Real-Time Measurements of Cell Proliferation Using a Lab-on-CMOS Capacitance Sensor Array

被引：35

作者：

Senevirathna, Bathiya Prashan ^{[1
,2
]}

Lu, Sheung ^{[1
,2
]}

Dandin, Marc P. ^{[2
,3
,4
]}

Basile, John ^{[5
]}

Smela, Elisabeth ^{[2
,6
]}

Abshire, Pamela A. ^{[1
,2
]}

机构：

[1] Univ Maryland, Dept Elect & Comp Engn, College Pk, MD 20742 USA

[2] Univ Maryland, Syst Res Inst, College Pk, MD 20742 USA

[3] Univ Maryland, Fischell Dept Bioengn, College Pk, MD 20742 USA

[4] Kiskeya Microsyst, Rockville, MD 20851 USA

[5] Univ Maryland, Sch Dent, Dept Oncol & Diagnost Sci, Baltimore, MD 21201 USA

[6] Univ Maryland, Dept Mech Engn, College Pk, MD 20742 USA

来源：

IEEE TRANSACTIONS ON BIOMEDICAL CIRCUITS AND SYSTEMS | 2018年 / 12卷 / 03期

基金：

芬兰科学院;

关键词：

Capacitance measurement; cell culture; CMOS integrated circuits; dielectric measurements; lab on a chip; mixed analog-digital integrated circuits; CHIP APPLICATIONS; RING OSCILLATORS; ADHESION; BACTERIA; MIGRATION; IMPEDANCE;

D O I：

10.1109/TBCAS.2018.2821060

中图分类号：

R318 [生物医学工程];

学科分类号：

0831 ;

摘要：

We describe a capacitance sensor array that has been incorporated into a lab-on-CMOS system for applications in monitoring cell viability. This paper presents analyticalmodels, calibration results, and measured experimental results of the biosensor. The sensor has been characterized and exhibits a sensitivity of 590 kHz/fF. We report results from benchtop tests and in vitro experiments demonstrating on-chip tracking of cell adhesion as well as monitoring of cell viability. Human ovarian cancer cells were cultured on chip, and measured capacitance responses were validated by comparison with images from photomicrographs of the chip surface. Analysis was performed to quantify cell proliferation and adhesion, and responses to live cells were estimated to be 100 aF/cell.

引用

页码：510 / 520

页数：11

共 50 条

[41] A REAL-TIME CELL PROLIFERATION AND MOTILITY MONITORING SYSTEM
Moscelli, Nicola
van den Driesche, Sander
Vellekoop, Michael J.
Witarski, Wojciech
BIODEVICES 2011, 2011, : 230 - +
[42] REAL-TIME FINGERPRINT SENSOR USING A HOLOGRAM
IGAKI, S
EGUCHI, S
YAMAGISHI, F
IKEDA, H
INAGAKI, T
APPLIED OPTICS, 1992, 31 (11): : 1794 - 1802
[43] Evaluation of a capacitance-based soil moisture sensor for real-time applications
Andrade-Sánchez, P
Upadhyaya, SK
Agüera-Vega, J
Jenkins, BM
TRANSACTIONS OF THE ASAE, 2004, 47 (04): : 1281 - 1287
[44] Real-time retinal imaging with a parallel optical coherence tomography using a CMOS smart array detector
Kim, Jeehyun
Sohn, Bong-Soo
JOURNAL OF THE KOREAN PHYSICAL SOCIETY, 2007, 51 (05) : 1787 - 1791
[45] Kalman filtering to real-time trace water level measurements using ultrasonic sensor
Iswanto, B. H.
Parmono, I. F.
Delina, M.
4TH ANNUAL APPLIED SCIENCE AND ENGINEERING CONFERENCE, 2019, 2019, 1402
[46] Integration of a photodiode array and centroid processing on a single CMOS chip for a real-time Shack-Hartmann wavefront sensor
Pui, BH
Hayes-Gill, B
Clark, M
Somekh, MG
See, CW
Morgan, S
Ng, A
IEEE SENSORS JOURNAL, 2004, 4 (06) : 787 - 794
[47] Live Demonstration: An NFC based Batteryless CMOS ISFET Array for Real-Time pH Measurements of Bio-fluids
Douthwaite, Matthew
Georgiou, Pantelis
2017 IEEE SENSORS, 2017, : 469 - 469
[48] Lab-on-Fiber Humidity Sensor for Real-Time Respiratory Rate Monitoring
Luo, Si
Ding, Yunlian
Zhu, Xiaoshuai
Li, Yang
Ling, Qiang
Duan, Zhiwei
Zhang, Yusheng
Chen, Haiyun
Yu, Zhangwei
Du, Kaikai
Cai, Lu
Wang, Huigang
Guan, Zuguang
Chen, Daru
IEEE SENSORS JOURNAL, 2024, 24 (13) : 20663 - 20668
[49] Real-time implementation of optical sensor on lab rig model for speed estimation
Nagaraju, Deepa
Sharan, Preeta
Sharma, Sneha
Chakraborty, Srijani
JOURNAL OF OPTICS-INDIA, 2024, 53 (03): : 2460 - 2468
[50] Real-time self-mixing sensor for vibration measurements
Norgia, M.
Magnani, A.
Pesaton, A.
ELECTRO-OPTICAL REMOTE SENSING, PHOTONIC TECHNOLOGIES, AND APPLICATIONS VI, 2012, 8542

← 1 2 3 4 5 →