Biomaterials‐Based Approaches to Tumor Spheroid and Organoid Modeling

Thakuri, Pradip Shahi; Liu, Chun; Luker, Gary D.; Tavana, Hossein

doi:10.1002/adhm.201700980

Cited by 102 publications

(97 citation statements)

References 200 publications

(421 reference statements)

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“…The natural proteins used as cell culture matrices are collagen, gelatin, fibrin, silk protein (mainly referring to silk fibroin), poly‐ l ‐lysine (PLL), and soy protein . These proteins can interact with cells and supply physiologically relevant microenvironments to guide cellular behaviors by presenting componential cues . In addition, Matrigel and decellularized extracellular matrices (dECM) are typical animal‐derived mixtures of various polysaccharides (e.g., HA and heparan), proteins (e.g., collagen and laminin), and growth factors.…”

Section: Snapshot Of Hydrogelsmentioning

confidence: 99%

“…Synthetic hydrogels are often considered to be permissive biomaterials for cell culture due to their bioinert properties . The common synthetic polymers in previous reports include polyethylene glycol (PEG) and its derivates, polylactic acid (PLA), poly(lactic‐ co ‐glycolic acid) (PLGA), poly(vinyl alcohol) (PVA), poly(ε‐caprolactone) (PCL), polyacrylic acid (PAA), polyacrylamide (PAm), poly(2‐hydroxyethyl methacrylate) (PHEMA), and polyurethane (PU) . They are usually blended/modified with proteins (e.g., laminin) or peptides (e.g., Arg‐Gly‐Asp, RGD) to increase their biocompatibility for employment as 3D scaffolds.…”

Section: Snapshot Of Hydrogelsmentioning

confidence: 99%

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Advances in Hydrogels in Organoids and Organs‐on‐a‐Chip

et al. 2019

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The major motivation is to better mimic human physiology and functions at multiscales from the molecular to the cellular, tissue, organ or even whole organism level. Current model systems primarily rely on the monolayer cell cultures and animal models. Simplistic monolayer cultures have their advantages, but they are often significantly different in gene expression, epigenetics, and cell function compared to native 3D tissues. [1,2] Also, they often lack cell-cell and cell-matrix interactions, [2,3] leading to the absence of tissue specific properties. Although animal models are widely used in biomedical research, they fail to faithfully predict human responses in a physiologically relevant manner due to the significant species divergences. [4] The limitations of these systems have provided an impetus for the development of alternative cell-based 3D models in vitro that better resemble the complex functionalities of living organs. Over the last several years, organoids and organ-on-a-chip (OOC), representing the major technological breakthrough, have emerged as two distinct model systems to achieve the same goal of building 3D organotypic models in vitro by bridging the gap between animal models and monolayer cultures. These engineered models are different in terms of cell source, tissue composition, architectural variability, functional features, scales, cellular fidelity, etc. Organoids, primarily evolving from developmental principles, refer to 3D multicellular tissues by self-organization of stem cells or organ-specific progenitors, which can recapitulate the intricate architectures and functionalities of in vivo organs. [5][6][7] Recent breakthroughs in organoid technology have enabled the successful generation of a variety of human organoids, such as the brain, [8,9] intestine, [10,11] liver, [12] kidney, [13,14] lung, [15] etc. These near physiological 3D organoids have garnered momentum for their potential applications in human organ development and disease modeling, drug screening and regenerative medicine. The explosion of organoids research has been catalyzed by the significant progress of stem cell biology and availability of human stem cells. In contrast, the OOC, relying on the bioengineering design principle, is a miniaturized in vitro model that can recreate the functional units of living organs on a microfluidic cell culture device using predifferentiated cells, often cell lines. [1,16] The OOC is primarily evolved from the convergence of tissue engineering and microfabricated technologies, which is characterized by the capability to simulate cellular microenvironment by precise control over fluid flow, mechanical forces and biochemical factors. [4,17] Remarkable progress has been made Significant advances in materials, microscale technology, and stem cell biology have enabled the construction of 3D tissues and organs, which will ultimately lead to more effective diagnostics and therapy. Organoids and organs-on-a-chip (OOC), evolved from developmental biology and bioengineering principles, have e...

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Section: Snapshot Of Hydrogelsmentioning

confidence: 99%

Section: Snapshot Of Hydrogelsmentioning

confidence: 99%

Advances in Hydrogels in Organoids and Organs‐on‐a‐Chip

et al. 2019

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“…In all matrices, E‐cadherin was enriched at cell–cell boundaries, and laminin‐332 appeared to be interspersed throughout the spheroid, with slight concentrations at cell–cell boundaries (Figure ). These results indicated that the LNCaP cells assume a disorganized, non‐polarized morphology within the spheroids, consistent with the behavior of LNCaP cells in previously investigated synthetic matrices such as functionalized hyaluronic acid …”

Section: Resultsmentioning

confidence: 97%

“…In response to the shortcomings of Matrigel, multiple synthetic 3D culture systems have received considerable interest . Synthetic matrices may avoid the most limiting aspects of Matrigel but must be designed to recapitulate the extracellular matrix's mechanical properties, transport properties, specific biological interactions, and degradation/remodeling processes that occur within the tumor microenvironment .…”

Section: Introductionmentioning

confidence: 99%

Self‐Assembling Peptide Gels for 3D Prostate Cancer Spheroid Culture

Hainline

Handley

et al. 2018

Macromolecular Bioscience

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Progress in prostate cancer research is presently limited by a shortage of reliable in vitro model systems. We describe a novel self-assembling peptide, bQ13, which forms nanofibers and gels useful for the 3D culture of prostate cancer spheroids, with improved cytocompatibility compared to related fibrillizing peptides. The mechanical properties of bQ13 gels could be controlled by adjusting peptide concentration, with storage moduli ranging between 1–10 kPa. bQ13’s ability to remain soluble at mildly basic pH considerably improved the viability of encapsulated cells compared to other self-assembling nanofiber-forming peptides. LNCaP cells formed spheroids in bQ13 gels with similar morphologies and sizes to those formed in Matrigel or RADA16-I. Moreover, prostate-specific antigen (PSA) was produced by LNCaP cells in all matrices, and PSA production was more responsive to enzalutamide treatment in bQ13 gels than in other fibrillized peptide gels. bQ13 represents an attractive platform for further tailoring within 3D cell culture systems.

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“…Organoids have been utilized as microphysiological systems to study the important morphogenetic and functional hallmarks found in the human tissues. 42,43 Recently, organoids have emerged as alternative platforms to understand cancer biology. 44,45 Hence, organoid cultures have been established for many cancer types with success rates between 15% and 100%.…”

Section: Engineering Matrices To Build Better Organoidsmentioning

confidence: 99%

Design and Fabrication of Three-Dimensional Printed Scaffolds for Cancer Precision Medicine

Shafiee

2020

Tissue Engineering Part A

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Three-dimensional (3D)-engineered scaffolds have been widely investigated as drug delivery systems (DDS) or cancer models with the aim to develop effective cancer therapies. The in vitro and in vivo models developed via 3D printing (3DP) and tissue engineering concepts have significantly contributed to our understanding of cellcell and cell-extracellular matrix interactions in the cancer microenvironment. Moreover, 3D tumor models were used to study the therapeutic efficiency of anticancer drugs. The present study aims to provide an overview of applying the 3DP and tissue engineering concepts for cancer studies with suggestions for future research directions. The 3DP technologies being used for the fabrication of personalized DDS have been highlighted and the potential technical approaches and challenges associated with the fused deposition modeling, the inkjetpowder bed, and stereolithography as the most promising 3DP techniques for drug delivery purposes are briefly described. Then, the advances, challenges, and future perspectives in tissue-engineered cancer models for precision medicine are discussed. Overall, future advances in this arena depend on the continuous integration of knowledge from cancer biology, biofabrication techniques, multiomics and patient data, and medical needs to develop effective treatments ultimately leading to improved clinical outcomes.

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Biomaterials‐Based Approaches to Tumor Spheroid and Organoid Modeling

Cited by 102 publications

References 200 publications

Advances in Hydrogels in Organoids and Organs‐on‐a‐Chip

Advances in Hydrogels in Organoids and Organs‐on‐a‐Chip

Self‐Assembling Peptide Gels for 3D Prostate Cancer Spheroid Culture

Design and Fabrication of Three-Dimensional Printed Scaffolds for Cancer Precision Medicine

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