A Review on Surface Stress-Based Miniaturized Piezoresistive SU-8 Polymeric Cantilever Sensors

Mathew, Ribu; Sankar, A. Ravi

doi:10.1007/s40820-018-0189-1

Cited by 88 publications

(52 citation statements)

References 270 publications

(196 reference statements)

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“…The upper SiO 2 layer is formed by re-oxidizing the polysilicon in an oxidation furnace [40]. The stiffness (k) of the fabricated piezoresistive sensor measured using AFM is 131-146 mN/m, which is well below the stiffness required for BioMEMS applications (1000 mN/m [41,42]). COMSOL 5.3 software is used to perform design and simulation of the piezoresistive sensor to optimize the dimensions for better stiffness and sensitivity [43].…”

Section: Fabrication and Calibration Of The Piezoresistive Devicementioning

confidence: 96%

Ultrasensitive detection of cadmium ions using a microcantilever-based piezoresistive sensor for groundwater

Rotake

Darji

Kale

2020

Beilstein J. Nanotechnol.

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This paper proposes the selective and ultrasensitive detection of Cd(II) ions using a cysteamine-functionalized microcantilever-based sensor with cross-linked ᴅʟ-glyceraldehyde (DL-GC). The detection time for various laboratory-based techniques is generally 12–24 hours. The experiments were performed to create self-assembled monolayers (SAMs) of cysteamine cross-linked with ᴅʟ-glyceraldehyde on the microcantilever surface to selectively capture the targeted Cd(II). The proposed portable microfluidic platform is able to achieve the detection in 20–23 min with a limit of detection (LOD) of 0.56 ng (2.78 pM), which perfectly describes its excellent performance over other reported techniques. Many researchers used nanoparticle-based sensors for the detection of heavy metal ions, but daily increasing usage and commercialization of nanoparticles are rapidly expanding their deleterious effect on human health and the environment. The proposed technique uses a blend of thin-film and microcantilever (micro-electromechanical systems) technology, which mitigate the disadvantages of the nanoparticle approaches, for the selective detection of Cd(II) with a LOD below the WHO limit of 3 μg/L.

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Section: Fabrication and Calibration Of The Piezoresistive Devicementioning

confidence: 96%

Ultrasensitive detection of cadmium ions using a microcantilever-based piezoresistive sensor for groundwater

Rotake

Darji

Kale

2020

Beilstein J. Nanotechnol.

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“…Gold (Au) based one-dimensional (1-D) nanomaterial is a candidate for achieving an ultrasensitive MC biosensor device [38][39][40][41][42][43]. Speci cally, for exible chemo resistive sensors.Au nanowires (AuNWs) are attractive because they possess minimal cross-sectional area but have the ability to increase the oodcurrent along the axial current direction, resulting in higher conductance changes compared to the typical zero-dimensional (0-D) nanomaterials [44,45].…”

Section: Introductionmentioning

confidence: 99%

Synthesis, Characterisation and Cytotoxicity of Gold Nanowires for Ultra-Sensitive Biosensor Development

Lah

Gray

Trigueros

2020

Preprint

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With the long-term goal of developing an ultra-sensitive microcantilever-based nano biosensor for versatile biomarker detection, new controlled bioreceptor-analytes systems are being explored to overcome the disadvantages of conventional ones. Gold nanowires (AuNWs) have been used as a probe to overcome the tolerance problem that occurs in response to changes in environmental conditions. However, the cytotoxicity of AuNWs is still unclear. Here, we examined the cytotoxicity of AuNWs systems using both commercial and as-synthesised AuNWs. In vitro experiments show that commercial AuNWs with an average quoted length of 6 µm are highly toxic against Gram-negative Escherichia coli (E. coli) at 50 µg/ml. However, this toxicity is due to the presence of CTAB surfactant not by the nanostructure. Conversely, the as-synthesised AuNWs with an average length of 9.5 µm show non-cytotoxicity even at the maximum viable concentration (330µg/ml). These findings may lead to the development of potentially life-saving cytotoxicity -free nano biosensors for an early diagnostic of potential diseases.

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“…Environmental conditions have a major impact on human well-being, comfort, and productivity. High air pollution levels for example may cause adverse health effects (Al horr et al, 2016;Moreno-Rangel et al, 2018). Therefore, research and development of chemical sensors have been progressively advanced, especially with the technological enhancement in micro-electro-mechanical systems (MEMS), which has led to the realization of highly sensitive and selective microscale sensors (Corigliano et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Phase optimization of thermally actuated piezoresistive resonant MEMS cantilever sensors

Setiono¹,

Fahrbach²,

Xu³

et al. 2019

J. Sens. Sens. Syst.

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Abstract. The asymmetric resonance response in thermally actuated piezoresistive cantilever sensors causes a need for optimization, taking parasitic actuation–sensing effects into account. In this work, two compensation methods based on Wheatstone bridge (WB) input voltage (VWB_in) adjustment and reference circuit involvement were developed and investigated to diminish those unwanted coupling influences. In the first approach, VWB_in was increased, resulting in a higher current flowing through the WB piezoresistors as well as a temperature gradient reduction between the thermal actuator (heating resistor: HR) and the WB, which can consequently minimize the parasitic coupling. Nevertheless, increasing VWB_in (e.g., from 1 to 3.3 V) may also yield an unwanted increase in power consumption by more than 10 times. Therefore, a second compensation method was considered: i.e., a reference electronic circuit is integrated with the cantilever sensor. Here, an electronic reference circuit was developed, which mimics the frequency behavior of the parasitic coupling. By subtracting the output of this circuit from the output of the cantilever, the resonance response can thus be improved. Both simulated and measured data show optimized amplitude and phase characteristics around resonant frequencies of 190.17 and 202.32 kHz, respectively. With this phase optimization in place, a phase-locked-loop (PLL) based system can be used to track the resonant frequency in real time, even under changing conditions of temperature (T) and relative humidity (RH), respectively. Finally, it is expected to enhance the sensitivity of such piezoresistive electro-thermal cantilever sensors under loading with any target analytes (e.g., particulate matter, gas, and humidity).

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A Review on Surface Stress-Based Miniaturized Piezoresistive SU-8 Polymeric Cantilever Sensors

Cited by 88 publications

References 270 publications

Ultrasensitive detection of cadmium ions using a microcantilever-based piezoresistive sensor for groundwater

Ultrasensitive detection of cadmium ions using a microcantilever-based piezoresistive sensor for groundwater

Synthesis, Characterisation and Cytotoxicity of Gold Nanowires for Ultra-Sensitive Biosensor Development

Phase optimization of thermally actuated piezoresistive resonant MEMS cantilever sensors

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