基于压电振荡原理的微阵列点样系统的研制

针对基于电磁微阀原理的非接触点样方式存在操作过程复杂、点样量偏大,以及压电喷墨原理的非接触点样方式存在点样针不易清洗、造价昂贵等不足,研制了一种基于压电振荡原理的新型非接触点样装置,实现了微量液体点样.在本装置中,毛细管点样针与压电驱动装置为两个独立单元,可以单独对毛细管点样针进行更换和清洗.采用激光拉制法制备的玻璃毛细管点样针具有内径可调、成本低等优点.此点样方式通过改变压电陶瓷的振幅和频率,可在10Symbolm@@_10～10Symbolm@@_9 L之间调控点样体积.以此为基础,结合三维精密位移控制技术,研制了一种基于压电振荡原理的微阵列生物芯片点样系统.对点样系统的点样体积、点样密度、点样精度等参数进行了测试,结果表明,此点样系统的最小点样体积可达320 pL,点样密度可达4000 点/cm2,并能够实现界面图案化制备.

Development of Piezoelectric Oscillation-Based Microarray Spotting System

A new type of piezoelectric oscillation-based non-contact spotting mode has been developed to overcome the disadvantages of traditional non-contact spotting modes including complicated operation procedure, cleaning difficulty of spotting needle, large sample consumption of electromagnetic microvalve and high spotting cost of piezoelectric inkjet based non-contact spotting mode. In the device, the capillary spotting needle and the piezoelectric driving device are two independent units used for replacing and cleaning capillary spotting needle. The glass capillary spotting needle is prepared by the laser melting method with adjustable diameter and low cost. The sample spotting volume of the device can be easily adjusted in the range of 10Symbolm@@_10-10Symbolm@@_9 by changing the amplitude and frequency of piezoelectric ceramic. A microarray spotting system is developed by the combination of the piezoelectric oscillation-based non-contact spotting mode and three dimensional precision displacement control technology. The multiple parameters of as-prepared microarray spotting system have been tested including spotting volume, density of spot and spotting precision. The experimental results indicate that the minimum volume of single spot with 320 pL and the highest density of spot with 4000 spots/cm2 can be achieved by the as-prepared microarray spotting system. Furthermore, the as-prepared microarray spotting system can also be employed to fabricate patterned interface.