Application of 3D tumoroid systems to define immune and cytotoxic therapeutic responses based on tumoroid and tissue slice culture molecular signatures

Finnberg, Niklas; Gokare, Prashanth; Lev, Avital; Grivennikov, Sergei I.; Macfarlane, Alexander W.; Campbell, Kerry S.; Winters, Ryan M.; Kaputa, Karen; Farma, Jeffrey M.; Abbas, Abbas El-Sayed; Grasso, Luigi; Nicolaides, Nicholas C.; El‐Deiry, Wafik S.

doi:10.18632/oncotarget.19965

Cited by 96 publications

(83 citation statements)

References 34 publications

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“…For example, comparison of drug response profiles of breast, prostate and lung cancer cell lines revealed clear differences in dose response curves to docetaxel and fulvestrant when cells were grown in collagen and compared to 2D cultures or other 3D culture systems such as low attachment plates and other natural scaffolds, including alginate and Matrigel (Stock et al, 2016 ). Multiple myeloma cells cultured in a Matrigel-based human bone marrow-like microenvironment provide a system for preclinical testing of chemotherapeutics that take into account adhesion-mediated mechanisms of drug resistance (Kirshner et al, 2008 ) and Matrigel-embedded 3D-tumoroids derived from tissue of patients with colorectal cancer and lung cancer can provide a 3D culture system for drug testing that contains not only tumor cells but also immune cells from surrounding tissues (Finnberg et al, 2017 ). Matrigel and similar products are a gelatinous mixture of proteins and growth factors secreted by Engelbreth-Holm-Swarm mouse sarcoma cells (Kleinman and Martin, 2005 ).…”

Section: The Extracellular Matrix (Ecm) and Other Microenvironmentalmentioning

confidence: 99%

Three-Dimensional in Vitro Cell Culture Models in Drug Discovery and Drug Repositioning

2018

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Drug development is a lengthy and costly process that proceeds through several stages from target identification to lead discovery and optimization, preclinical validation and clinical trials culminating in approval for clinical use. An important step in this process is high-throughput screening (HTS) of small compound libraries for lead identification. Currently, the majority of cell-based HTS is being carried out on cultured cells propagated in two-dimensions (2D) on plastic surfaces optimized for tissue culture. At the same time, compelling evidence suggests that cells cultured in these non-physiological conditions are not representative of cells residing in the complex microenvironment of a tissue. This discrepancy is thought to be a significant contributor to the high failure rate in drug discovery, where only a low percentage of drugs investigated ever make it through the gamut of testing and approval to the market. Thus, three-dimensional (3D) cell culture technologies that more closely resemble in vivo cell environments are now being pursued with intensity as they are expected to accommodate better precision in drug discovery. Here we will review common approaches to 3D culture, discuss the significance of 3D cultures in drug resistance and drug repositioning and address some of the challenges of applying 3D cell cultures to high-throughput drug discovery.

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Section: The Extracellular Matrix (Ecm) and Other Microenvironmentalmentioning

confidence: 99%

Three-Dimensional in Vitro Cell Culture Models in Drug Discovery and Drug Repositioning

2018

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“…Organoids resemble the heterogeneous cytoarchitecture found in vivo and advanced microscopy techniques can be used to follow the dynamic processes of organoid development and maturation been made in cancer immunotherapy, and several organoid-based models have been created to better our understanding on how the immune system eradicates tumor cells, facilitating a personalized immunotherapeutic approach [171]. Currently, two conceptually different organoid models are used-i.e., cancer organoids cultured directly from tumors preserving endogenous immune cells and other non-epithelial cell types (holistic approach) [172][173][174][175], and cancer organoids co-cultured with immune cell subsets isolated and separately expanded (reductionist approach) [176][177][178]. The two are equally valid approaches to understanding cell-cell interactions, modelling immune checkpoint blockade and testing CAR-T cell-mediated cytotoxicity and represent a highly informative platform for the development of cancer immunotherapy.…”

Section: Integrating the Microenvironment In Organoids: Current Advancesmentioning

confidence: 99%

Modeling neoplastic disease with spheroids and organoids

et al. 2020

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Cancer is a complex disease in which both genetic defects and microenvironmental components contribute to the development, progression, and metastasization of disease, representing major hurdles in the identification of more effective and safer treatment regimens for patients. Three-dimensional (3D) models are changing the paradigm of preclinical cancer research as they more closely resemble the complex tissue environment and architecture found in clinical tumors than in bidimensional (2D) cell cultures. Among 3D models, spheroids and organoids represent the most versatile and promising models in that they are capable of recapitulating the heterogeneity and pathophysiology of human cancers and of filling the gap between conventional 2D in vitro testing and animal models. Such 3D systems represent a powerful tool for studying cancer biology, enabling us to model the dynamic evolution of neoplastic disease from the early stages to metastatic dissemination and the interactions with the microenvironment. Spheroids and organoids have recently been used in the field of drug discovery and personalized medicine. The combined use of 3D models could potentially improve the robustness and reliability of preclinical research data, reducing the need for animal testing and favoring their transition to clinical practice. In this review, we summarize the recent advances in the use of these 3D systems for cancer modeling, focusing on their innovative translational applications, looking at future challenges, and comparing them with most widely used animal models.

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“… 70 – 74 Tissue-derived organoids can be cocultured with local tumor-infiltrating immune cells to assess the response to chemotherapeutic agents and radiation. 75 Along with the ability to assess the effects of chemotherapeutic agents and radiation directly on patient tumor samples, organoids also allow us to more deeply analyze the transcriptional and proteomic profiles of individual patients. Using normal and cancer organoids derived from the same patient, Cristobal and coworkers 76 determined a CRC-specific proteomic profile that showed a significant enrichment in Wnt signaling as would be expected, along with unique tumor proteomic signatures.…”

Section: Methodsmentioning

confidence: 99%

Organoid Models of Colorectal Pathology: Do They Hold the Key to Personalized Medicine? A Systematic Review

DeHaan

Sarvestani

Huang

2020

Diseases of the Colon &Amp; Rectum

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Application of 3D tumoroid systems to define immune and cytotoxic therapeutic responses based on tumoroid and tissue slice culture molecular signatures

Cited by 96 publications

References 34 publications

Three-Dimensional in Vitro Cell Culture Models in Drug Discovery and Drug Repositioning

Three-Dimensional in Vitro Cell Culture Models in Drug Discovery and Drug Repositioning

Modeling neoplastic disease with spheroids and organoids

Organoid Models of Colorectal Pathology: Do They Hold the Key to Personalized Medicine? A Systematic Review

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