Zhao Xinkai, Li Ziyu, Cao Bingbing, Jin Yichao, Wang Wenxing, Tian Jing, Dai Liang, Sun Dan, Zhang Ce
State Key Laboratory of Photon-Technology in Western China Energy, Institute of Photonics and Photon-Technology, Northwest University, No. 1, Xuefu Avenue, Xi'an, 710127, Shaanxi, China.
Hunter Laboratory Technology (Nanjing) Co., Ltd., No. 182, Innovation Center, No. 2 Qiande Road, Nanjing, 211122, Jiangsu, China.
Heliyon. 2024 Aug 20;10(16):e36495. doi: 10.1016/j.heliyon.2024.e36495. eCollection 2024 Aug 30.
Zebrafish is a highly advantageous model animal for drug screening and toxicity evaluation thanks to its amenability to optical imaging (i.e., transparency), possession of organ structures similar to humans, and the ease with which disease models can be established. However, current zebrafish drug screening technologies and devices suffer from limitations such as low level of automation and throughput, and low accuracy caused by the heterogeneity among individual zebrafish specimens. To address these issues, we herein develop a high-throughput zebrafish drug screening system. This system is capable of maintaining optimal culturing conditions and simultaneously monitoring and analyzing the movement of 288 zebrafish larvae under various external conditions, such as drug combinations. Moreover, to eliminate the effect of heterogeneity, locomotion of participating zebrafish is assessed and grouped before experiments. It is demonstrated that in contrast to the experimental results without pre-selection, which shows ∼20 % damaged motor function (i.e., degree of attenuation), the drug-induced variations among zebrafish with equivalent mobility reaches ∼80 %. Overall, our high-throughput zebrafish drug screening system overcomes current limitations by improving automation, throughput, and accuracy, resulting in enhanced detection of drug-induced variations in zebrafish motor function.
斑马鱼是一种非常适合用于药物筛选和毒性评估的模式动物,这得益于它易于进行光学成像(即具有透明性)、拥有与人类相似的器官结构,以及易于建立疾病模型。然而,目前的斑马鱼药物筛选技术和设备存在一些局限性,如自动化程度和通量较低,以及由于斑马鱼个体样本之间的异质性导致的准确性较低。为了解决这些问题,我们在此开发了一种高通量斑马鱼药物筛选系统。该系统能够维持最佳培养条件,并同时监测和分析288条斑马鱼幼体在各种外部条件(如药物组合)下的运动。此外,为了消除异质性的影响,在实验前对参与实验的斑马鱼的运动能力进行评估和分组。结果表明,与未进行预选的实验结果相比,未进行预选的实验结果显示约20%的运动功能受损(即衰减程度),而具有同等运动能力的斑马鱼之间药物诱导的差异达到约80%。总体而言,我们的高通量斑马鱼药物筛选系统通过提高自动化程度、通量和准确性克服了当前的局限性,从而增强了对斑马鱼运动功能中药物诱导变化的检测。
