Abstract
Measuring the temperature of a sample is a fundamental need in many biological and chemical processes. When the volume of the sample is on the microliter or nanoliter scale (e.g., cells, microorganisms, precious samples, or samples in microfluidic devices), accurate measurement of the sample temperature becomes challenging. In this work, we demonstrate a technique for accurately determining the temperature of microliter volumes using a simple 3D-printed microfluidic chip. We accomplish this by first filling “microfluidic thermometer” channels on the chip with substances with precisely known freezing/melting points. We then use a thermoelectric cooler to create a stable and linear temperature gradient along these channels within a measurement region on the chip. A custom software tool (available as online Supporting Information) is then used to find the locations of solid-liquid interfaces in the thermometer channels; these locations have known temperatures equal to the freezing/melting points of the substances in the channels. The software then uses the locations of these interfaces to calculate the temperature at any desired point within the measurement region. Using this approach, the temperature of any microliter-scale on-chip sample can be measured with an uncertainty of about a quarter of a degree Celsius. As a proof-of-concept, we use this technique to measure the unknown freezing point of a 50 microliter volume of solution and demonstrate its feasibility on a 400 nanoliter sample. Additionally, this technique can be used to measure the temperature of any on-chip sample, not just near-zero-Celsius freezing points. We demonstrate this by using an oil that solidifies near room temperature (coconut oil) in a microfluidic thermometer to measure on-chip temperatures well above zero Celsius. By providing a low-cost and simple way to accurately measure temperatures in small volumes, this technique should find applications in both research and educational laboratories.
Highlights
The ability to accurately measure temperatures is a crucial need in many biological and chemical processes [1,2,3,4]
These techniques are less suitable for measuring the temperature of microliter- or nanoliter-scale volumes
A microfluidic thermometer: Precise temperature measurements in microliter- and nanoliter-scale volumes microscope image of the measurement region while the channels are filled with water, the solid-liquid interfaces are visible and define an isotherm (T = 0 ̊C) inside the chip. (D) During use, the user locates solidliquid interfaces in four channels containing fluids with known freezing/melting points (0 ̊C and -5.08 ̊C in this example), and our software uses these locations to calculate the linear temperature gradient along the channels in this region. (E) Using this gradient, the temperature of the contents of the middle channel can be determined at any point within the measurement region with an uncertainty of about a quarter of a degree Celsius
Summary
The ability to accurately measure temperatures is a crucial need in many biological and chemical processes [1,2,3,4]. A microfluidic thermometer: Precise temperature measurements in microliter- and nanoliter-scale volumes thermocouples and thermistors are adequate for measuring the temperature of a substance. These techniques are less suitable for measuring the temperature of microliter- or nanoliter-scale volumes (which are commonly encountered with cells, microorganisms, precious samples, and samples inside microfluidic chips). Infrared (IR) thermometers can measure the temperature of a surface [5,6,7], but their sensitivity to a material’s emissivity and large sensing area make IR thermometers less suitable for measuring the temperature of the fluid inside a microfluidic chip [8, 9]. There is an unmet need for simple, broadly-applicable, and label-free techniques for measuring temperatures in small fluid volumes
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