We present a MEMS-based differential scanning calorimetric (DSC) device combining highly sensitive thermoelectric sensing, on-chip self-calibration, and microfluidic regulation for thermodynamic characterization of biomolecular samples on a minimized scale. The device integrates well-defined microfluidic reaction chambers and utilizes a three-dimensional structure in which a layer of resistive microheaters and temperature sensors are precisely aligned to these chambers to provide uniform heating, in-situ temperature sensing, and convenient self-calibration. Notably, this device exploits the novel use of an antimony-bismuth (Sb-Bi) thermopile with high thermoelectric performance to significantly enhance device sensitivity and thus allow for DSC detection with minimized sample consumption. We demonstrate the utility of this MEMS DSC device by characterizing the unfolding of proteins in a minimized volume (1 μL), and at low protein concentrations approaching practically useful levels (1 mg/mL). Quantitative thermodynamic properties including the total enthalpy change (ΔH) and melting temperature (Tm) during this conformational transition are determined and found to agree with published data.
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机译:我们提出了一种基于MEMS的差示扫描量热(DSC)设备,该设备结合了高度灵敏的热电传感,片上自校准和微流控技术,可在最小规模上对生物分子样品进行热力学表征。该设备集成了定义明确的微流体反应腔室,并利用三维结构,其中一层电阻微加热器和温度传感器精确地对准了这些腔室,以提供均匀的加热,原位温度感测和方便的自校准。值得注意的是,该设备利用具有高热电性能的锑-铋(Sb-Bi)热电堆的新颖用途来显着提高设备的灵敏度,从而允许在最小化样品消耗的情况下进行DSC检测。我们通过以最小的体积(1μL)和低蛋白浓度接近实用水平(1 mg / mL)表征蛋白质的展开来证明该MEMS DSC设备的实用性。确定了该构象转变过程中的定量热力学性质,包括总焓变(ΔH)和熔融温度(T m ),并与公开的数据相符。
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