2021
DOI: 10.1080/10408444.2021.1953439
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Applicability of organ-on-chip systems in toxicology and pharmacology

Abstract: Organ-on-chip (OoC) systems are microfabricated cell culture devices designed to model functional units of human organs by harboring an in vitro generated organ surrogate. In the present study, we reviewed issues and opportunities related to the application of OoC in the safety and efficacy assessment of chemicals and pharmaceuticals, as well as the steps needed to achieve this goal. The relative complexity of OoC over simple in vitro assays provides advantages and disadvantages in the context of compound test… Show more

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Cited by 19 publications
(6 citation statements)
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“…Organ-on-chip models integrate mechanical (such as shear or strain stress) and chemical (growth factors, cytokines) cues and include tailored sensing of the culture environment regarding aspects as medium flow rate, temperature, pH, partial pressure of gases, and mechanical forces, among many others [ 7 9 ]. Organ-on-chip are a particularly promising strategy for assessing the safety and efficacy of chemicals and pharmaceuticals [ 10 ]; the devices can harbor simple (cell lines) or complex (organoids) biological structures [ 11 ], and can be designed to allow communication between cell types of different organs, in what has been called multiorgan chips. Another recent advance is bioprinting, in which 3D printing-like techniques are used to combine cells, growth factors, and/or biomaterials to create 3D cell aggregates resembling tissues or organs [ 12 , 13 ].…”
Section: The Dimensions Of Biomedical Research Toolsmentioning
confidence: 99%
“…Organ-on-chip models integrate mechanical (such as shear or strain stress) and chemical (growth factors, cytokines) cues and include tailored sensing of the culture environment regarding aspects as medium flow rate, temperature, pH, partial pressure of gases, and mechanical forces, among many others [ 7 9 ]. Organ-on-chip are a particularly promising strategy for assessing the safety and efficacy of chemicals and pharmaceuticals [ 10 ]; the devices can harbor simple (cell lines) or complex (organoids) biological structures [ 11 ], and can be designed to allow communication between cell types of different organs, in what has been called multiorgan chips. Another recent advance is bioprinting, in which 3D printing-like techniques are used to combine cells, growth factors, and/or biomaterials to create 3D cell aggregates resembling tissues or organs [ 12 , 13 ].…”
Section: The Dimensions Of Biomedical Research Toolsmentioning
confidence: 99%
“…The organ-on-a-chip technology uses microfabricated cell culture devices that combine biomaterial technologies, microfluidic systems, and tissue engineering and can simulate the crosstalk between different tissues and organs. [89] Despite its current limitations, [90] the organ-on-chip technology has been employed to study several aging-related diseases, such as rheumatoid arthritis, [91] hypertensive nephropathy, [92] diabetes, [71] and neuromuscular diseases [93] (Fig. 3C).…”
Section: Applications Of Organoids In Aging Researchmentioning
confidence: 99%
“…The final step of the OoC development process is the functional validation: Only through a comprehensive characterization of the model’s capability to recreate in vivo functions and mechanisms as well as of its limitations, it is possible to build confidence in its predictivity and the translatability of results. ,, This functional validation can encompass different types of case studies depending on its specific intended use, for example, (i) the assessment of its response to sets of training and validation compounds, (ii) the recapitulation of known physiological mechanisms and responses to defined stimuli, or (iii) the recreation of defined pathogenesis processes and pathophysiological responses. In addition to the validation of the function, it is crucial to also define the window of functional stability, i.e., the time frame during which studies can be conducted.…”
Section: Functional Validationmentioning
confidence: 99%