Flow Rate and Wall Shear Stress Characterization of a Biomimetic Aerosol Exposure System.

IF 1.7 4区 医学 Q4 BIOPHYSICS Journal of Biomechanical Engineering-Transactions of the Asme Pub Date : 2024-04-01 DOI:10.1115/1.4064549
S Emma Sarles, Edward C Hensel, Janessa Terry, Caleb Nuss, Risa J Robinson
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Abstract

Current in vitro emissions and exposure systems lack biomimicry, use unrealistic flow conditions, produce unrealistic dose, and provide inaccurate biomechanical cues to cell cultures, limiting ability to correlate in vitro outcomes with in vivo health effects. A biomimetic in vitro system capable of puffing aerosol and clean air inhalation may empower researchers to investigate complex questions related to lung injury and disease. A biomimetic aerosol exposure system (BAES), including an electronic cigarette adapter, oral cavity module (OCM), and bifurcated exposure chamber (BEC) was designed and manufactured. The fraction of aerosol deposited in transit to a filter pad or lost as volatiles was 0.116±0.021 in a traditional emissions setup versus 0.098 ± 0.015 with the adapter. The observed flowrate was within 5% of programed flowrate for puffing (25 mL/s), puff-associated respiration (450 mL/s), and tidal inhalation (350 mL/s). The maximum flowrate observed in the fabricated BAES was 450 mL/s, exceeding the lower target nominal wall shear stress of 0.025 Pa upstream of the bifurcation and fell below the target of 0.02 Pa downstream. This in vitro system addresses several gaps observed in commercially available systems and may be used to study many inhaled aerosols. The current work illustrates how in silico models may be used to correlate results of an in vitro study to in vivo conditions, rather than attempting to design an in vitro system that performs exactly as the human respiratory tract.

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仿生气溶胶曝露系统的流速和壁面剪切应力特征。
目前的体外排放和暴露系统缺乏生物仿真性,使用不切实际的流动条件,产生不切实际的剂量,并为细胞培养提供不准确的生物力学线索,从而限制了将体外结果与体内健康影响相关联的能力。一个能够膨化气溶胶和吸入洁净空气的生物模拟体外系统可使研究人员有能力研究与肺损伤和疾病有关的复杂问题。我们设计并制造了一个生物模拟气溶胶暴露系统,包括电子香烟适配器、口腔模块和分叉暴露室。在传统的排放装置中,气溶胶沉积在过滤垫上或以挥发物形式流失的比例为 0.116 ± 0.021,而使用适配器时为 0.098 ± 0.015。观察到的流速在下列情况下均在设定流速的 5%以内:吹气(25 毫升/秒)、与吹气相关的呼吸(450 毫升/秒)和潮气吸入(350 毫升/秒)。在制造的 BAES 中观察到的最大流速为 450 毫升/秒,在分叉口上游超过了 0.025 帕的较低目标额定壁剪应力,而在下游则低于 0.02 帕的目标值。该体外系统弥补了市售系统的一些不足,可用于研究多种吸入气溶胶。目前的研究工作说明了如何利用硅学模型将体外研究结果与体内条件相关联,而不是试图设计一个与人体呼吸道表现完全一样的体外系统。
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来源期刊
CiteScore
3.40
自引率
5.90%
发文量
169
审稿时长
4-8 weeks
期刊介绍: Artificial Organs and Prostheses; Bioinstrumentation and Measurements; Bioheat Transfer; Biomaterials; Biomechanics; Bioprocess Engineering; Cellular Mechanics; Design and Control of Biological Systems; Physiological Systems.
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