Inertial mixing of acoustically levitated droplets for time-lapse protein crystallography

Droplet Pub Date : 2024-05-28 DOI:10.1002/dro2.132
Soichiro Tsujino, Yohei Sato, Shichao Jia, Michal W. Kepa, Sofia Trampari, Takashi Tomizaki
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Abstract

Varying the chemical consistency of acoustically levitated droplets opens up an in situ study of chemical and biochemical reactions in small volumes. However, the optimization of the mixing time and the minimization of the positional instability induced by solution dispensing are necessary for practical applications such as the study of the transient state of macromolecules crystallography during the ligand binding processes. For this purpose, we study the inertial mixing in a configuration compatible with the room-temperature crystallography using the acoustic levitation diffractometer, therein solution drops ejected at high velocity collide and coalesce with droplets dispensed on acoustically levitated and rotating polymer thin-film sample holders. With the proposed method, we are able to achieve the mixing time of ∼0.1 s for sub-micro and a few microliter droplets. The observed short mixing time is ascribed to the rapid penetration of the solution into the droplets and confirmed by a computational fluid dynamic simulation. The demonstrated accelerated solution mixing is tested in a pilot time-lapse protein crystallography experiment using the acoustic levitation diffractometer. The results indicate the detection of transient ligand binding state within 2 s after the solution dispensing, suggesting the feasibility of the proposed method for studying slow biochemical processes.

Abstract Image

声学悬浮液滴的惯性混合,用于延时蛋白质晶体学研究
通过改变声学悬浮液滴的化学稠度,可以对小体积的化学和生化反应进行现场研究。然而,在实际应用中,如研究配体结合过程中大分子晶体学的瞬态时,必须优化混合时间并尽量减少溶液分配引起的位置不稳定性。为此,我们使用声学悬浮衍射仪研究了与室温结晶学兼容的惯性混合配置,其中高速喷射出的溶液滴与在声学悬浮和旋转聚合物薄膜样品架上分配的液滴碰撞并聚合。利用所提出的方法,我们能够使亚微米和几微升液滴的混合时间达到 ∼ 0.1 秒。所观察到的短混合时间归因于溶液快速渗入液滴,并通过计算流体动力学模拟得到了证实。在使用声学悬浮衍射仪进行的试验性延时蛋白质晶体学实验中,对所证明的加速溶液混合进行了测试。结果表明,在溶液分配后 2 秒内就能检测到瞬时配体结合状态,这表明所提出的方法在研究缓慢的生物化学过程方面是可行的。
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CiteScore
6.60
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