboelectric Effect

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