Three dimensional in vitro models of cancer: Bioprinting multilineage glioblastoma models

Hermida, Miguel A.; Kumar, J. Dinesh; Schwarz, Daniela; Laverty, Keith G.; Bartolo, Alberto Di; Ardron, Marcus; Bogomolnijs, Mihails; Clavreul, Anne; Brennan, Paul M.; Wiegand, Ulrich K.; Melchels, Ferry P.W.; Shu, Wenmiao; Leslie, Nicholas

doi:10.1016/j.jbior.2019.100658

Cited by 72 publications

(75 citation statements)

References 67 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This was replicated by stimulating angiogenesis through cultured GSCs secreted factors present in the cell medium [ 32 , 35 ]. A recent study managed to recapitulate the heterogeneous glioblastoma tumor microenvironment in bioprinted constructs using an array of cancer and stromal cells including MM6 monocyte/macrophages, U87MG glioblastoma cells, glioblastoma stem cells, microglia and glioma associated stromal cells (GASCs) providing a more realistic chemotherapeutic response [151] ( Fig. 4 -C).…”

Section: Cancer-specific Bioprinted Models For Precision Chemotherapymentioning

confidence: 99%

3D Bioprinted cancer models: Revolutionizing personalized cancer therapy

Augustine

Kalva

Ahmad

et al. 2021

Translational Oncology

111

View full text Add to dashboard Cite

Highlights This review describes how 3D bioprinting can be used for developing patient specific cancer models. Bioprinted cancer models containing patient-derived cancer and stromal cells is promising for personalized cancer therapy screening 3D bioprinted constructs form physiologically relevant cell–cell and cell–matrix interactions. Bioprinted cancer models mimic the 3D heterogeneity of real tumors.

show abstract

Section: Cancer-specific Bioprinted Models For Precision Chemotherapymentioning

confidence: 99%

3D Bioprinted cancer models: Revolutionizing personalized cancer therapy

Augustine

Kalva

Ahmad

et al. 2021

Translational Oncology

111

View full text Add to dashboard Cite

show abstract

“…Another multinozzle extrusion‐based bioprinting method was used to produce a 3D model with GBM cell lines or GSCs, patient‐derived GBM‐associated stromal cells (GASCs), and microglia in an alginate‐based hydrogel. [ 188 ] The alginate was functionalized with RGDs, and in some groups with HA and collagen. The 3D multicellular models showed moderately enhanced resistance to TMZ and enhanced resistance to cisplatin, a compound that failed many clinical trials but showed promising results in 2D cultures, indicating potential application of this system for more reliable preclinical drug efficacy evaluations.…”

Section: D Bioprinting For Gbm and Bbbmentioning

confidence: 99%

Biomaterials and 3D Bioprinting Strategies to Model Glioblastoma and the Blood–Brain Barrier

2020

View full text Add to dashboard Cite

Glioblastoma (GBM) is the most prevalent and lethal adult primary central nervous system cancer. An immunosuppresive and highly heterogeneous tumor microenvironment, restricted delivery of chemotherapy or immunotherapy through the blood–brain barrier (BBB), together with the brain's unique biochemical and anatomical features result in its universal recurrence and poor prognosis. As conventional models fail to predict therapeutic efficacy in GBM, in vitro 3D models of GBM and BBB leveraging patient‐ or healthy‐individual‐derived cells and biomaterials through 3D bioprinting technologies potentially mimic essential physiological and pathological features of GBM and BBB. 3D‐bioprinted constructs enable investigation of cellular and cell–extracellular matrix interactions in a species‐matched, high‐throughput, and reproducible manner, serving as screening or drug delivery platforms. Here, an overview of current 3D‐bioprinted GBM and BBB models is provided, elaborating on the microenvironmental compositions of GBM and BBB, relevant biomaterials to mimic the native tissues, and bioprinting strategies to implement the model fabrication. Collectively, 3D‐bioprinted GBM and BBB models are promising systems and biomimetic alternatives to traditional models for more reliable mechanistic studies and preclinical drug screenings that may eventually accelerate the drug development process for GBM.

show abstract

“…Recently, bioprinted alginate–collagen–hylauronic acid matrix comprising of glioblastoma cancer cells was fabricated to control the spatial organization of tumor constructs applied for preclinical drug sensitivity and to study the tumor microenvironment (Hermida et al, 2020). The study shows that the 3D bioprinting of cells has negligible effect on cell viability, and more resistance to anticancer drugs (resembling in vivo condition) than 2D culture.…”

Section: Application Of 3d Culture Techniquesmentioning

confidence: 99%

Fabrication techniques of biomimetic scaffolds in three‐dimensional cell culture: A review

Badekila

Kini

Jaiswal

2020

Journal Cellular Physiology

View full text Add to dashboard Cite

In the last four decades, several researchers worldwide have routinely and meticulously exercised cell culture experiments in two-dimensional (2D) platforms. Using traditionally existing 2D models, the therapeutic efficacy of drugs has been inappropriately validated due to the failure in generating the precise therapeutic response. Fortunately, a 3D model addresses the foregoing limitations by recapitulating the in vivo environment. In this context, one has to contemplate the design of an appropriate scaffold for favoring the organization of cell microenvironment. Instituting pertinent model on the platter will pave way for a precise mimicking of in vivo conditions. It is because animal cells in scaffolds oblige spontaneous formation of 3D colonies that molecularly, phenotypically, and histologically resemble the native environment. The 3D culture provides insight into the biochemical aspects of cell-cell communication, plasticity, cell division, cytoskeletal reorganization, signaling mechanisms, differentiation, and cell death. Focusing on these criteria, this paper discusses in detail, the diversification of polymeric scaffolds based on their available resources. The paper also reviews the well-founded and latest techniques of scaffold fabrication, and their applications pertaining to tissue engineering, drug screening, and tumor model development.

show abstract

Three dimensional in vitro models of cancer: Bioprinting multilineage glioblastoma models

Cited by 72 publications

References 67 publications

3D Bioprinted cancer models: Revolutionizing personalized cancer therapy

3D Bioprinted cancer models: Revolutionizing personalized cancer therapy

Biomaterials and 3D Bioprinting Strategies to Model Glioblastoma and the Blood–Brain Barrier

Fabrication techniques of biomimetic scaffolds in three‐dimensional cell culture: A review

Contact Info

Product

Resources

About