Development and characterization of a microfluidic model of the tumour microenvironment

The physical microenvironment of tumours is characterized by heterotypic cell interactions and physiological gradients of nutrients, waste products and oxygen. This tumour microenvironment has a major impact on the biology of cancer cells and their response to chemotherapeutic agents. Despite this,...

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Bibliographic Details
Published in:Scientific reports 2016-10, Vol.6 (1), p.36086, Article 36086
Main Authors: Ayuso, Jose M., Virumbrales-Muñoz, María, Lacueva, Alodia, Lanuza, Pilar M., Checa-Chavarria, Elisa, Botella, Pablo, Fernández, Eduardo, Doblare, Manuel, Allison, Simon J., Phillips, Roger M., Pardo, Julián, Fernandez, Luis J., Ochoa, Ignacio
Format: Article
Language:English
Subjects:
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Apoptosis
Cancer
Cell interactions
Cell proliferation
Chemotherapy
Data processing
Drug screening
Glucose
Humanities and Social Sciences
Microfluidics
multidisciplinary
Nutrients
Oxygen
Physiology
Science
Spheroids
Tumor microenvironment
Tumors
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Summary:The physical microenvironment of tumours is characterized by heterotypic cell interactions and physiological gradients of nutrients, waste products and oxygen. This tumour microenvironment has a major impact on the biology of cancer cells and their response to chemotherapeutic agents. Despite this, most in vitro cancer research still relies primarily on cells grown in 2D and in isolation in nutrient- and oxygen-rich conditions. Here, a microfluidic device is presented that is easy to use and enables modelling and study of the tumour microenvironment in real-time. The versatility of this microfluidic platform allows for different aspects of the microenvironment to be monitored and dissected. This is exemplified here by real-time profiling of oxygen and glucose concentrations inside the device as well as effects on cell proliferation and growth, ROS generation and apoptosis. Heterotypic cell interactions were also studied. The device provides a live ‘window’ into the microenvironment and could be used to study cancer cells for which it is difficult to generate tumour spheroids. Another major application of the device is the study of effects of the microenvironment on cellular drug responses. Some data is presented for this indicating the device’s potential to enable more physiological in vitro drug screening.
ISSN:2045-2322
2045-2322
DOI:10.1038/srep36086