Tzu Chieh Chao1, Omid Arjmandi-Tash2, Diganta B Das3, Victor M Starov4. 1. Department of Chemical Engineering, Loughborough University, Loughborough LE11 3TU, UK. Electronic address: T.Chao@lboro.ac.uk. 2. Department of Chemical Engineering, Loughborough University, Loughborough LE11 3TU, UK. Electronic address: O.Arjmandi-Tash@lboro.ac.uk. 3. Department of Chemical Engineering, Loughborough University, Loughborough LE11 3TU, UK. Electronic address: d.b.das@lboro.ac.uk. 4. Department of Chemical Engineering, Loughborough University, Loughborough LE11 3TU, UK. Electronic address: v.m.starov@lboro.ac.uk.
Abstract
HYPOTHESIS: The process of dried blood spot sampling involves simultaneous spreading and penetration of blood into a porous filter paper with subsequent evaporation and drying. Spreading of small drops of blood, which is a non-Newtonian liquid, over a dry porous layer is investigated from both theoretical and experimental points of view. EXPERIMENTS AND THEORY: A system of two differential equations is derived, which describes the time evolution of radii of both the drop base and the wetted region inside the porous medium. The system of equations does not include any fitting parameters. The predicted time evolutions of both radii are compared with experimental data published earlier. FINDINGS: For a given power law dependency of viscosity of blood with different hematocrit level, radii of both drop base and wetted region, and contact angle fell on three universal curves if appropriate scales are used with a plot of the dimensionless radii of the drop base and the wetted region inside the porous layer and dynamic contact angle on dimensionless time. The predicted theoretical relationships are three universal curves accounting satisfactorily for the experimental data.
HYPOTHESIS: The process of dried blood spot sampling involves simultaneous spreading and penetration of blood into a porous filter paper with subsequent evaporation and drying. Spreading of small drops of blood, which is a non-Newtonian liquid, over a dry porous layer is investigated from both theoretical and experimental points of view. EXPERIMENTS AND THEORY: A system of two differential equations is derived, which describes the time evolution of radii of both the drop base and the wetted region inside the porous medium. The system of equations does not include any fitting parameters. The predicted time evolutions of both radii are compared with experimental data published earlier. FINDINGS: For a given power law dependency of viscosity of blood with different hematocrit level, radii of both drop base and wetted region, and contact angle fell on three universal curves if appropriate scales are used with a plot of the dimensionless radii of the drop base and the wetted region inside the porous layer and dynamic contact angle on dimensionless time. The predicted theoretical relationships are three universal curves accounting satisfactorily for the experimental data.
Authors: Kristina Malsagova; Artur Kopylov; Alexander Stepanov; Tatyana Butkova; Alexander Izotov; Anna Kaysheva Journal: Diagnostics (Basel) Date: 2020-04-23