Literature DB >> 7811940

An estimated shape function for drift in a platelet-transport model.

C Yeh1, A C Calvez, E C Eckstein.   

Abstract

Prior work has shown that concentration profiles of platelets in flowing whole blood and of platelet-sized beads in flowing blood suspensions can include near-wall excesses. A model to describe this phenomenon was built about a single-component convective diffusion equation. To incorporate redistribution to preferred sites by shear flows of red cell suspensions, the model used a drift shape function (in addition to the commonly used augmented diffusion coefficient). This paper reports experiments that provide an average concentration profile from which the shape function for that model is calculated; the experiments and shape function are for the particular conditions of 40% hematocrit, platelet-sized latex beads (2.5 microns diameter), tube ID of 217 microns, and a wall shear rate of 555 s-1. Less precise estimates of the shape function obtained from data of previous studies indicate that the shape function is similar for the hematocrit of 15%.

Mesh:

Year:  1994        PMID: 7811940      PMCID: PMC1225482          DOI: 10.1016/S0006-3495(94)80595-8

Source DB:  PubMed          Journal:  Biophys J        ISSN: 0006-3495            Impact factor:   4.033


  8 in total

1.  Near wall concentration profiles of 1.0 and 2.5 microns beads during flow of blood suspensions.

Authors:  J F Koleski; E C Eckstein
Journal:  ASAIO Trans       Date:  1991 Jan-Mar

2.  Model of platelet transport in flowing blood with drift and diffusion terms.

Authors:  E C Eckstein; F Belgacem
Journal:  Biophys J       Date:  1991-07       Impact factor: 4.033

3.  Concentration profiles of platelet-sized latex beads for conditions relevant to hollow-fiber hemodialyzers.

Authors:  C M Waters; E C Eckstein
Journal:  Artif Organs       Date:  1990-02       Impact factor: 3.094

4.  Concentration profiles of 1 and 2.5 microns beads during blood flow. Hematocrit effects.

Authors:  E C Eckstein; J F Koleski; C M Waters
Journal:  ASAIO Trans       Date:  1989 Jul-Sep

5.  The near-wall excess of platelet-sized particles in blood flow: its dependence on hematocrit and wall shear rate.

Authors:  A W Tilles; E C Eckstein
Journal:  Microvasc Res       Date:  1987-03       Impact factor: 3.514

6.  Blood platelets are concentrated near the wall and red blood cells, in the center in flowing blood.

Authors:  P A Aarts; S A van den Broek; G W Prins; G D Kuiken; J J Sixma; R M Heethaar
Journal:  Arteriosclerosis       Date:  1988 Nov-Dec

7.  Transient lateral transport of platelet-sized particles in flowing blood suspensions.

Authors:  C Yeh; E C Eckstein
Journal:  Biophys J       Date:  1994-05       Impact factor: 4.033

8.  Localization within a thin optical section of fluorescent blood platelets flowing in a microvessel.

Authors:  G J Tangelder; D W Slaaf; H C Tierlinck; R Alewijnse; R S Reneman
Journal:  Microvasc Res       Date:  1982-03       Impact factor: 3.514
  8 in total
  10 in total

1.  Finite platelet size could be responsible for platelet margination effect.

Authors:  A A Tokarev; A A Butylin; E A Ermakova; E E Shnol; G P Panasenko; F I Ataullakhanov
Journal:  Biophys J       Date:  2011-10-19       Impact factor: 4.033

Review 2.  Biological effects of dynamic shear stress in cardiovascular pathologies and devices.

Authors:  Gaurav Girdhar; Danny Bluestein
Journal:  Expert Rev Med Devices       Date:  2008-03       Impact factor: 3.166

3.  Grow with the flow: a spatial-temporal model of platelet deposition and blood coagulation under flow.

Authors:  Karin Leiderman; Aaron L Fogelson
Journal:  Math Med Biol       Date:  2010-05-03       Impact factor: 1.854

4.  Hematocrit and flow rate regulate the adhesion of platelets to von Willebrand factor.

Authors:  Hsieh Chen; Jennifer I Angerer; Marina Napoleone; Armin J Reininger; Stefan W Schneider; Achim Wixforth; Matthias F Schneider; Alfredo Alexander-Katz
Journal:  Biomicrofluidics       Date:  2013-12-06       Impact factor: 2.800

5.  Computational model of whole blood exhibiting lateral platelet motion induced by red blood cells.

Authors:  Lindsay M Crowl; Aaron L Fogelson
Journal:  Int J Numer Method Biomed Eng       Date:  2010-03-01       Impact factor: 2.747

6.  Multiscale prediction of patient-specific platelet function under flow.

Authors:  Matthew H Flamm; Thomas V Colace; Manash S Chatterjee; Huiyan Jing; Songtao Zhou; Daniel Jaeger; Lawrence F Brass; Talid Sinno; Scott L Diamond
Journal:  Blood       Date:  2012-04-18       Impact factor: 22.113

7.  A MATHEMATICAL MODEL OF PLATELET AGGREGATION IN AN EXTRAVASCULAR INJURY UNDER FLOW.

Authors:  Kathryn G Link; Matthew G Sorrells; Nicholas A Danes; Keith B Neeves; Karin Leiderman; Aaron L Fogelson
Journal:  Multiscale Model Simul       Date:  2020-11-18       Impact factor: 1.930

8.  Fluid Mechanics of Blood Clot Formation.

Authors:  Aaron L Fogelson; Keith B Neeves
Journal:  Annu Rev Fluid Mech       Date:  2015-01-01       Impact factor: 18.511

9.  A General Shear-Dependent Model for Thrombus Formation.

Authors:  Alireza Yazdani; He Li; Jay D Humphrey; George Em Karniadakis
Journal:  PLoS Comput Biol       Date:  2017-01-17       Impact factor: 4.475

Review 10.  Physical forces regulating hemostasis and thrombosis: Vessels, cells, and molecules in illustrated review.

Authors:  Jessica Lin; Matthew G Sorrells; Wilbur A Lam; Keith B Neeves
Journal:  Res Pract Thromb Haemost       Date:  2021-07-14
  10 in total

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