Human leucocytes processed by fast-rate inertial microfluidics retain conventional functional characteristics

Carvell, Tom; Burgoyne, Paul; Milne, Laura; Campbell, John D. M.; Fraser, Alasdair R.; Bridle, Helen

doi:10.1098/rsif.2023.0572

J. R. Soc. Interface.

2024

DOI: 10.1098/rsif.2023.0572

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Human leucocytes processed by fast-rate inertial microfluidics retain conventional functional characteristics

Tom Carvell,

Paul Burgoyne,

Laura Milne

et al.

Abstract: The manufacturing of clinical cellular therapies is a complex process frequently requiring manipulation of cells, exchange of buffers and volume reduction. Current manufacturing processes rely on either low throughput open centrifugation-based devices, or expensive closed-process alternatives. Inertial focusing (IF) microfluidic devices offer the potential for high-throughput, inexpensive equipment which can be integrated into a closed system, but to date no IF devices have been approved for use in cell therap… Show more

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Cited by 3 publications

References 76 publications

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Microfluidic technologies: buffer exchange in bioprocessing, a mini review

Carvell,

Burgoyne,

Fraser

et al. 2024

Microfluid Nanofluid

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Buffer exchange is a common process in manufacturing protocols for a wide range of bioprocessing applications, with a variety of technologies available to manipulate biological materials for culture medium exchange, cell washing and buffer removal. Microfluidics is an emerging field for buffer exchange and has shown promising results with both prototype research and commercialised devices which are inexpensive, highly customisable and often have the capacity for scalability to substantially increase throughput. Microfluidic devices are capable of processing biological materials and exchanging solutions without the need for conventional processing techniques like centrifugation, which are time-consuming, unsuitable for large volumes and may be damaging to cells. The use of microfluidic separation devices for cell therapy manufacturing has been under-explored despite some device designs successfully being used for diagnostic enrichment of rare circulating tumour cells from peripheral blood. This mini-review aims to review the current state of microfluidic devices for buffer exchange, provide an insight into the advantages microfluidics offers for buffer exchange and identify future developments key to exploiting the technology for this application.

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Microfluidic technologies: buffer exchange in bioprocessing, a mini review

Carvell,

Burgoyne,

Fraser

et al. 2024

Microfluid Nanofluid

View full text Add to dashboard Cite

show abstract

Human leucocytes processed by fast-rate inertial microfluidics retain conventional functional characteristics

Carvell,

Burgoyne,

Milne

et al. 2024

J. R. Soc. Interface.

View full text Add to dashboard Cite

The manufacturing of clinical cellular therapies is a complex process frequently requiring manipulation of cells, exchange of buffers and volume reduction. Current manufacturing processes rely on either low throughput open centrifugation-based devices, or expensive closed-process alternatives. Inertial focusing (IF) microfluidic devices offer the potential for high-throughput, inexpensive equipment which can be integrated into a closed system, but to date no IF devices have been approved for use in cell therapy manufacturing, and there is limited evidence for the effects that IF processing has on human cells. The IF device described in this study was designed to simultaneously separate leucocytes, perform buffer exchange and provide a volume reduction to the cell suspension, using high flow rates with high Reynolds numbers. The performance and effects of the IF device were characterized using peripheral blood mononuclear cells and isolated monocytes. Post-processing cell effects were investigated using multi-parameter flow cytometry to track cell viability, functional changes and fate. The IF device was highly efficient at separating CD14+ monocytes (approx. 97% to one outlet, approx. 60% buffer exchange, 15 ml min −1 ) and leucocyte processing was well tolerated with no significant differences in downstream viability, immunophenotype or metabolic activity when compared with leucocytes processed with conventional processing techniques. This detailed approach provides robust evidence that IF devices could offer significant benefits to clinical cell therapy manufacture.

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Categorising hybrid material microfluidic devices

Carvell,

Burgoyne,

Fraser

et al. 2024

Front. Lab. Chip. Technol.

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Microfluidic devices are useful tools for a wide range of biomedical, industrial, and environmental applications. Hybrid microfluidic devices utilising more than two materials are increasingly being used for their capacity to produce unique structures and perform novel functions. However, an analysis of publications across the field shows that whilst hybrid microfluidic devices have been reported, there remains no system of classifying hybrid devices which could help future researchers in optimising material selection. To resolve this issue, we propose a system of classifying hybrid microfluidic devices primarily as containing either hybrid structural, chemical, or electrical components. This is expanded upon and developed into a hierarchy, with combinations of different primary components categorised into secondary or tertiary hybrid device groupings. This classification approach is useful as it describes materials that can be combined to create novel hybrid microfluidic devices.

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Human leucocytes processed by fast-rate inertial microfluidics retain conventional functional characteristics

Cited by 3 publications

References 76 publications

Microfluidic technologies: buffer exchange in bioprocessing, a mini review

Microfluidic technologies: buffer exchange in bioprocessing, a mini review

Human leucocytes processed by fast-rate inertial microfluidics retain conventional functional characteristics

Categorising hybrid material microfluidic devices

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