A photovoltage-based integrated sensor for extracellular redox potential measurement and acidification detection

In this study, photovoltage technique is applied in the development of a monolithically integrated sensor for redox (reduction-oxidation) potential and pH mea- surement. The sensor employs the electrolyte-insulator semiconductor structure, with deposition of a layer of gold metal on partial surface...

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Bibliographic Details
Published in:Chinese science bulletin 2014-07, Vol.59 (19), p.2309-2317
Main Authors: Wang, Jun, Wu, Chengxiong, Zhou, Jie, Cai, Hua, Liu, Qingjun, Wang, Ping
Format: Article
Language:English
Subjects:
Acidification
Chemistry/Food Science
cultured cells
Earth Sciences
Electrode potentials
Electrolytic cells
Engineering
Gold
Humanities and Social Sciences
iron
kidney cells
Kidneys
Life Sciences
metabolism
metabolites
multidisciplinary
Physics
pH值测量
rats
redox potential
Science
Science (multidisciplinary)
Sensors
silica
Silicon dioxide
光伏技术
检测传感器
氧化还原电位
电位测量
细胞外
酸化
集成传感器
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Summary:In this study, photovoltage technique is applied in the development of a monolithically integrated sensor for redox (reduction-oxidation) potential and pH mea- surement. The sensor employs the electrolyte-insulator semiconductor structure, with deposition of a layer of gold metal on partial surface of insulator silicon dioxide. Silicon dioxide and gold layer on a single chip form two distinct sensing sites, by sharing the same measuring system, the detection of redox potential and pH variation can be real ized. In this work, the sensor characteristics is tested, and the sensitivity for redox potential and pH measurement is 53.8 mV/log([Fe(Ⅱ)]/[Fe(Ⅲ)]) and 44.3 mV/pH respectively. To demonstrate the validity of the sensor in extra cellular detection, neonatal rat kidney cells are cultured on the sensor surface and then packaged in a flow chamber, thus the acidification rate of metabolites and the redox potential variation in extracellular microenvironment can be continuously monitored. Experimental results indicate increasing acidification and reducing potentials under physiological conditions. The synthesis parameters have potentials in detail revelation of cell metabolism.
ISSN:1001-6538
1861-9541
DOI:10.1007/s11434-014-0178-9