微矩阵电极在人类多功能干细胞分化的心肌细胞上的应用

目的应用微矩阵电极系统MEA(Multielectrode Array,MEA)鉴别人类多功能干细胞分化的心肌细胞的电生理特性并建立体外药物检测平台。方法将人类多功能干细胞分化的心肌细胞团贴于经0.1%明胶处理过的MEA芯片,培养3d后,心肌细胞团保持节律性收缩,应用McRack采集分析软件记录给予10M河豚毒素(TTX)前后心肌细胞场电位(field potential duration,FPD)和心率(heart rate)的变化。结果该方法可用于记录心肌细胞胞外电生理特性;10M的TTX可降低心率,缩短FP min的幅度。结论该技术操作简单,高效,可成功记录人类多功能干细胞分化的心肌细胞的电生理特性,并可用于临床药物筛选。

Two-photon 3D printed spring-based Fabry-Pérot cavity resonator for acoustic wave detection and imaging

Optical fiber microresonators have attracted considerable interest for acoustic detection because of their compact size and high optical quality.Here,we have proposed,designed,and fabricated a spring-based Fabry-Pérot cavity microresonator for highly sensitive acoustic detection.We observed two resonator vibration modes:one relating to the spring vibration state and the other determined by the point-clamped circular plate vibration mode.We found that the vibration modes can be coupled and optimized by changing the structure size.The proposed resonator is directly 3D printed on an optical fiber tip through two-photon polymerization and is used for acoustic detection and imaging.The experiments show that the device exhibits a high sensitivity and low noise equivalent acoustic signal level of 2.39 mPa∕Hz^(1∕2)at 75 kHz that can detect weak acoustic waves,which can be used for underwater object imaging.The results demonstrate that the proposed work has great potential in acoustic detection and biomedical imaging applications.

Direct laser writing spiral Sagnac waveguide for ultrahigh magnetic field sensing

A high-birefringence spiral Sagnac waveguide(SSW)device fabricated via direct laser writing(DLW)using a two-photon polymerization(2PP)technique is proposed,designed,and experimentally demonstrated as an ultrahigh magnetic field sensor.The sensor comprises a Y-style tapered waveguide and an SSW containing two microfluidic channels.The SSW has a total length of∼2.4 mm and a spiral radius of∼200μm.Due to the asymmetric structure,the SSW has a high birefringence of 0.016,which can be designed as a magnetic field sensor,as a magnetic fluid can be filled into the microfluidic channel changing the guiding mode and the birefringence and consequently leading to a change in phase of the interferometer when the applied magnetic field changes.The experimental results show that the proposed photonic device has a sensitivity to magnetic fields as high as 0.48 nm/Oe within a range from 10 to 100 Oe.The proposed device is very stable and easy to fabricate,and it can therefore be used for weak magnetic field detection.