Bridging barriers: advances and challenges in modeling biological barriers and measuring barrier integrity in organ-on-chip systems
Biological barriers such as the blood-brain barrier, skin, and intestinal mucosal barrier play key roles in homeostasis, disease physiology, and drug delivery - as such, it is important to create representative in vitro models to improve understanding of barrier biology and serve as tools for therap...
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| Veröffentlicht in: | Lab on a chip 2024-06, Vol.24 (13), p.3199-3225 |
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| creator | Ugodnikov, Alisa Persson, Henrik Simmons, Craig A |
| description | Biological barriers such as the blood-brain barrier, skin, and intestinal mucosal barrier play key roles in homeostasis, disease physiology, and drug delivery - as such, it is important to create representative
in vitro
models to improve understanding of barrier biology and serve as tools for therapeutic development. Microfluidic cell culture and organ-on-a-chip (OOC) systems enable barrier modelling with greater physiological fidelity than conventional platforms by mimicking key environmental aspects such as fluid shear, accurate microscale dimensions, mechanical cues, extracellular matrix, and geometrically defined co-culture. As the prevalence of barrier-on-chip models increases, so does the importance of tools that can accurately assess barrier integrity and function without disturbing the carefully engineered microenvironment. In this review, we first provide a background on biological barriers and the physiological features that are emulated through
in vitro
barrier models. Then, we outline molecular permeability and electrical sensing barrier integrity assessment methods, and the related challenges specific to barrier-on-chip implementation. Finally, we discuss future directions in the field, as well important priorities to consider such as fabrication costs, standardization, and bridging gaps between disciplines and stakeholders.
Biological barriers play key roles in homeostasis, disease physiology and drug delivery, highlighting a need for representative
in vitro
tools. We discuss advances and challenges in modeling and measuring barrier integrity in organ-on-chip systems. |
| doi_str_mv | 10.1039/d3lc01027a |
| format | Article |
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in vitro
models to improve understanding of barrier biology and serve as tools for therapeutic development. Microfluidic cell culture and organ-on-a-chip (OOC) systems enable barrier modelling with greater physiological fidelity than conventional platforms by mimicking key environmental aspects such as fluid shear, accurate microscale dimensions, mechanical cues, extracellular matrix, and geometrically defined co-culture. As the prevalence of barrier-on-chip models increases, so does the importance of tools that can accurately assess barrier integrity and function without disturbing the carefully engineered microenvironment. In this review, we first provide a background on biological barriers and the physiological features that are emulated through
in vitro
barrier models. Then, we outline molecular permeability and electrical sensing barrier integrity assessment methods, and the related challenges specific to barrier-on-chip implementation. Finally, we discuss future directions in the field, as well important priorities to consider such as fabrication costs, standardization, and bridging gaps between disciplines and stakeholders.
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in vitro
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in vitro
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in vitro
barrier models. Then, we outline molecular permeability and electrical sensing barrier integrity assessment methods, and the related challenges specific to barrier-on-chip implementation. Finally, we discuss future directions in the field, as well important priorities to consider such as fabrication costs, standardization, and bridging gaps between disciplines and stakeholders.
Biological barriers play key roles in homeostasis, disease physiology and drug delivery, highlighting a need for representative
in vitro
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in vitro
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in vitro
barrier models. Then, we outline molecular permeability and electrical sensing barrier integrity assessment methods, and the related challenges specific to barrier-on-chip implementation. Finally, we discuss future directions in the field, as well important priorities to consider such as fabrication costs, standardization, and bridging gaps between disciplines and stakeholders.
Biological barriers play key roles in homeostasis, disease physiology and drug delivery, highlighting a need for representative
in vitro
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| ispartof | Lab on a chip, 2024-06, Vol.24 (13), p.3199-3225 |
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| source | MEDLINE; Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection |
| subjects | Animals Blood-brain barrier Blood-Brain Barrier - metabolism Homeostasis Humans Integrity Intestinal Mucosa - metabolism Lab-On-A-Chip Devices Microfluidic Analytical Techniques - instrumentation Microfluidic devices Models, Biological Permeability Physiology Production costs |
| title | Bridging barriers: advances and challenges in modeling biological barriers and measuring barrier integrity in organ-on-chip systems |
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