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Characterization and Separation of Suspension Cells by Isoacoustic Focusing

Rezayati Charan, Mahdi LU (2023)
Abstract
Enabling techniques for separating target cells, such as subgroups of white blood cells and cancer
cells from blood and other body fluids, are necessary for lab work facilitation, inline integration with
high-end bioanalytical instrumentation, and for point-of-care or home testing. The work of this thesis
addresses this need by further studying an equilibrium-based ultrasonic wave-based technology called
isoacoustic focusing to characterize and gain access to cells. In this size-insensitive technique, cells are
suspended in a microchannel filled with an inhomogeneous medium where the interaction of diffusion,
gravity, and acoustic radiation shapes a smooth gradient profile for the acoustic impedance of the
media... (More)
Enabling techniques for separating target cells, such as subgroups of white blood cells and cancer
cells from blood and other body fluids, are necessary for lab work facilitation, inline integration with
high-end bioanalytical instrumentation, and for point-of-care or home testing. The work of this thesis
addresses this need by further studying an equilibrium-based ultrasonic wave-based technology called
isoacoustic focusing to characterize and gain access to cells. In this size-insensitive technique, cells are
suspended in a microchannel filled with an inhomogeneous medium where the interaction of diffusion,
gravity, and acoustic radiation shapes a smooth gradient profile for the acoustic impedance of the
media orthogonal to the flow. While flowing, the acoustic radiation force pushes cells towards their
isoacoustic point where the acoustic contrast and radiation force become zero and cells’ acoustically
induced sideways displacement ceases. The first two included papers in this thesis uncover in detail the
acoustophoretic motion of cells suspended in homogeneous and inhomogeneous media in a stop-flow
condition. Cell three-dimensional trajectories were measured by a defocused-image tracking approach,
and the technique’s applicability for tracking cells was assessed by determining the associated error
when measuring the out-of-image-plane component of the tracks. In a homogeneous medium, for cells
with near-zero acoustic contrast, strong effects of buoyancy and acoustic streaming were observed,
and small distributions of cell properties within a population resulted in large differences in the
cell motion patterns. The second article shows how cells migrate towards their iso-acoustic point in
acoustic impedance gradient media while acoustic streaming is substantially suppressed. This enabled
the readout of the effective acoustic impedance of neutrophils and K562 cancer cells. A numerical
model was introduced to estimate the acoustic energy density in the acoustic impedance gradient
media by tracking particles of known properties. To examine cell separation based on the knowledge
acquired in the two first studies, the third paper presents the use of gradient acoustic focusing and
dense media containing iodixanol to purify peripheral blood mononuclear cells (PBMCs) from whole
blood in a label-free and flow-through format. By modifying the medium and thus tuning the contrast
factor of the cells, PBMCs were enriched relative to RBCs by a factor of 3600 to 11000 and with a
separation efficiency of 85%. Such a level of RBC depletion is high compared to most other microfluidic
methods and similar to density centrifugation. In the fourth Paper, we show that cell compressibility
can be determined at the isoacoustic point by an independent measurement of the density of each cell.
Cells were pre-sorted off-chip in linear, continuous, and reproducible density gradients, and fractions
with known densities were fed into an isoacoustic focusing device. The relation between density and
compressibility for two cell types was investigated, and it was found that for increasing density of
K562 cells, the compressibility decreases. For neutrophils, the compressibility was measured, and a
slight change was observed with increasing density. (Less)
Please use this url to cite or link to this publication:
author
supervisor
opponent
  • Prof. Viklund, Martin, KTH Royal Institute of Technology, Sweden.
organization
publishing date
type
Thesis
publication status
published
subject
publisher
Department of Biomedical Engineering, Lund university
defense location
Lecture Hall E:1406, building E, Ole Römers väg 3, Faculty of Engineering LTH, Lund University, Lund.
defense date
2023-11-10 09:00:00
ISBN
978-91-8039-858-9
978-91-8039-857-2
language
English
LU publication?
yes
id
4ea269d2-a275-4ecd-b691-26d50d4da67e
date added to LUP
2023-10-13 16:04:48
date last changed
2024-02-13 11:29:42
@phdthesis{4ea269d2-a275-4ecd-b691-26d50d4da67e,
  abstract     = {{Enabling techniques for separating target cells, such as subgroups of white blood cells and cancer<br/>cells from blood and other body fluids, are necessary for lab work facilitation, inline integration with<br/>high-end bioanalytical instrumentation, and for point-of-care or home testing. The work of this thesis<br/>addresses this need by further studying an equilibrium-based ultrasonic wave-based technology called<br/>isoacoustic focusing to characterize and gain access to cells. In this size-insensitive technique, cells are<br/>suspended in a microchannel filled with an inhomogeneous medium where the interaction of diffusion,<br/>gravity, and acoustic radiation shapes a smooth gradient profile for the acoustic impedance of the<br/>media orthogonal to the flow. While flowing, the acoustic radiation force pushes cells towards their<br/>isoacoustic point where the acoustic contrast and radiation force become zero and cells’ acoustically<br/>induced sideways displacement ceases. The first two included papers in this thesis uncover in detail the<br/>acoustophoretic motion of cells suspended in homogeneous and inhomogeneous media in a stop-flow<br/>condition. Cell three-dimensional trajectories were measured by a defocused-image tracking approach,<br/>and the technique’s applicability for tracking cells was assessed by determining the associated error<br/>when measuring the out-of-image-plane component of the tracks. In a homogeneous medium, for cells<br/>with near-zero acoustic contrast, strong effects of buoyancy and acoustic streaming were observed,<br/>and small distributions of cell properties within a population resulted in large differences in the<br/>cell motion patterns. The second article shows how cells migrate towards their iso-acoustic point in<br/>acoustic impedance gradient media while acoustic streaming is substantially suppressed. This enabled<br/>the readout of the effective acoustic impedance of neutrophils and K562 cancer cells. A numerical<br/>model was introduced to estimate the acoustic energy density in the acoustic impedance gradient<br/>media by tracking particles of known properties. To examine cell separation based on the knowledge<br/>acquired in the two first studies, the third paper presents the use of gradient acoustic focusing and<br/>dense media containing iodixanol to purify peripheral blood mononuclear cells (PBMCs) from whole<br/>blood in a label-free and flow-through format. By modifying the medium and thus tuning the contrast<br/>factor of the cells, PBMCs were enriched relative to RBCs by a factor of 3600 to 11000 and with a<br/>separation efficiency of 85%. Such a level of RBC depletion is high compared to most other microfluidic<br/>methods and similar to density centrifugation. In the fourth Paper, we show that cell compressibility<br/>can be determined at the isoacoustic point by an independent measurement of the density of each cell.<br/>Cells were pre-sorted off-chip in linear, continuous, and reproducible density gradients, and fractions<br/>with known densities were fed into an isoacoustic focusing device. The relation between density and<br/>compressibility for two cell types was investigated, and it was found that for increasing density of<br/>K562 cells, the compressibility decreases. For neutrophils, the compressibility was measured, and a<br/>slight change was observed with increasing density.}},
  author       = {{Rezayati Charan, Mahdi}},
  isbn         = {{978-91-8039-858-9}},
  language     = {{eng}},
  month        = {{10}},
  publisher    = {{Department of Biomedical Engineering, Lund university}},
  school       = {{Lund University}},
  title        = {{Characterization and Separation of Suspension Cells by Isoacoustic Focusing}},
  url          = {{https://lup.lub.lu.se/search/files/161855142/PhD_Kappa_MRC.pdf}},
  year         = {{2023}},
}