DocumentCode
3003095
Title
Thermistor based nano-needle for single cell thermal characterization
Author
Binslem, Salma Abdullah ; Ahmad, Mohd Ridzuan
Author_Institution
Dept. of Control & Mechatron. Eng., Univ. Teknol. Malaysia, Skudai, Malaysia
fYear
2013
fDate
Nov. 29 2013-Dec. 1 2013
Firstpage
590
Lastpage
595
Abstract
Cell´s intracellular temperature has shown to have a vital role in controlling a cell´s conditions, properties, activities, and the cell response towards external stimuli. Yet, Current conventional methods are not able to give accurate or any measurements when spatial resolution decreases to a micro scale. Many researches from different field are trying to develop ways that give high accuracy and high temperature sensitivity. We present here a Nano-needle microfluidic system for single cell temperature measurement; however, here we discussed the optimization using finite element approach of the sensor design using tungsten as the electrodes, and semiconducting metal oxide Co3O4 as the sensing material. The dimension of the sensor that gave the highest voltage thus highest sensitivity were ratio 1:4 of element diameter/electrode cross sectional area, a gap of 450nm between electrodes and a penetration depth of 0.25 in electrode 0.25nm. Furthermore, Voltage response gave results to measure a 0.1°C.
Keywords
bioMEMS; biomedical electrodes; biothermics; cellular biophysics; cobalt compounds; finite element analysis; microfluidics; microsensors; nanobiotechnology; nanosensors; needles; temperature sensors; thermistors; tungsten; Co3O4; W; cell activities; cell conditions; cell intracellular temperature; cell properties; cell response; conventional method; depth 0.25 nm; distance 450 nm; electrode cross sectional area; electrodes; element diameter; external stimuli; finite element approach; high accuracy sensitivity; high temperature sensitivity; microscale; nanoneedle microfluidic system; optimization; semiconducting metal oxide Co3O4; sensing material; sensor design; sensor dimension; single cell temperature measurement; single cell thermal characterization; spatial resolution; temperature 0.1 degC; thermistor based nanoneedle; tungsten; voltage response; Electrodes; Finite element analysis; Microfluidics; Nanobioscience; Temperature distribution; Temperature measurement; Temperature sensors; Single cell; finite element analysis; thermal properties; thermistor based nano-needle;
fLanguage
English
Publisher
ieee
Conference_Titel
Control System, Computing and Engineering (ICCSCE), 2013 IEEE International Conference on
Conference_Location
Mindeb
Print_ISBN
978-1-4799-1506-4
Type
conf
DOI
10.1109/ICCSCE.2013.6720034
Filename
6720034
Link To Document