Design and modeling of electrode networks for code-division multiplexed resistive pulse sensing in microfluidic devices

Liu, Ruxiu; Waheed, Waqas; Wang, Ningquan; Civelekoglu, Ozgun; Boya, Mert; Chu, Chia‐Heng; Sarioglu, A. Fatih

doi:10.1039/c7lc00545h

Cited by 25 publications

(14 citation statements)

References 44 publications

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“…Matched filters are generally used to identify a known signal or template in an unknown signal. The matched filter can improve noise rejection and extract features out of a noisy signal Matched filters have been extensively used for the detection of blood vessels, ECG peaks, seismic events, moving targets, cracks, SONAR, and microfluidic cells [44][45][46][47][48][49][50][51]. It is similar to the convolution of an unknown signal with a conjugated time-reversed version of the template.…”

Section: Wheeze Detection Using Matched Filtermentioning

confidence: 99%

Design Analysis and Human Tests of Foil-Based Wheezing Monitoring System for Asthma Detection

Khan

Qaiser

Shaikh

et al. 2020

IEEE Trans. Electron Devices

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We present a flexible acoustic sensor that has been designed to detect wheezing (a common symptom of asthma) while attached to the chest of a human. We adopted a parallel plate capacitive structure using air as the dielectric material. The pressure (acoustic) waves from wheezing vibrate the top diaphragm of the structure, thereby, changing the output capacitance. The sensor is designed such that it resonates in the frequency range of wheezing (100-1000Hz) which presents twofold benefits. The resonance results in large deflection of the diaphragm that eradicates the need for using signal amplifiers (used in microphones). Secondly, the design itself acts as a low pass filter to reduce the effect of background noise which mostly lies in >1000Hz frequency range. The resulting analog interface is minimal and thus, consumes less power and occupies less space. The sensor is made up of low-cost sustainable materials (aluminum foil) which greatly reduces the cost and complexity of manufacturing processes. A robust wheezing detection (Matched filter) algorithm is used to identify different types of wheezing sounds among the noisy signals originating from the chest that lie in the same frequency range as wheezing. The sensor is connected to a smartphone via Bluetooth, enabling signal processing and further integration into digital medical electronic systems based on the Internet of Things (IoT). Bending, cyclic pressure, heat, and sweat tests are performed on the sensor to evaluate its performance in simulated real-life harsh conditions.

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Section: Wheeze Detection Using Matched Filtermentioning

confidence: 99%

Design Analysis and Human Tests of Foil-Based Wheezing Monitoring System for Asthma Detection

Khan

Qaiser

Shaikh

et al. 2020

IEEE Trans. Electron Devices

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“…Our sensing strategy is based on the Microfluidic CODES scheme, which uses micromachined electrode patterns to multiplex spatiotemporal cell data across a microfluidic device. [30][31][32] In our device, a three-electrode Coulter counter was shaped to form distinct electrode patterns (i.e., sensors) at six different nodes to monitor cell passage between microfluidic chambers. Each sensor is composed of an array of 5 μm-wide finger electrodes separated by 5 μm gaps and produces a specific 31-bit digital code, which was implemented by an interdigitated arrangement of three electrodes: two sensing electrodes to set the bit polarity (positive for "1" and negative for "0") and one common electrode meandering in between to excite the sensor network ( Figure 1d).…”

Section: Device Design and Operationmentioning

confidence: 99%

“…In addition, we designed sensor codes to be mutually orthogonal (Gold sequences), [33,34] and therefore, we could 1 by the same or different sensors (Table 1.1). [30,32] Moreover, in the case of cell debris or aggregates, the electrical signal generated by sensors do not match any of the templates constructed based on single cell signals and therefore, these data are discarded and do not affect the assay performance. Figure 3.…”

Section: Device Design and Operationmentioning

confidence: 99%

Combinatorial Immunophenotyping of Cell Populations with an Electronic Antibody Microarray

Chu

Wang

Ozkaya‐Ahmadov

et al. 2019

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“…To address the signal overlapping issue, Liu et al demonstrated a microfluidic CODES technology based on the code division multiple access (CDMA) principle to simultaneously resolve signals from a combined waveform. 102,103 The CDMA technology, widely used in telecommunications, achieves signal multiplexing by modulating signals from individual channels with different orthogonal digital spreading codes; individual signals can be recovered by crosscorrelating the multiplexed signal with standard templates, i.e., the measured analog square pulse signals representing each digital spreading code. The sensing principle of the microfluidic CODES method is shown in Fig.…”

Section: Codes Multiplexingmentioning

confidence: 99%

Lab-on-a-chip electrical multiplexing techniques for cellular and molecular biomarker detection

Liu

Zhe

2018

Biomicrofluidics

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Signal multiplexing is vital to develop lab-on-a-chip devices that can detect and quantify multiple cellular and molecular biomarkers with high throughput, short analysis time, and low cost. Electrical detection of biomarkers has been widely used in lab-on-a-chip devices because it requires less external equipment and simple signal processing and provides higher scalability. Various electrical multiplexing for lab-on-a-chip devices have been developed for comprehensive, high throughput, and rapid analysis of biomarkers. In this paper, we first briefly introduce the widely used electrochemical and electrical impedance sensing methods. Next, we focus on reviewing various electrical multiplexing techniques that had achieved certain successes on rapid cellular and molecular biomarker detection, including direct methods (spatial and time multiplexing), and emerging technologies (frequency, codes, particle-based multiplexing). Lastly, the future opportunities and challenges on electrical multiplexing techniques are also discussed.

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Design and modeling of electrode networks for code-division multiplexed resistive pulse sensing in microfluidic devices

Cited by 25 publications

References 44 publications

Design Analysis and Human Tests of Foil-Based Wheezing Monitoring System for Asthma Detection

Design Analysis and Human Tests of Foil-Based Wheezing Monitoring System for Asthma Detection

Combinatorial Immunophenotyping of Cell Populations with an Electronic Antibody Microarray

Lab-on-a-chip electrical multiplexing techniques for cellular and molecular biomarker detection

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