Surface tension driven flow of blood in a rectangular microfluidic channel: Effect of erythrocyte aggregation

Pasias, Dimitris; Passos, Andreas; Constantinides, Georgios; Balabani, Stavroula; Kaliviotis, Efstathios

doi:10.1063/5.0008939

Cited by 23 publications

(28 citation statements)

References 59 publications

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“…Therefore, if aggregation increases, then blood viscosity increases as well and the shear-thinning behavior of blood is altered. Numerical studies have demonstrated the effects of aggregation in blood viscosity [120,122,[152][153][154] and experimental studies have observed that RBCs' deformability induces cell aggregation during flow in microcapillaries, allowing the formation of clusters of cells [98,155,156]. Moreover, the aging of storaged RBCs also contributes to the increase in aggregation and affects its viscosity.…”

Section: Comparison With Numerical Results Of the Collective Behavior...mentioning

confidence: 99%

“…Eventually, high-speed and high-resolution cameras, with an enhanced sensitivity and mounted to an optical microscope, enabled velocity measurements of such small-scale flows. In this aspect, several techniques have been developed to measure the velocity fields of blood and RBCs at the microscale, such as µPIV (microparticles image velocimetry) or PTV (particle tracking velocimetry) and wavelet-based optical flow velocimetry (wOFV) [95][96][97][98][99]. 5), is averaged for different initial conditions of the RBC.…”

Section: Hemodynamics and Hemorheology For A Single Cellmentioning

confidence: 99%

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Microfluidics Approach to the Mechanical Properties of Red Blood Cell Membrane and Their Effect on Blood Rheology

et al. 2022

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In this article, we describe the general features of red blood cell membranes and their effect on blood flow and blood rheology. We first present a basic description of membranes and move forward to red blood cell membranes’ characteristics and modeling. We later review the specific properties of red blood cells, presenting recent numerical and experimental microfluidics studies that elucidate the effect of the elastic properties of the red blood cell membrane on blood flow and hemorheology. Finally, we describe specific hemorheological pathologies directly related to the mechanical properties of red blood cells and their effect on microcirculation, reviewing microfluidic applications for the diagnosis and treatment of these diseases.

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Section: Comparison With Numerical Results Of the Collective Behavior...mentioning

confidence: 99%

Section: Hemodynamics and Hemorheology For A Single Cellmentioning

confidence: 99%

Microfluidics Approach to the Mechanical Properties of Red Blood Cell Membrane and Their Effect on Blood Rheology

et al. 2022

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“…These alterations contribute to a reduction of mass transport and interrupt the blood flow in capillary vessels. To effectively detect changes in blood samples from a physical point of view, several rheological properties (i.e., viscosity [ 3 , 4 , 5 , 6 ], viscoelasticity [ 7 ], red blood cell (RBC) deformability [ 8 , 9 , 10 , 11 , 12 , 13 ], RBC aggregation [ 14 , 15 , 16 , 17 ], RBC sedimentation rate [ 18 , 19 ], and Hct [ 20 ]) have been measured for screening or diagnosing various diseases, including coronary heart disease, hypertension, diabetes [ 21 ], sickle cell anemia [ 22 , 23 ], and malaria. Plasma protein (i.e., fibrinogen) contributes to increasing RBC aggregation.…”

Section: Introductionmentioning

confidence: 99%

“…Although a blood flow rate can be estimated consistently with micro-particle image velocimetry (PIV) [ 31 ], it is very difficult to obtain an accurate flow rate of a blood sample. The flow rate obtained with micro-PIV varies strongly with several factors, such as flow rate, hematocrit, diluent, RBC aggregation, and RBC deformability [ 13 , 14 , 29 ]. Whenever blood viscosity is to be monitored, tedious calibration procedures are required in advance using the same blood sample.…”

Section: Introductionmentioning

confidence: 99%

Assessment of Blood Biophysical Properties Using Pressure Sensing with Micropump and Microfluidic Comparator

Kang

2022

Micromachines

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To identify the biophysical properties of blood samples consistently, macroscopic pumps have been used to maintain constant flow rates in a microfluidic comparator. In this study, the bulk-sized and expensive pump is replaced with a cheap and portable micropump. A specific reference fluid (i.e., glycerin solution [40%]) with a small volume of red blood cell (RBC) (i.e., 1% volume fraction) as fluid tracers is supplied into the microfluidic comparator. An averaged velocity (<Ur>) obtained with micro-particle image velocimetry is converted into the flow rate of reference fluid (Qr) (i.e., Qr = CQ × Ac × <Ur>, Ac: cross-sectional area, CQ = 1.156). Two control variables of the micropump (i.e., frequency: 400 Hz and volt: 150 au) are selected to guarantee a consistent flow rate (i.e., COV < 1%). Simultaneously, the blood sample is supplied into the microfluidic channel under specific flow patterns (i.e., constant, sinusoidal, and periodic on-off fashion). By monitoring the interface in the comparator as well as Qr, three biophysical properties (i.e., viscosity, junction pressure, and pressure-induced work) are obtained using analytical expressions derived with a discrete fluidic circuit model. According to the quantitative comparison results between the present method (i.e., micropump) and the previous method (i.e., syringe pump), the micropump provides consistent results when compared with the syringe pump. Thereafter, representative biophysical properties, including the RBC aggregation, are consistently obtained for specific blood samples prepared with dextran solutions ranging from 0 to 40 mg/mL. In conclusion, the present method could be considered as an effective method for quantifying the physical properties of blood samples, where the reference fluid is supplied with a cheap and portable micropump.

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“…Methods such as image segmentation allow the identification of structures with specific characteristics [ 25 , 26 ]. To accommodate the blood sample to be processed, simple microfluidic configurations are often used, offering several advantages [ 27 , 28 , 29 , 30 ]. Other techniques, such piezocoagulography, have been also utilized for blood coagulation, showing also the possibility of studying the initial stage of fibrin formation in the clotting process [ 31 ].…”

Section: Introductionmentioning

confidence: 99%

Development of an Optical Method for the Evaluation of Whole Blood Coagulation

Louka

Kaliviotis

2021

Biosensors

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Blood coagulation is a defense mechanism, which is activated in case of blood loss, due to vessel damage, or other injury. Pathological cases arise from malfunctions of the blood coagulation mechanism, and rapid growth of clots results in partially or even fully blocked blood vessel. The aim of this work is to characterize blood coagulation, by analyzing the time-dependent structural properties of whole blood, using an inexpensive design and robust processing approaches. The methods used in this work include brightfield microscopy and image processing techniques, applied on finger-prick blood samples. The blood samples were produced and directly utilized in custom-made glass microchannels. Color images were captured via a microscopy-camera setup for a period of 35 min, utilizing three different magnifications. Statistical information was extracted directly from the color components and the binary conversions of the images. The main advantage in the current work lies on a Boolean classification approach utilized on the binary data, which enabled to identify the interchange between specific structural elements of blood, namely the red blood cells, the plasma and the clotted regions, as a result of the clotting process. Coagulation indices produced included a bulk coagulation index, a plasma-reduction based index and a clot formation index. The results produced with the inexpensive design and the low computational complexity in the current approach, show good agreement with the literature, and a great potential for a robust characterization of blood coagulation.

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Surface tension driven flow of blood in a rectangular microfluidic channel: Effect of erythrocyte aggregation

Cited by 23 publications

References 59 publications

Microfluidics Approach to the Mechanical Properties of Red Blood Cell Membrane and Their Effect on Blood Rheology

Microfluidics Approach to the Mechanical Properties of Red Blood Cell Membrane and Their Effect on Blood Rheology

Assessment of Blood Biophysical Properties Using Pressure Sensing with Micropump and Microfluidic Comparator

Development of an Optical Method for the Evaluation of Whole Blood Coagulation

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