The effect of particle seeding on the rheological properties of blood Analog fluid used during laser Doppler velocimetry.

IF 0.8 4区医学 Q4 BIOPHYSICS

Biorheology Pub Date : 2025-09-05 DOI:10.1177/0006355X251375279

Shreyash M Manegaonkar, Israel O Ajiboye, Sana Sukhija, Deveshi Sukhija, Rupak K Banerjee

{"title":"The effect of particle seeding on the rheological properties of blood Analog fluid used during laser Doppler velocimetry.","authors":"Shreyash M Manegaonkar, Israel O Ajiboye, Sana Sukhija, Deveshi Sukhija, Rupak K Banerjee","doi":"10.1177/0006355X251375279","DOIUrl":null,"url":null,"abstract":"BackgroundThe viscosity of blood analog fluid (BAF) influences the hemodynamics during testing of medical devices and implants in cardiovascular systems mimicking physiologic flow conditions. BAF, typically composed of water, glycerin, and Xanthan gum, is used to simulate blood's non-Newtonian shear-thinning behavior. Additionally, BAF may include microsphere particles for flow visualization in Laser Doppler Velocimetry (LDV) experiments, though their impact on viscosity remained an under-investigated area. Hypothesis: Addition of particles in the form of polymer microspheres in a BAF solution influences the rheological properties of the fluid.MethodsThree different test fluids comprising of 16 ml BAF solution with the varying concentrations of polymer microspheres were created: 1% (weight/volume; w/v) and 2% w/v represent test samples, whereas 0% w/v (no microsphere) represents a control sample. The viscosities of BAF for with and without polymer microspheres were measured using a concentric cylinder viscometer. Recorded viscosity data was then optimized by fitting the Carreau model.ResultsSeeding of polymer microspheres in BAF results in significant changes in shear-thinning properties, such as zero- and infinite-viscosity (<math><msub><mi>μ</mi><mn>0</mn></msub></math> and <math><msub><mi>μ</mi><mi>∞</mi></msub></math>, respectively), in relation to viscosity of real blood or BAF without microspheres. It is evident that effect of microsphere seeding in BAF is relatively more pronounced on <math><msub><mi>μ</mi><mn>0</mn></msub></math> as compared to <math><msub><mi>μ</mi><mi>∞</mi></msub></math>.ConclusionPolymer microspheres in BAF significantly alters its shear-thinning properties and must be considered for better hemodynamic evaluations in medical device testing.","PeriodicalId":9167,"journal":{"name":"Biorheology","volume":" ","pages":"6355X251375279"},"PeriodicalIF":0.8000,"publicationDate":"2025-09-05","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Biorheology","FirstCategoryId":"5","ListUrlMain":"https://doi.org/10.1177/0006355X251375279","RegionNum":4,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"BIOPHYSICS","Score":null,"Total":0}

引用次数: 0

Abstract

BackgroundThe viscosity of blood analog fluid (BAF) influences the hemodynamics during testing of medical devices and implants in cardiovascular systems mimicking physiologic flow conditions. BAF, typically composed of water, glycerin, and Xanthan gum, is used to simulate blood's non-Newtonian shear-thinning behavior. Additionally, BAF may include microsphere particles for flow visualization in Laser Doppler Velocimetry (LDV) experiments, though their impact on viscosity remained an under-investigated area. Hypothesis: Addition of particles in the form of polymer microspheres in a BAF solution influences the rheological properties of the fluid.MethodsThree different test fluids comprising of 16 ml BAF solution with the varying concentrations of polymer microspheres were created: 1% (weight/volume; w/v) and 2% w/v represent test samples, whereas 0% w/v (no microsphere) represents a control sample. The viscosities of BAF for with and without polymer microspheres were measured using a concentric cylinder viscometer. Recorded viscosity data was then optimized by fitting the Carreau model.ResultsSeeding of polymer microspheres in BAF results in significant changes in shear-thinning properties, such as zero- and infinite-viscosity ( $μ_{0}$ and $μ_{\infty}$ , respectively), in relation to viscosity of real blood or BAF without microspheres. It is evident that effect of microsphere seeding in BAF is relatively more pronounced on $μ_{0}$ as compared to $μ_{\infty}$ .ConclusionPolymer microspheres in BAF significantly alters its shear-thinning properties and must be considered for better hemodynamic evaluations in medical device testing.

查看原文本刊更多论文

粒子播种对激光多普勒测速中血液模拟流体流变特性的影响。

背景：血液模拟液（BAF）的粘度影响心血管系统中模拟生理流动条件的医疗器械和植入物测试过程中的血液动力学。BAF通常由水、甘油和黄原胶组成，用于模拟血液的非牛顿剪切变薄行为。此外，在激光多普勒测速（LDV）实验中，BAF可能包括用于流动显示的微球颗粒，尽管它们对粘度的影响仍然是一个尚未研究的领域。假设：在BAF溶液中加入聚合物微球形式的颗粒会影响流体的流变性能。方法制备了三种不同的测试液，由16 ml的BAF溶液组成，其中含有不同浓度的聚合物微球：1%（重量/体积；w/v）和2% w/v代表测试样品，而0% w/v（无微球）代表对照样品。用同心圆柱粘度计测定了含和不含聚合物微球的BAF的粘度。然后通过拟合carcarau模型对记录的粘度数据进行优化。结果在BAF中加入聚合物微球后，与真实血液或未加入微球的BAF相比，BAF的剪切减薄性能发生了显著变化，如零粘度和无限粘度（分别为μ0和μ∞）。可见，微球播种对BAF的影响在μ0比μ∞更明显。结论在BAF中加入聚合物微球可显著改变BAF的剪切减薄性能，在医疗器械的血流动力学评价中应予以考虑。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Biorheology 医学-工程：生物医学

CiteScore

2.00

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Biorheology is an international interdisciplinary journal that publishes research on the deformation and flow properties of biological systems or materials. It is the aim of the editors and publishers of Biorheology to bring together contributions from those working in various fields of biorheological research from all over the world. A diverse editorial board with broad international representation provides guidance and expertise in wide-ranging applications of rheological methods to biological systems and materials. The scope of papers solicited by Biorheology extends to systems at different levels of organization that have never been studied before, or, if studied previously, have either never been analyzed in terms of their rheological properties or have not been studied from the point of view of the rheological matching between their structural and functional properties. This biorheological approach applies in particular to molecular studies where changes of physical properties and conformation are investigated without reference to how the process actually takes place, how the forces generated are matched to the properties of the structures and environment concerned, proper time scales, or what structures or strength of structures are required.