Designing Microfluidic Devices to Sort Haematopoietic Stem Cells Based on Their Mechanical Properties

Designing Microfluidic Devices to Sort Haematopoietic Stem Cells Based on Their Mechanical Properties

Aim. Few haematopoietic stem cells (HSCs) injected systemically for therapeutic purposes actually reach sites of injury as the vast majority become entrapped within pulmonary capillaries. One promising approach to maintain circulating HSC numbers would be to separate subpopulations with smaller size...

Full description

Bibliographic Details
Main Authors: Mingming Du, Dean Kavanagh, Zhibing Zhang, Neena Kalia
Format: Article
Language:English
Published: Hindawi Limited 2019-01-01
Series:Stem Cells International
Online Access:http://dx.doi.org/10.1155/2019/8540706
id doaj-91e6fec32bb549a09f4468eb7fff751b
record_format Article
spelling doaj-91e6fec32bb549a09f4468eb7fff751b2020-11-24T21:27:49ZengHindawi LimitedStem Cells International1687-966X1687-96782019-01-01201910.1155/2019/85407068540706Designing Microfluidic Devices to Sort Haematopoietic Stem Cells Based on Their Mechanical PropertiesMingming Du0Dean Kavanagh1Zhibing Zhang2Neena Kalia3School of Chemical Engineering, University of Birmingham, Birmingham, B15 2TT, UKInstitute of Cardiovascular Sciences, University of Birmingham, Birmingham, B15 2TT, UKSchool of Chemical Engineering, University of Birmingham, Birmingham, B15 2TT, UKInstitute of Cardiovascular Sciences, University of Birmingham, Birmingham, B15 2TT, UKAim. Few haematopoietic stem cells (HSCs) injected systemically for therapeutic purposes actually reach sites of injury as the vast majority become entrapped within pulmonary capillaries. One promising approach to maintain circulating HSC numbers would be to separate subpopulations with smaller size and/or greater deformability from a heterogeneous population. This study tested whether this could be achieved using label-free microfluidic devices. Methods. 2 straight (A-B) and 3 spiral (C-E) devices were fabricated with different dimensions. Cell sorting was performed at different flow rates after which cell diameter and stiffness were determined using micromanipulation. Cells isolated using the most efficient device were tested intravitally for their ability to home to the mouse injured gut. Results. Only straight Device B at a high flow rate separated HSCs with different mechanical properties. Side outlets collected mostly deformable cells (nominal rupture stress/σR=6.81 kPa; coefficient of variation/CV=0.31) at a throughput of 2.3×105 cells/min. All spiral devices at high flow rates separated HSCs with different stiffness and size. Inner outlets collected mostly deformable cells in Devices C (σR=25.06 kPa; CV=0.26), D (σR=22.21 kPa; CV=0.41), and E (σR=29.26 kPa; CV=0.27) at throughputs of 2.3×105 cells/min, 1.5×105 cells/min, and 1.6×105 cells/min, respectively. Since Device C separated cells with higher efficiency and throughput, it was utilized to test the homing ability of separated cells in vivo. Significantly more deformable cells were observed trafficking through the injured gut—interestingly, increased retention was not observed. Conclusion. This study applied microfluidics to separate subpopulations from one stem cell type based on their intrinsic mechanical heterogeneity. Fluid dynamics within curved devices most effectively separated HSCs. Such devices may benefit cellular therapy.http://dx.doi.org/10.1155/2019/8540706
collection DOAJ
language English
format Article
sources DOAJ
author Mingming Du
Dean Kavanagh
Zhibing Zhang
Neena Kalia
spellingShingle Mingming Du
Dean Kavanagh
Zhibing Zhang
Neena Kalia
Designing Microfluidic Devices to Sort Haematopoietic Stem Cells Based on Their Mechanical Properties
Stem Cells International
author_facet Mingming Du
Dean Kavanagh
Zhibing Zhang
Neena Kalia
author_sort Mingming Du
title Designing Microfluidic Devices to Sort Haematopoietic Stem Cells Based on Their Mechanical Properties
title_short Designing Microfluidic Devices to Sort Haematopoietic Stem Cells Based on Their Mechanical Properties
title_full Designing Microfluidic Devices to Sort Haematopoietic Stem Cells Based on Their Mechanical Properties
title_fullStr Designing Microfluidic Devices to Sort Haematopoietic Stem Cells Based on Their Mechanical Properties
title_full_unstemmed Designing Microfluidic Devices to Sort Haematopoietic Stem Cells Based on Their Mechanical Properties
title_sort designing microfluidic devices to sort haematopoietic stem cells based on their mechanical properties
publisher Hindawi Limited
series Stem Cells International
issn 1687-966X
1687-9678
publishDate 2019-01-01
description Aim. Few haematopoietic stem cells (HSCs) injected systemically for therapeutic purposes actually reach sites of injury as the vast majority become entrapped within pulmonary capillaries. One promising approach to maintain circulating HSC numbers would be to separate subpopulations with smaller size and/or greater deformability from a heterogeneous population. This study tested whether this could be achieved using label-free microfluidic devices. Methods. 2 straight (A-B) and 3 spiral (C-E) devices were fabricated with different dimensions. Cell sorting was performed at different flow rates after which cell diameter and stiffness were determined using micromanipulation. Cells isolated using the most efficient device were tested intravitally for their ability to home to the mouse injured gut. Results. Only straight Device B at a high flow rate separated HSCs with different mechanical properties. Side outlets collected mostly deformable cells (nominal rupture stress/σR=6.81 kPa; coefficient of variation/CV=0.31) at a throughput of 2.3×105 cells/min. All spiral devices at high flow rates separated HSCs with different stiffness and size. Inner outlets collected mostly deformable cells in Devices C (σR=25.06 kPa; CV=0.26), D (σR=22.21 kPa; CV=0.41), and E (σR=29.26 kPa; CV=0.27) at throughputs of 2.3×105 cells/min, 1.5×105 cells/min, and 1.6×105 cells/min, respectively. Since Device C separated cells with higher efficiency and throughput, it was utilized to test the homing ability of separated cells in vivo. Significantly more deformable cells were observed trafficking through the injured gut—interestingly, increased retention was not observed. Conclusion. This study applied microfluidics to separate subpopulations from one stem cell type based on their intrinsic mechanical heterogeneity. Fluid dynamics within curved devices most effectively separated HSCs. Such devices may benefit cellular therapy.
url http://dx.doi.org/10.1155/2019/8540706
work_keys_str_mv AT mingmingdu designingmicrofluidicdevicestosorthaematopoieticstemcellsbasedontheirmechanicalproperties
AT deankavanagh designingmicrofluidicdevicestosorthaematopoieticstemcellsbasedontheirmechanicalproperties
AT zhibingzhang designingmicrofluidicdevicestosorthaematopoieticstemcellsbasedontheirmechanicalproperties
AT neenakalia designingmicrofluidicdevicestosorthaematopoieticstemcellsbasedontheirmechanicalproperties
_version_ 1725973195895341056

Similar Items