Cited 24 time in webofscience Cited 27 time in scopus

Mass fabrication of uniform sized 3D tumor spheroid using high-throughput microfluidic system

Title
Mass fabrication of uniform sized 3D tumor spheroid using high-throughput microfluidic system
Authors
Kwak, B.Lee, Y.Lee, J.Lee, Sung WonLim, J.
DGIST Authors
Lee, Sung Won
Issue Date
2018-04
Citation
Journal of Controlled Release, 275, 201-207
Type
Article
Article Type
Article
Keywords
CellsControlled drug deliveryDiseasesDropsDrug deliveryDrug productsDrug therapyEfficiencyFluidic devicesMicrofluidicsMonolayersThroughputAccurate predictionComplex characteristicsDoxorubicinDroplet-based microfluidicsHigh throughputMass fabricationMicro fluidic systemTumor spheroidTumors
ISSN
0168-3659
Abstract
In vivo tumors develop in a three-dimensional manner and have unique and complex characteristics. Physico-biochemical barriers on tumors cause drug resistance and limit drug delivery efficiency. Currently, 2D cancer cell monolayer platforms are frequently used to test the efficiency of new drug materials. However, the monolayer platform generally overestimates drug efficiency because of the absence of physico-biochemical barriers. Many literatures indicated that a 3D tumor spheroid model has very similar characteristics to in vivo tumor models, and studies demonstrated the accurate prediction of drug efficiency using this model. The use of a 3D tumor spheroid model in drug development process remains challenging because of the low generation yield and difficulties in size control. In this study, we developed a droplet-based microfluidic system that can generate cancer cells encapsulated by micro-droplets with very high generation yield (16–20 Hz, 1000 droplets/min). The system can control the number of encapsulated cancer cells in the droplet or diameter of the 3D spheroid model precisely between 50 and 150 μm. Moreover, the formed 3D tumor spheroid model can be cultured for >2 weeks by an additional step of droplet disruption and recollection, and can grow up to 245 μm in diameter. © 2018 Elsevier B.V.
URI
http://hdl.handle.net/20.500.11750/6089
DOI
10.1016/j.jconrel.2018.02.029
Publisher
Elsevier B.V.
Related Researcher
  • Author Lee, Sungwon Bio-Harmonized Device Lab
  • Research Interests Ultrathin Device Fabrication; Bio sensors Development; Functional Material Development
Files:
There are no files associated with this item.
Collection:
Department of Emerging Materials ScienceBio-Harmonized Device Lab1. Journal Articles


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