Impedance-based microfluidic cytometry for label-free monitoring and on-demand microcarrier sorting

Impedance-based microfluidic cytometry for label-free monitoring and on-demand microcarrier sorting

In cell-based manufacturing, three-dimensional (3D) cell cultures, including spheroids (cellular aggregates), microcarriers and hydrogel microparticles (~100-300 µm) are widely used for scaled-up cell expansion and cell processing in tissue engineering, cell therapies, etc. Conventional bioprocess s...

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Main Author: Gong, Lingyan
Other Authors: Hou Han Wei
Format: Thesis-Doctor of Philosophy
Language:English
Published: Nanyang Technological University 2024
Subjects:
Engineering
Medicine, Health and Life Sciences
Microfluidics
Impedance cytometry
Actuated sorting
Microcarriers
Cell aggregates
Hydrogel microparticles
Cell-based manufacturing
Online Access:https://hdl.handle.net/10356/174073
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1740732024-04-09T03:58:58Z Impedance-based microfluidic cytometry for label-free monitoring and on-demand microcarrier sorting Gong, Lingyan Hou Han Wei School of Mechanical and Aerospace Engineering hwhou@ntu.edu.sg Engineering Medicine, Health and Life Sciences Microfluidics Impedance cytometry Actuated sorting Microcarriers Cell aggregates Hydrogel microparticles Cell-based manufacturing In cell-based manufacturing, three-dimensional (3D) cell cultures, including spheroids (cellular aggregates), microcarriers and hydrogel microparticles (~100-300 µm) are widely used for scaled-up cell expansion and cell processing in tissue engineering, cell therapies, etc. Conventional bioprocess sensors measure culture medium bulk properties (e.g. gases, pH, temperature, metabolites) to monitor biomass indirectly which provide limited information on cell heterogeneity and product quality. This advocates an unmet need to develop novel in-line monitoring methodologies to enable accurate monitoring of cell growth and cell quality (size, viability etc.) in continuous bioprocesses. In this PhD thesis, we first developed a novel multi-frequency microfluidic impedance cytometry device for label-free monitoring of cellular properties of single spheroids, Cytodex microcarriers and cell-encapsulated hydrogel microparticles. Two impedance signatures namely 1) low-frequency impedance (|ZLF|) and 2) opacity defined as the ratio of high-frequency impedance to low-frequency impedance (|ZHF|/|ZLF|), were defined to assess biomass and cell viability at single particle resolution. Using breast cancer (MCF-7) spheroids and HaCaT cell-encapsulated hydrogel particles, we demonstrated that |ZLF| increased with biomass, while higher opacity indicated cell death due to compromised cell membrane. Anti-cancer drug (Paclitaxel)-treated spheroids exhibited lower |ZLF| with increased cell dissociation. Interestingly, adipose-derived mesenchymal stem cell (ADSC) differentiation on Cytodex-3 microcarriers exhibited higher impedance magnitude when differentiating into adipocytes due to intracellular lipid content, and higher opacity when differentiating into osteoblasts due to calcium deposition and changes in membrane components. To achieve continuous harvesting of cellular products, the device is integrated with a real-time piezo-actuated particle sorter based on user-defined multi-frequency impedance signatures. We first performed biomass profiling of Cytodex-3 microcarriers seeded with adipose-derived mesenchymal stem cells (ADSCs) to sort well-seeded or confluent microcarriers for downstream culture or harvesting, respectively. Next, we demonstrated impedance-based isolation of microcarriers with osteogenic differentiated ADSCs which was validated with a two-fold increase of calcium content in sorted ADSCs. Impedance profiling of heterogenous ADSCs-encapsulated hydrogel (alginate) microparticles and 3D ADSC aggregate mixtures was also performed to sort particles with high biomass and cell viability to improve cell quality. Overall, the scalable microfluidic platform technology enables in-line sample processing from bioreactors directly and automated analysis (up to 200 particles/sec) of cell quality attributes and on-demand sorting (up to 10 particles/sec) to maximize cell yield and improve the control of cell quality in continuous cell-based manufacturing. Doctor of Philosophy 2024-03-15T00:02:09Z 2024-03-15T00:02:09Z 2023 Thesis-Doctor of Philosophy Gong, L. (2023). Impedance-based microfluidic cytometry for label-free monitoring and on-demand microcarrier sorting. Doctoral thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/174073 https://hdl.handle.net/10356/174073 10.32657/10356/174073 en This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (CC BY-NC 4.0). application/pdf Nanyang Technological University
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering
Medicine, Health and Life Sciences
Microfluidics
Impedance cytometry
Actuated sorting
Microcarriers
Cell aggregates
Hydrogel microparticles
Cell-based manufacturing
spellingShingle Engineering
Medicine, Health and Life Sciences
Microfluidics
Impedance cytometry
Actuated sorting
Microcarriers
Cell aggregates
Hydrogel microparticles
Cell-based manufacturing
Gong, Lingyan
Impedance-based microfluidic cytometry for label-free monitoring and on-demand microcarrier sorting
description In cell-based manufacturing, three-dimensional (3D) cell cultures, including spheroids (cellular aggregates), microcarriers and hydrogel microparticles (~100-300 µm) are widely used for scaled-up cell expansion and cell processing in tissue engineering, cell therapies, etc. Conventional bioprocess sensors measure culture medium bulk properties (e.g. gases, pH, temperature, metabolites) to monitor biomass indirectly which provide limited information on cell heterogeneity and product quality. This advocates an unmet need to develop novel in-line monitoring methodologies to enable accurate monitoring of cell growth and cell quality (size, viability etc.) in continuous bioprocesses. In this PhD thesis, we first developed a novel multi-frequency microfluidic impedance cytometry device for label-free monitoring of cellular properties of single spheroids, Cytodex microcarriers and cell-encapsulated hydrogel microparticles. Two impedance signatures namely 1) low-frequency impedance (|ZLF|) and 2) opacity defined as the ratio of high-frequency impedance to low-frequency impedance (|ZHF|/|ZLF|), were defined to assess biomass and cell viability at single particle resolution. Using breast cancer (MCF-7) spheroids and HaCaT cell-encapsulated hydrogel particles, we demonstrated that |ZLF| increased with biomass, while higher opacity indicated cell death due to compromised cell membrane. Anti-cancer drug (Paclitaxel)-treated spheroids exhibited lower |ZLF| with increased cell dissociation. Interestingly, adipose-derived mesenchymal stem cell (ADSC) differentiation on Cytodex-3 microcarriers exhibited higher impedance magnitude when differentiating into adipocytes due to intracellular lipid content, and higher opacity when differentiating into osteoblasts due to calcium deposition and changes in membrane components. To achieve continuous harvesting of cellular products, the device is integrated with a real-time piezo-actuated particle sorter based on user-defined multi-frequency impedance signatures. We first performed biomass profiling of Cytodex-3 microcarriers seeded with adipose-derived mesenchymal stem cells (ADSCs) to sort well-seeded or confluent microcarriers for downstream culture or harvesting, respectively. Next, we demonstrated impedance-based isolation of microcarriers with osteogenic differentiated ADSCs which was validated with a two-fold increase of calcium content in sorted ADSCs. Impedance profiling of heterogenous ADSCs-encapsulated hydrogel (alginate) microparticles and 3D ADSC aggregate mixtures was also performed to sort particles with high biomass and cell viability to improve cell quality. Overall, the scalable microfluidic platform technology enables in-line sample processing from bioreactors directly and automated analysis (up to 200 particles/sec) of cell quality attributes and on-demand sorting (up to 10 particles/sec) to maximize cell yield and improve the control of cell quality in continuous cell-based manufacturing.
author2 Hou Han Wei
author_facet Hou Han Wei
Gong, Lingyan
format Thesis-Doctor of Philosophy
author Gong, Lingyan
author_sort Gong, Lingyan
title Impedance-based microfluidic cytometry for label-free monitoring and on-demand microcarrier sorting
title_short Impedance-based microfluidic cytometry for label-free monitoring and on-demand microcarrier sorting
title_full Impedance-based microfluidic cytometry for label-free monitoring and on-demand microcarrier sorting
title_fullStr Impedance-based microfluidic cytometry for label-free monitoring and on-demand microcarrier sorting
title_full_unstemmed Impedance-based microfluidic cytometry for label-free monitoring and on-demand microcarrier sorting
title_sort impedance-based microfluidic cytometry for label-free monitoring and on-demand microcarrier sorting
publisher Nanyang Technological University
publishDate 2024
url https://hdl.handle.net/10356/174073
_version_ 1814047014167511040

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