A novel 3D mammalian cell perfusion-culture system in microfluidic channels

Toh, Yi‐Chin; Zhang, Chi; Zhang, Jing; Khong, Yuet Mei; Shi, Chao; Samper, Victor; Noort, Danny van; Hutmacher, Dietmar W.; Yu, Hanry

doi:10.1039/b614872g

Cited by 388 publications

(355 citation statements)

References 52 publications

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“…2d). 62 About 4 6 10 3 cells per channel were applied, which corresponds to approximately 0.05 liver lobule. Cells were perfusion-seeded into these structures, achieving a high 3D cell-cell interaction.…”

Section: Relevance Of Cell Sourcesmentioning

confidence: 99%

Chip-based liver equivalents for toxicity testing – organotypicalness versus cost-efficient high throughput

2013

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Drug-induced liver toxicity dominates the reasons for pharmaceutical product ban, withdrawal or nonapproval since the thalidomide disaster in the late-1950s. Hopes to finally solve the liver toxicity test dilemma have recently risen to a historic level based on the latest progress in human microfluidic tissue culture devices. Chip-based human liver equivalents are envisaged to identify liver toxic agents regularly undiscovered by current test procedures at industrial throughput. In this review, we focus on advanced microfluidic microscale liver equivalents, appraising them against the level of architectural and, consequently, functional identity with their human counterpart in vivo. We emphasise the inherent relationship between human liver architecture and its drug-induced injury. Furthermore, we plot the current socio-economic drug development environment against the possible value such systems may add.Finally, we try to sketch a forecast for translational innovations in the field.

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Section: Relevance Of Cell Sourcesmentioning

confidence: 99%

Chip-based liver equivalents for toxicity testing – organotypicalness versus cost-efficient high throughput

2013

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“…The use of HEK in toxicity assays (Chou et al 2002;Didier et al 1999;Monteiro-Riviere et al 2005;Rouse et al 2006;Shvedova et al 2003) makes this cell type an attractive candidate for use in microfluidic high throughput toxicity assays. Cell culture in microfluidic systems has been demonstrated by others Delamarche et al 2005;Figallo et al 2007;Flaim et al 2005;Folch and Toner 2000;Gu et al 2004;Hui and Bhatia 2007;Hung et al 2005a, Hung et al b;Kane et al 2006;Khademhosseini et al 2004;Kim et al 2006;Leclerc et al 2006a;b;Lee et al 2006;Prokop et al 2004;Raty et al 2004;Rhee et al 2005;Sin et al 2004;Song et al 2005;Toh et al 2007;Tourovskaia et al 2005;Walker et al 2002) but keratinocytes have not yet been studied at the microscale.…”

Section: Introductionmentioning

confidence: 99%

Characterization of microfluidic human epidermal keratinocyte culture

2008

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Human epidermal keratinocytes (HEK) are skin cells of primary importance in maintaining the body's defensive barrier and are used in vitro to assess the irritation potential and toxicity of chemical compounds. Microfluidic systems hold promise for high throughput irritant and toxicity assays, but HEK growth kinetics have yet to be characterized within microscale culture chambers. This research demonstrates HEK patterning on microscale patches of Type I collagen within microfluidic channels and maintenance of these cells under constant medium perfusion for 72 h. HEK were shown to maintain 93.0%-99.6% viability at 72 h under medium perfusion ranging from 0.025-0.4 ll min -1 . HEK maintained this viability while *100% confluent-a level not possible in 96 well plates. Microscale HEK cultures offer the ability to precisely examine the morphology, behavior and viability of individual cells which may open the door to new discoveries in toxicological screening methods and wound healing techniques.

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“…We have combined the front-and side-trapping mechanisms into a microfluidic channel with dimensions of 10 4 m ͑length͒ ϫ 600 m ͑width͒ ϫ 100 m ͑height͒, in arrays of micropillars ͑dimensions 30 ϫ 50 m and a 20 m gap size͒ located in the center of the microfluidic channel to filter and trap the cells using a withdrawal flow. 31,[42][43][44][45] These trapped cells maintain good viability, 3D morphology, sufficient cell-cell and cell-matrix interactions, as well as high levels of albumin secretion and UDP-glucuronyltransferase ͑UGT͒ activity for in vitro toxicology applications.…”

Section: Hydrodynamic Trappingmentioning

confidence: 99%

“…Cells are typically trapped together as cell clusters to maintain 3D cell morphology and enhanced cellular and tissue functions. 31 Here we will review various cell trapping methods in microfluidic systems and analyze their strength and limitations.…”

Section: Introductionmentioning

confidence: 99%

Exploitation of physical and chemical constraints for three-dimensional microtissue construction in microfluidics

Choudhury

Iliescu

et al. 2011

Biomicrofluidics

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There are a plethora of approaches to construct microtissues as building blocks for the repair and regeneration of larger and complex tissues. Here we focus on various physical and chemical trapping methods for engineering three-dimensional microtissue constructs in microfluidic systems that recapitulate the in vivo tissue microstructures and functions. Advances in these in vitro tissue models have enabled various applications, including drug screening, disease or injury models, and cellbased biosensors. The future would see strides toward the mesoscale control of even finer tissue microstructures and the scaling of various designs for high throughput applications. These tools and knowledge will establish the foundation for precision engineering of complex tissues of the internal organs for biomedical applications.

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A novel 3D mammalian cell perfusion-culture system in microfluidic channels

Cited by 388 publications

References 52 publications

Chip-based liver equivalents for toxicity testing – organotypicalness versus cost-efficient high throughput

Chip-based liver equivalents for toxicity testing – organotypicalness versus cost-efficient high throughput

Characterization of microfluidic human epidermal keratinocyte culture

Exploitation of physical and chemical constraints for three-dimensional microtissue construction in microfluidics

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