3D bioprinted glioma stem cells for brain tumor model and applications of drug susceptibility

Dai, Xingliang; Ma, Cheng; Lan, Qing; Xu, Tao

doi:10.1088/1758-5090/8/4/045005

Cited by 240 publications

(183 citation statements)

References 53 publications

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“…Encapsulated NSCs had an initial cell viability of ~75% and were able to differentiate into neurons and glial cells. Similar results were found with a bioink of sodium alginate, fibrinogen, and gelatin (Dai et al, 2016). The bioink was soaked in calcium chloride and thrombin solutions after printing to crosslink the sodium alginate and fibrinogen components, respectively.…”

Section: Strategies For Biomaterials Printingsupporting

confidence: 73%

Microscale Architecture in Biomaterial Scaffolds for Spatial Control of Neural Cell Behavior

Meco

Lampe

2018

Front. Mater.

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Biomaterial scaffolds mimic aspects of the native central nervous system (CNS) extracellular matrix (ECM) and have been extensively utilized to influence neural cell (NC) behavior in in vitro and in vivo settings. These biomimetic scaffolds support NC cultures, can direct the differentiation of NCs, and have recapitulated some native NC behavior in an in vitro setting. However, NC transplant therapies and treatments used in animal models of CNS disease and injury have not fully restored functionality. The observed lack of functional recovery occurs despite improvements in transplanted NC viability when incorporating biomaterial scaffolds and the potential of NC to replace damaged native cells. The behavior of NCs within biomaterial scaffolds must be directed in order to improve the efficacy of transplant therapies and treatments. Biomaterial scaffold topography and imbedded bioactive cues, designed at the microscale level, can alter NC phenotype, direct migration, and differentiation. Microscale patterning in biomaterial scaffolds for spatial control of NC behavior has enhanced the capabilities of in vitro models to capture properties of the native CNS tissue ECM. Patterning techniques such as lithography, electrospinning and three-dimensional (3D) bioprinting can be employed to design the microscale architecture of biomaterial scaffolds. Here, the progress and challenges of the prevalent biomaterial patterning techniques of lithography, electrospinning, and 3D bioprinting are reported. This review analyzes NC behavioral response to specific microscale topographical patterns and spatially organized bioactive cues.

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Section: Strategies For Biomaterials Printingsupporting

confidence: 73%

Microscale Architecture in Biomaterial Scaffolds for Spatial Control of Neural Cell Behavior

Meco

Lampe

2018

Front. Mater.

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“…bioprinted Hela cells with gelatin/alginate/fibrinogen hydrogel and found that MMP-2 and MMP-9 expression of tumor cells in hydrogel were higher than those of the 2D control 16 . Previously, we have bioprinted a brain tumor model by extruding glioma stem cells-laden hydrogel 17 . But it is known that solid tumor contains not only tumor cells but also a variety of stromal cells, which are the important sources of extracellular matrix and cytokines.…”

Section: Introductionmentioning

confidence: 99%

Coaxial 3D bioprinting of self-assembled multicellular heterogeneous tumor fibers

Dai

Liu

Ouyang

et al. 2017

Sci Rep

Self Cite

107

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Three-dimensional (3D) bioprinting of living structures with cell-laden biomaterials has been achieved in vitro, however, some cell-cell interactions are limited by the existing hydrogel. To better mimic tumor microenvironment, self-assembled multicellular heterogeneous brain tumor fibers have been fabricated by a custom-made coaxial extrusion 3D bioprinting system, with high viability, proliferative activity and efficient tumor-stromal interactions. Therein, in order to further verify the sufficient interactions between tumor cells and stroma MSCs, CRE-LOXP switch gene system which contained GSCs transfected with “LOXP-STOP-LOXP-RFP” genes and MSCs transfected with “CRE recombinase” gene was used. Results showed that tumor-stroma cells interacted with each other and fused, the transcription of RFP was higher than that of 2D culture model and control group with cells mixed directly into alginate, respectively. RFP expression was observed only in the cell fibers but not in the control group under confocal microscope. In conclusion, coaxial 3D bioprinted multicellular self-assembled heterogeneous tumor tissue-like fibers provided preferable 3D models for studying tumor microenvironment in vitro, especially for tumor-stromal interactions.

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“…High-throughput pharmacological study [36,78] 3D bioprinting Primary feline H1 cardiomyocytes First rhythmic beating of 3D printed structure [93][94][95] Lung Microfabrication Epithelial cells Use of porous membrane to mimic lung functions [31,37] 3D bioprinting A549 cells and EA hy926 cells World's first 3D bioprinted lung tissue [101] Bone 3D bioprinting BMSCs High viability in microextrusion-based bioprinting [108,109,158,159] Cancer Self-assembled Intestinal stem cells Discovery of LGR5+ intestinal stem cells [52,62] Microfabrication Breast cancer cells Perfusable human microvascularized bone-mimicking (BMi) microenvironment [81,168] 3D bioprinting OVCAR-5 and MRC-5 cells Insight into complex cell-cell communication in 3D [113][114][115][116][117] Multi Self-assembled Liver, gut, vessel cells High throughput hanging drop [30,[49][50][51][52] Microfabrication Liver, heart, and vessel cells Automated control of perfusion [11,19,27,32] 3D bioprinting NPC and HCT-116 cells Multiorgan bioprinted model [30,122] a)…”

Section: Engineering Technologiesmentioning

confidence: 99%

“…[116] In summary, 3D bioprinted glioma model provides a novel alternative tool for studying glioma genesis, glioma stem cell biology, drug resistance, and glioma anticancer drug susceptibility in vitro. [115] Other groups have generated different cancer 3D in vitro models including models for bone and breast cancers using 3D bioprinting. [116,117] …”

Section: Bioprinted Cancer Modelsmentioning

confidence: 99%

3D Miniaturization of Human Organs for Drug Discovery

Park

Wetzel

Dréau

et al. 2017

Adv Healthcare Materials

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“Engineered human organs” hold promises for predicting the effectiveness and accuracy of drug responses while reducing cost, time, and failure rates in clinical trials. Multiorgan human models utilize many aspects of currently available technologies including self‐organized spherical 3D human organoids, microfabricated 3D human organ chips, and 3D bioprinted human organ constructs to mimic key structural and functional properties of human organs. They enable precise control of multicellular activities, extracellular matrix (ECM) compositions, spatial distributions of cells, architectural organizations of ECM, and environmental cues. Thus, engineered human organs can provide the microstructures and biological functions of target organs and advantageously substitute multiscaled drug‐testing platforms including the current in vitro molecular assays, cell platforms, and in vivo models. This review provides an overview of advanced innovative designs based on the three main technologies used for organ construction leading to single and multiorgan systems useable for drug development. Current technological challenges and future perspectives are also discussed.

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3D bioprinted glioma stem cells for brain tumor model and applications of drug susceptibility

Cited by 240 publications

References 53 publications

Microscale Architecture in Biomaterial Scaffolds for Spatial Control of Neural Cell Behavior

Microscale Architecture in Biomaterial Scaffolds for Spatial Control of Neural Cell Behavior

Coaxial 3D bioprinting of self-assembled multicellular heterogeneous tumor fibers

3D Miniaturization of Human Organs for Drug Discovery

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