A Review of Skin-Wearable Sensors for Non-Invasive Health Monitoring Applications

Mao, Pengsu; Li, Haoran; Yu, Zhibin

doi:10.3390/s23073673

Cited by 27 publications

(11 citation statements)

References 231 publications

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“…It was observed that pure liquid VOCs showed less permeability due to the dehydration of the stratum corneum. 104,105 Increased skin temperature enhances percutaneous absorption proportionally. In most studies, skin absorption measurements were conducted in temperature-controlled experiments.…”

Section: Skin-emitted Volatolomes and Their Association With Diseasesmentioning

confidence: 99%

Skin emitted volatiles analysis for noninvasive diagnosis: the current advances in sample preparation techniques for biomedical application

S.,

Saquib,

Poojary

et al. 2024

RSC Adv.

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Section: Skin-emitted Volatolomes and Their Association With Diseasesmentioning

confidence: 99%

Skin emitted volatiles analysis for noninvasive diagnosis: the current advances in sample preparation techniques for biomedical application

S.,

Saquib,

Poojary

et al. 2024

RSC Adv.

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show abstract

“…In recent years, novel OPAMP architectures have emerged [18][19][20][21] aiming to enhance their functionality for specific domains. One such critical domain is biomedical electronics, where OPAMPs play a crucial role [22] and serve as fundamental building blocks. In biomedical electronic circuits, OPAMPs need to address the unique features demanded by bio-potential signals (i.e.…”

Section: Introductionmentioning

confidence: 99%

Design and Analysis of a High Gain, Low-Noise and Low-Power Analog Front End for ECG Acquisition in 45nm Technology Using Gm/Id Method

Emon,

Salim,

Chowdhury

2024

Preprint

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In this work, an analog front-end (AFE) circuit for Electrocardiogram (ECG) detection system has been designed, implemented, and investigated in an industry-standard Cadence simulation framework using advanced technology node of 45 nm. The AFE consists of an instrumentation amplifier, a Butterworth band-pass filter (with fifth-order low-pass and second-order high-pass sections), and a second-order notch filter- all are based on two-stage, Miller-compensated operational transconductance amplifiers (OTA). The OTAs have been designed employing the $g_m/I_D$ methodology. Both the pre-layout and post-layout simulation were carried out. The layout consumes an area of 0.0058 mm$^2$ without the resistors and capacitors. Analysis of various simulation results were carried out for the proposed AFE. The circuit demonstrates a post-layout bandwidth of 239 Hz with a variable gain between 44 to 58 dB, a notch depth of -56.4 dB at 50.1 Hz, a total harmonic distortion (THD) of -59.65 dB (less than 1\%), an input referred noise spectral density of $

show abstract

“…In recent years, novel OPAMP architectures have emerged [19][20][21][22][23], aiming to enhance their functionality for specific domains. One such critical domain is biomedical electronics, where OPAMPs play a crucial role [24] and serve as fundamental building blocks. In biomedical electronic circuits, OPAMPs need to address the unique features demanded by bio-potential signals (i.e., ECG, EEG, EMG), which include high amplification (as these signals are inherently weak), low noise levels (to ensure accurate signal acquisition and subsequent processing), and low power consumption.…”

Section: Introductionmentioning

confidence: 99%

Design and Analysis of a High-Gain, Low-Noise, and Low-Power Analog Front End for Electrocardiogram Acquisition in 45 nm Technology Using gm/ID Method

Emon,

Salim,

Chowdhury

2024

Electronics

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In this work, an analog front-end (AFE) circuit for an electrocardiogram (ECG) detection system has been designed, implemented, and investigated in an industry-standard Cadence simulation framework using an advanced technology node of 45 nm. The AFE consists of an instrumentation amplifier, a Butterworth band-pass filter (with fifth-order low-pass and second-order high-pass sections), and a second-order notch filter—all are based on two-stage, Miller-compensated operational transconductance amplifiers (OTA). The OTAs have been designed employing the gm/ID methodology. Both the pre-layout and post-layout simulation are carried out. The layout consumes an area of 0.00628 mm2 without the resistors and capacitors. Analysis of various simulation results are carried out for the proposed AFE. The circuit demonstrates a post-layout bandwidth of 239 Hz, with a variable gain between 44 and 58 dB, a notch depth of −56.4 dB at 50.1 Hz, a total harmonic distortion (THD) of −59.65 dB (less than 1%), an input-referred noise spectral density of <34 μVrms/Hz at the pass-band, a dynamic range of 52.71 dB, and a total power consumption of 10.88 μW with a supply of ±0.6 V. Hence, the AFE exhibits the promise of high-quality signal acquisition capability required for portable ECG detection systems in modern healthcare.

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A Review of Skin-Wearable Sensors for Non-Invasive Health Monitoring Applications

Cited by 27 publications

References 231 publications

Skin emitted volatiles analysis for noninvasive diagnosis: the current advances in sample preparation techniques for biomedical application

Skin emitted volatiles analysis for noninvasive diagnosis: the current advances in sample preparation techniques for biomedical application

Design and Analysis of a High Gain, Low-Noise and Low-Power Analog Front End for ECG Acquisition in 45nm Technology Using Gm/Id Method

Design and Analysis of a High-Gain, Low-Noise, and Low-Power Analog Front End for Electrocardiogram Acquisition in 45 nm Technology Using gm/ID Method

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