Thermal conductivity of a Jurkat cell measured by a transient laser point heating method

•Micropipette thermal sensing is a unique technique, which allows for measuring the thermal conductivity of a biological cell.•The transient temperature measurement due to laser point heating at the sensor is compared with COMSOL Multiphysics simulation, which leads to extraction of cell level therm...

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Bibliographic Details
Published inInternational journal of heat and mass transfer Vol. 160; p. 120161
Main Authors Shrestha, R., Atluri, R., Simmons, D.P., Kim, D.S., Choi, T.Y.
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 01.10.2020
Elsevier BV
Subjects
Chemical composition
Conduction heating
Conductive heat transfer
Effective medium theory
Energy transfer
Heat conductivity
Jurkat cell
Laser beam heating
Laser point heating
Measurement techniques
Microspheres
Polyethylenes
Structural models
Thermal conductivity
Thermal energy
Thermal sensor
Thermodynamic properties
Uniqueness
Weight
Jurkat cell
Thermal conductivity
Thermal sensor
Laser point heating
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Summary:•Micropipette thermal sensing is a unique technique, which allows for measuring the thermal conductivity of a biological cell.•The transient temperature measurement due to laser point heating at the sensor is compared with COMSOL Multiphysics simulation, which leads to extraction of cell level thermal conductivity.•A multiparameter fitting technique through MATLAB is utilized to obtain optimal parameters (e.g., thermal conductivity).•The technique is mechanically non-invasive for characterization of thermal conductivity of microscale materials. To understand and quantify the thermal energy transfer in a biological cell, the measurement of thermal properties at a cellular level is emerging as great importance. We report herein a unique technique that utilizes a laser point heat source for temporal temperature rise in a micro-pipette thermal sensor; this technique characterizes heat conduction of a measured sample, the Jurkat cell, thus measuring the sample's thermal conductivity (TC). To this end, we incorporated the computational model in COMSOL to solve for the transient temperature and used the multi-parameter fitting of the experimental data using MATLAB. To address the influence of a Jurkat cell's chemical composition on TC, we compared three structural models for prediction of effective thermal conductivity in heterogeneous materials thereby determining the weight percentage of the Jurkat cell. When considering water and protein as the major constituents, we found that a combination of Maxwell-Euken and Effective Medium Theory modeling provides the closest approximation to published weight percent data and, therefore, is recommended for prediction of the cell composition. We validate the accuracy of the measurement technique, itself, by measuring polyethylene microspheres and observed 1% deviation from published data. The unique technique was determined to be mechanically non-invasive, capable of maintaining viable cells, and capable of measuring the thermal conductivity of a Jurkat cell, which was demonstrated to be 0.538 W/(m⋅K) ± 1%.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2020.120161