Engineering cancer microenvironments for in vitro 3-D tumor models

Asghar, Waseem; Assal, Rami El; Shafiee, Hadi; Pitteri, Sharon J.; Paulmurugan, Ramasamy; Demirci, Utkan

doi:10.1016/j.mattod.2015.05.002

Cited by 263 publications

(222 citation statements)

References 186 publications

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“…Moreover, a Matrigel with lung cancer cell mixture injected into an animal model resulted in rapid formation of tumour MCSs in animals compared with cell injections without Matrigel. The similar results were also obtained from cancer cells of A253 and B16F10 [76]. However, three-dimensional tumour models grown on the Matrigel exhibited less similarity to the in vivo tumours compared with three-dimensional poly (lactide-co-glycolide) (PLG) engineered tumours because of a decreased level of IL-8 expression in the Matrigel [49].…”

Section: Natural Polymerssupporting

confidence: 75%

“…Human colon Matrigel -rich in growth factors, signal factors for cell proliferation -expensive and animal derived PC-3M, PrCa, NCI-H600 [74], HepG2 [75], A235, B16F10 [76] agar -damage on cells by forces from gel formation inside the agar -excellent mechanical properties human foreskin dermal fibroblasts [77], cortical cell [78] alginate -rapid formation of hydrogel scaffolds -strong chemicals required to break hydrogel networks to harvest MCSs human fat-derived stromal vascular fraction cells [79], human colon cancer cells (HCT116) [80] fibrin -promoting cell attachment -high cell viability human mesenchymal stem cell [81], B16-F1…”

Section: Micro-mouldingmentioning

confidence: 99%

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Advances in multicellular spheroids formation

Cui¹,

Hartanto²,

Zhang³

2017

J. R. Soc. Interface.

379

336

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Three-dimensional multicellular spheroids (MCSs) have a complex architectural structure, dynamic cell -cell/cell -matrix interactions and bio-mimicking in vivo microenvironment. As a fundamental building block for tissue reconstruction, MCSs have emerged as a powerful tool to narrow down the gap between the in vitro and in vivo model. In this review paper, we discussed the structure and biology of MCSs and detailed fabricating methods. Among these methods, the approach in microfluidics with hydrogel support for MCS formation is promising because it allows essential cell -cell/cell -matrix interactions in a confined space.

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Section: Natural Polymerssupporting

confidence: 75%

Section: Micro-mouldingmentioning

confidence: 99%

Advances in multicellular spheroids formation

Cui¹,

Hartanto²,

Zhang³

2017

J. R. Soc. Interface.

379

336

View full text Add to dashboard Cite

show abstract

“…For example, murine models are complex, expensive and time-consuming and 2D in vitro tumour models, although simpler and faster, fail to mimic the native 3D tissue structure or the surrounding tumour microenvironment. To overcome some of these limitations, 3D in vitro models are being developed that offer the capability to investigate the role of the TME in a more physiologically realistic 3D condition compared with standard 2D in vitro assays [30]. TME architecture presents structural, mechanical and chemical cues that affect the expression of essential molecules such as integrins and matrix metalloproteinases that activate signalling pathways to regulate cell adhesion, EMT, migration and differentiation; and, although a degree of simplification is probably needed, it can be argued that standard 2D systems missing the features of 3D tissue organisation that play an essential part in cell growth, function, differentiation and interaction lack sufficient physiological relevance.…”

Section: Tumour Models For T Cell Immunotherapymentioning

confidence: 99%

Microfluidic models for adoptive cell-mediated cancer immunotherapies

Adriani

Pavesi

Tan

et al. 2016

Drug Discovery Today

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Current adoptive T cell therapies have shown promising results in clinical trials but need further development as an effective cancer treatment. Here, we discuss how 3D microfluidic tumour models mimicking the tumour microenvironment could help in testing T cell immunotherapies by assessing engineered T cells and identifying combinatorial therapy to improve therapeutic efficacy. We propose that 3D microfluidic systems can be used to screen different patient-specific treatments, thereby reducing the burden of in vivo testing and facilitating the rapid translation of successful T cell cancer immunotherapies to the clinic.

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“…Recently, strategies for the on-demand capture, proliferation, and release of cells in biomimetic three-dimensional (3D) environments have received increasing attention in fields such as cell biology, drug discovery and tissue engineering [1][2][3][4][5][6][7][8]. In particular, microcarriers have emerged as an optimized strategy based on novel 3D biomaterial scaffold platforms, which have advantages in terms of space saving, cost effectiveness, and lower time and labor requirements for cell culture [8][9][10].…”

Section: Introductionmentioning

confidence: 99%

“…In particular, microcarriers have emerged as an optimized strategy based on novel 3D biomaterial scaffold platforms, which have advantages in terms of space saving, cost effectiveness, and lower time and labor requirements for cell culture [8][9][10]. Several approaches have been employed for engineering cell microcarriers, including micromolding, electrojetting, photolithography and microfluidics [10][11][12][13][14].…”

Section: Introductionmentioning

confidence: 99%