含病毒颗粒的干燥：模拟液滴来源及成分的影响

Drying of virus-containing particles: modelling effects of droplet origin and composition.

作者信息

Jarvis Michael C

机构信息

School of Chemistry, Glasgow University, Glasgow, Scotland G12 8QQ UK.

出版信息

J Environ Health Sci Eng. 2021 Nov 5;19(2):1987-1996. doi: 10.1007/s40201-021-00750-6. eCollection 2021 Dec.

DOI:10.1007/s40201-021-00750-6

PMID:34754455

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8569499/

Abstract

BACKGROUND AND PURPOSE

Virus-containing aerosol droplets emitted by breathing, speech or coughing dry rapidly to equilibrium with ambient relative humidity (RH), increasing in solute concentration with effects on virus survival and decreasing in diameter with effects on sedimentation and respiratory uptake. The aim of this paper is to model the effect of ionic and macromolecular solutes on droplet drying and solute concentration.

METHODS

Deliquescence-efflorescence concepts and Kohler theory were used to simulate the evolution of solute concentrations and water activity in respiratory droplets, starting from efflorescence data on mixed NaCl/KCl aerosols and osmotic pressure data on respiratory macromolecules.

RESULTS

In NaCl/KCl solutions total salt concentrations were shown to reach 10-13 M at the efflorescence RH of 40-55%, depending on the K:Na ratio. Dependence on K:Na ratio implies that the evaporation curves differ between aerosols derived from saliva and from airway surfaces. The direct effect of liquid droplet size through the Kelvin term was shown to be smaller and restricted to the evolution of breath emissions. Modelling the effect of proteins and glycoproteins showed that salts determine drying equilibria down to the efflorescence RH, and macromolecules at lower RH.

CONCLUSION

Differences in solute composition between airway surfaces and saliva are predicted to lead to different drying behaviour of droplets emitted by breathing, speech and coughing. These differences may influence the inactivation of viruses.

摘要

背景与目的

呼吸、说话或咳嗽时喷出的含病毒气溶胶液滴会迅速干燥至与环境相对湿度（RH）达到平衡，溶质浓度增加，这会影响病毒存活，液滴直径减小，这会影响沉降和呼吸道摄取。本文的目的是模拟离子和大分子溶质对液滴干燥和溶质浓度的影响。

方法

利用潮解 - 风化概念和科勒理论来模拟呼吸道液滴中溶质浓度和水分活度的演变，起始数据为混合氯化钠/氯化钾气溶胶的风化数据和呼吸道大分子的渗透压数据。

结果

在氯化钠/氯化钾溶液中，根据钾：钠比例，在40 - 55%的风化相对湿度下，总盐浓度显示达到10 - 13摩尔/升。对钾：钠比例的依赖性意味着源自唾液和气道表面的气溶胶的蒸发曲线不同。通过开尔文项显示的液滴大小的直接影响较小，且仅限于呼气排放的演变。对蛋白质和糖蛋白影响的建模表明，盐决定了直至风化相对湿度时的干燥平衡，而大分子则决定了较低相对湿度时的干燥平衡。

结论

预计气道表面和唾液之间溶质组成的差异会导致呼吸、说话和咳嗽时喷出的液滴具有不同的干燥行为。这些差异可能会影响病毒的灭活。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/47c2/8617110/47682acfd1ee/40201_2021_750_Fig1_HTML.jpg

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含病毒颗粒的干燥：模拟液滴来源及成分的影响

Drying of virus-containing particles: modelling effects of droplet origin and composition.

作者信息

机构信息

出版信息

BACKGROUND AND PURPOSE

METHODS

RESULTS

CONCLUSION

背景与目的

方法

结果

结论

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