Mei Qian, Xia Zheng, Xu Feng, Soper Steven A, Fan Z Hugh
Department of Mechanical and Aerospace Engineering, University of Florida, P.O. Box 116250, Gainesville, Florida 32611, USA.
Anal Chem. 2008 Aug 1;80(15):6045-50. doi: 10.1021/ac800843v. Epub 2008 Jul 2.
We report the detection of luciferase by implementing a bioluminescent assay in microfluidic reactors. The reactors were fabricated in poly(methyl methacrylate) by hot embossing using a mold master with the reactor layouts made by high-precision micromilling. The overall fabrication process was simple to implement and had a quick turnaround time with low cost. Two reactors, one with smooth channels (called reactor I) and the other with staggered herringbone mixers (called reactor II), were studied for the bioluminescent assay. The assay was implemented by introducing a sample and an assay solution into the reactors and then mixing took place to achieve the enzymatic reactions. We found that the mixing efficiency in reactor II was 17.8 times higher than reactor I. Theoretical analysis of the experimental results indicated that the required channel length of mixing was linearly proportional to the flow rate. A calibration curve for luciferase was obtained for both reactors. We found that the detection sensitivity of reactor II was 3 times higher than reactor I. The limit of detection in reactor II was determined to be 0.14 microg/mL luciferase. The device was further exploited to determine the concentration of luciferase samples obtained from in vitro protein expression.
我们报告了通过在微流控反应器中实施生物发光测定法来检测荧光素酶。这些反应器是通过热压印在聚甲基丙烯酸甲酯中制造的,使用的模具母版是通过高精度微铣削制作的反应器布局。整个制造过程易于实施,周转时间短且成本低。研究了两个反应器,一个具有光滑通道(称为反应器I),另一个具有交错的人字形混合器(称为反应器II)用于生物发光测定。该测定是通过将样品和测定溶液引入反应器,然后进行混合以实现酶促反应来实施的。我们发现反应器II中的混合效率比反应器I高17.8倍。对实验结果的理论分析表明,混合所需的通道长度与流速成线性比例。获得了两个反应器的荧光素酶校准曲线。我们发现反应器II的检测灵敏度比反应器I高3倍。确定反应器II中的检测限为0.14μg/mL荧光素酶。该装置进一步用于测定从体外蛋白质表达获得的荧光素酶样品的浓度。