A microelectromechanical system artificial basilar membrane based on a piezoelectric cantilever array and its characterization using an animal model

Jang, Jongmoon; Lee, Jangwoo; Woo, Seongyong; Sly, David; Campbell, Luke; Cho, Jin Ho; O’Leary, Stephen; Park, Min Hyun; Han, Sungmin; Choi, Ji Wong; Jang, Jeong Hun; Choi, Hongsoo

doi:10.1038/srep12447

Cited by 81 publications

(76 citation statements)

References 52 publications

(90 reference statements)

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“…Results show that the proposed design has a clear frequency selectivity with a minimum quality factor of 1285 and mimics the natural operation of cochlea. Both the sensitivity and the quality factor of the proposed system are higher than the state-of-the-art piezoelectric transducers [4]. 3.…”

Section: Design and Modellingmentioning

confidence: 84%

“…The output of the piezoelectric acoustic sensor is going to be processed by an interface circuit and converted into current pulses which are sent to corresponding electrodes to stimulate the auditory neurons. Experimental results show that the device generates 200 mVpp at 100 dB Sound Pressure Level (SPL) which is the required sensing voltage of state-of-the-art neural stimulation circuitry [4]. High output voltages make implementation of the FICI systems more feasible.…”

Section: Design and Modellingmentioning

confidence: 99%

See 1 more Smart Citation

Thin Film PZT Acoustic Sensor for Fully Implantable Cochlear Implants

İlik

Koyuncuoğlu

Uluşan

et al. 2017

Proceedings of Eurosensors 2017, Paris, France, 3–6 September 2017

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This paper presents design and fabrication of a MEMS-based thin film piezoelectric transducer to be placed on an eardrum for fully-implantable cochlear implant (FICI) applications. Resonating at a specific frequency within the hearing band, the transducer senses eardrum vibration and generates the required voltage output for the stimulating circuitry. Moreover, high sensitivity of the sensor, 391.9 mV/Pa @900 Hz, decreases the required power for neural stimulation. The transducer provides highest voltage output in the literature (200 mVpp @100 dB SPL) to our knowledge. A multi-frequency piezoelectric sensor, covering the daily acoustic band, is designed based on the test results and validated through FEA. The implemented system provides mechanical filtering, and mimics the natural operation of the cochlea. Herewith, the proposed sensor overcomes the challenges in FICI operations and demonstrates proof-of-concept for next generation FICIs.

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Section: Design and Modellingmentioning

confidence: 84%

Section: Design and Modellingmentioning

confidence: 99%

Thin Film PZT Acoustic Sensor for Fully Implantable Cochlear Implants

İlik

Koyuncuoğlu

Uluşan

et al. 2017

Proceedings of Eurosensors 2017, Paris, France, 3–6 September 2017

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“…In 2011, Professor Ito's group at Tohoku University reported a study using a 40 m thick piezoelectric film [10]. In addition, a research paper on ABM experiment using piezoelectric cantilever was presented by Professor Hongsoo Choi's group at DGIST in Korea in 2015 [12]. However, there has been no report on the development of artificial cochlear having continuous membrane capable of sound signal transmission in the similar fashion to that of human hair cell on the basilar membrane (BM).…”

Section: Introductionmentioning

confidence: 99%

“…Since the resonant frequency varies depending on the position of the basilar membrane, this functions as a frequency analyzer [8,9]. For biomimetic artificial basilar membrane (ABM), the frequency classification of basilar membranes depends on the principle of tonotopy [10][11][12]. Thus, the ABM covers all ranges of audible frequencies and induces local resonance in specific frequencies, at the same time.…”

Section: Introductionmentioning

confidence: 99%

Fabrication of Si₃N₄-Based Artificial Basilar Membrane with ZnO Nanopillar Using MEMS Process

Kwak¹,

Jung

Song

et al. 2017

Journal of Sensors

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This paper presents the fabrication of Si 3 N 4 -based artificial basilar membrane (ABM) with ZnO nanopillar array. Structure of ABMs is composed of the logarithmically varying membrane fabricated by MEMS process and piezonanopillar array grown on the Si 3 N 4 -based membrane by hydrothermal method. We fabricate the bottom substrate containing Si 3 N 4 -based membrane for inducing the resonant motions from the sound wave and the top substrates of electrodes for acquiring electric signals. In addition, the bonding process of the top and bottom substrate is performed to build ABM device. Depending on sound wave input of the specific frequency, specific location of the ABM produces a resonant behavior. Then a local deformation of the piezonanopillar array produces an electric signal between top and bottom electrode. As experimental results of the fabricated ABM, the measured resonant frequencies are 2.34 kHz, 3.97 kHz, and 8.80 kHz and the produced electrical voltages on each resonant frequency are 794 nV, 398 nV, and 89 nV. Thus, this fabricated ABM device shows the possibility of being a biomimetic acoustic device.

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“…Up to 9.8 nW/cm 2 of power density was reported at 100 dB-SPL using thin film lead-zirconate-titanate (PZT) MEMS acoustic energy harvesters [2]. A piezoelectric cantilever array reported by Jang et al uses thin film AlN piezoelectric transducers [3], but the generated voltage is on the order of 50 μV and requires an external power source for neural stimulation. In a previous study of our group, Beker et al theoretically investigated the bulk piezoelectric energy harvesters attached on a flat ear drum model and verified the efficiency of using bulk PZT for power generation in CIs [4].…”

Section: Introductionmentioning

confidence: 99%

Bulk PZT Cantilever Based MEMS Acoustic Transducer for Cochlear Implant Applications

Koyuncuoğlu

İlik

Chamanian

et al. 2017

Proceedings of Eurosensors 2017, Paris, France, 3–6 September 2017

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This paper presents the first acoustic experimental results of a MEMS based bulk piezoelectric transducer for use in fully implantable cochlear implants (FICI). For this purpose, the transducer was attached onto an acoustically vibrating membrane. Sensing and energy harvesting performances were measured using neural stimulation and rectifier circuits, respectively. The chip has a 150 Hz bandwidth around 1800 Hz resonance frequency that is suitable for mechanical filtering as a sensor. As an energy harvester, bulk piezoelectric transducer generated a rectified power of 16.25 μW with 2.47 VDC with 120 dB-A sound input at 1780 Hz. Among other MEMS acoustic energy harvesters in the literature, reported transducer has the highest power density (1.5 × 10 −3 W/cm 3 ) to our knowledge.

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A microelectromechanical system artificial basilar membrane based on a piezoelectric cantilever array and its characterization using an animal model

Cited by 81 publications

References 52 publications

Thin Film PZT Acoustic Sensor for Fully Implantable Cochlear Implants

Thin Film PZT Acoustic Sensor for Fully Implantable Cochlear Implants

Fabrication of Si₃N₄-Based Artificial Basilar Membrane with ZnO Nanopillar Using MEMS Process

Bulk PZT Cantilever Based MEMS Acoustic Transducer for Cochlear Implant Applications

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A microelectromechanical system artificial basilar membrane based on a piezoelectric cantilever array and its characterization using an animal model

Cited by 81 publications

References 52 publications

Thin Film PZT Acoustic Sensor for Fully Implantable Cochlear Implants

Thin Film PZT Acoustic Sensor for Fully Implantable Cochlear Implants

Fabrication of Si3N4-Based Artificial Basilar Membrane with ZnO Nanopillar Using MEMS Process

Bulk PZT Cantilever Based MEMS Acoustic Transducer for Cochlear Implant Applications

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Product

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Fabrication of Si₃N₄-Based Artificial Basilar Membrane with ZnO Nanopillar Using MEMS Process