The surfactant Triton X-100 could help prevent colloidal metal nanocrystals from sticking to the water-oil interface in droplet reactors, according to new experiments by researchers at the Georgia Institute of Technology in the US and Zhejiang University in China. The new finding could greatly improve the yield of nanocrystals produced by this processing technique. Surfactant or no surfactant? Colloidal metal nanocrystals are up-and-coming technologically important materials that might be ideal in applications such as catalysis, photonics and sensing. However, they are difficult to produce in large quantities. Continuous-flow droplet reactors can be used to make nanocrystals in large quantities but they run into problems if the reaction solution does not contain a surfactant. This is understandable because the droplets have a much higher surface-to-volume ratio than the solution in a batch reactor and so the nanocrystals tend to concentrate at the water-oil interface of the droplets.

自然于2020年11月10日发布关于纳米医学的内容，文章指出肺表面活性剂在肺泡腔表面形成亚微米厚的液体层，因此吸入的纳米颗粒在与上皮细胞相互作用之前就与表面活性剂接触。我们研究了表面活性剂作为保护物理屏障的作用，通过模拟相互作用的硅-铜-肺泡上皮细胞系统在体外。电子显微镜显示，在纳米颗粒存在的情况下，囊泡被保存下来，而纳米颗粒与脂质相互作用导致混合聚集体的形成。荧光显微镜显示，在两种肺泡上皮细胞模型(A549和NCI-H441)中，表面活性剂使纳米颗粒的摄取降低了两个数量级，而与玻璃浸入培养或transwell上的气液界面培养无关。共聚焦显微镜通过显示纳米颗粒-脂质共定位与细胞的相互作用证实了结果。因此，我们的工作支持了这样一种观点，即肺表面活性剂对吸入的纳米颗粒起保护作用。因此，在预测纳米颗粒毒性或药物纳米载体吸收量时，表面活性剂的作用应予以考虑。基于本研究提出的模型可用于工程纳米颗粒的临床前试验。