Cellular dynamics of bovine aortic smooth muscle cells measured using MEMS force sensors

Tsukagoshi, Takuya; Nguyen, Thanh-Vinh; Shoji, Kayoko Hirayama; Takahashi, Hidetoshi; Matsumoto, Kiyoshi

doi:10.1088/1361-6463/aab146

Cited by 7 publications

(5 citation statements)

References 38 publications

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“…Two electrodes were placed at the roots of the two hinges and the resistance of the cantilever is defined as the resistance between the two electrodes. The fabrication process of the cantilever can be found in previous studies [24][25][26][27][28][29]. A photograph of the fabricated sensor chip attached and wire-bonded to a flexible substrate and a photograph of the cantilever are shown in Figure 2a.…”

Section: Piezoresistive Cantilevermentioning

confidence: 99%

“…A differential pressure in the range of ±10 Pa was applied to the cantilever using a pressure generator. The fractional resistance change of the cantilever was measured using the setup reported in previous studies [24][25][26][27][28][29][30][31][32], which consists of the Wheatstone bridge circuit and an amplifying circuit whose output is recorded using a ScopeCorder (Yokogawa Test & Measurement Co., Tokyo, Japan, DL850). The calibration result in Figure 2c shows the linear relationship between the differential pressure and the fractional resistance change of the cantilever.…”

Section: Piezoresistive Cantilevermentioning

confidence: 99%

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MEMS-Based Pulse Wave Sensor Utilizing a Piezoresistive Cantilever

Nguyen

Mizuki

Tsukagoshi

et al. 2020

Sensors

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This paper reports on a microelectromechanical systems (MEMS)-based sensor for pulse wave measurement. The sensor consists of an air chamber with a thin membrane and a 300-nm thick piezoresistive cantilever placed inside the chamber. When the membrane of the chamber is in contact with the skin above a vessel of a subject, the pulse wave of the subject causes the membrane to deform, leading to a change in the chamber pressure. This pressure change results in bending of the cantilever and change in the resistance of the cantilever, hence the pulse wave of the subject can be measured by monitoring the resistance of the cantilever. In this paper, we report the sensor design and fabrication, and demonstrate the measurement of the pulse wave using the fabricated sensor. Finally, measurement of the pulse wave velocity (PWV) is demonstrated by simultaneously measuring pulse waves at two points using the two fabricated sensor devices. Furthermore, the effect of breath holding on PWV is investigated. We showed that the proposed sensor can be used to continuously measure the PWV for each pulse, which indicates the possibility of using the sensor for continuous blood pressure measurement.

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Section: Piezoresistive Cantilevermentioning

confidence: 99%

Section: Piezoresistive Cantilevermentioning

confidence: 99%

MEMS-Based Pulse Wave Sensor Utilizing a Piezoresistive Cantilever

Nguyen

Mizuki

Tsukagoshi

et al. 2020

Sensors

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“…The sensor used in this study was a MEMS-based piezoresistive cantilever, similar to the sensors that have been developed in our previous studies to measure forces generated by droplets and cells [23][24][25][26][27][28][29] . The cantilever was fabricated from a silicon-on-insulator wafer, whose device Si, box, and handle Si layers' thicknesses were 300 nm, 400 nm, and 300 μm, respectively.…”

Section: Mems-based Acoustic Sensormentioning

confidence: 99%

Bubble entrapment during the recoil of an impacting droplet

Nguyen

Ichiki

2020

Microsyst Nanoeng

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When a droplet impacts a (super-)hydrophobic surface, there is a range of Weber numbers within which bubble entrapment will occur during droplet recoil due to closure of the air cavity developed when the droplet spreads out during the impact. In this study, we studied bubble entrapment using a microelectromechanical system (MEMS)-based acoustic sensor fabricated on a substrate. We found that bubble entrapment is followed by an acoustic vibration that can be detected by the sensor. Moreover, the frequency of the vibration is inversely proportional to the radius of the droplet, which indicates that this vibration is the resonant oscillation of the bubble. Therefore, the MEMS-based acoustic sensor can be used not only to detect but also to measure the size of the entrapped bubble. Finally, we demonstrated that it is possible to prevent bubble formation by allowing the air to escape to the underside of the droplet contact area. This can be done by creating through-holes on the substrate or decorating the substrate with sufficiently large textures.

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“…We used MEMS-based cantilever force sensors to investigate how the beating frequency of hiPSC-CMs changes with temperature. The use of silicon-based force sensors for studying cellular forces has advantages in terms of temporal resolution [ 18 , 19 , 20 , 30 , 31 ]. Silicon-based force sensors have temporal resolutions in the order of GHz, and it has been reported that the force can be measured in units of adhesive spots on cells because of their high measurement speed of 400 kHz [ 31 ].…”

Section: Discussionmentioning

confidence: 99%

“…The use of silicon-based force sensors for studying cellular forces has advantages in terms of temporal resolution [ 18 , 19 , 20 , 30 , 31 ]. Silicon-based force sensors have temporal resolutions in the order of GHz, and it has been reported that the force can be measured in units of adhesive spots on cells because of their high measurement speed of 400 kHz [ 31 ]. The present study was based on these previous studies, and the kHz-order sampling rate enabled the accurate detection of the timing of the beats.…”

Section: Discussionmentioning

confidence: 99%

Temperature Dependence of the Beating Frequency of hiPSC-CMs Using a MEMS Force Sensor

Ikegami

Tsukagoshi

Matsudaira

et al. 2023

Sensors

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It is expected that human iPS cell-derived cardiomyocytes (hiPSC-CMs) can be used to treat serious heart diseases. However, the properties and functions of human adult cardiomyocytes and hiPSC-CMs, including cell maturation, differ. In this study, we focused on the temperature dependence of hiPSC-CMs by integrating the temperature regulation system into our sensor platform, which can directly and quantitatively measure their mechanical motion. We measured the beating frequency of hiPSC-CMs at different environmental temperatures and found that the beating frequency increased as the temperature increased. Although the rate at which the beating frequency increased with temperature varied, the temperature at which the beating stopped was relatively stable at approximately 20 °C. The stopping of beating at this temperature was stable, even in immature hiPSC-CMs, and was considered to be a primitive property of cardiomyocytes.

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Cellular dynamics of bovine aortic smooth muscle cells measured using MEMS force sensors

Cited by 7 publications

References 38 publications

MEMS-Based Pulse Wave Sensor Utilizing a Piezoresistive Cantilever

MEMS-Based Pulse Wave Sensor Utilizing a Piezoresistive Cantilever

Bubble entrapment during the recoil of an impacting droplet

Temperature Dependence of the Beating Frequency of hiPSC-CMs Using a MEMS Force Sensor

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