Development of a 3D Tissue Engineered Bone Tumor Model

Burdett, Emily

16 September 2013

3D ex vivo tumor models are required which better replicate the microenvironment encountered by tumor cells in vivo. In this study, we applied bone tissue engineering culture techniques to develop an ex vivo 3D bone tumor model. Ewing sarcoma cells were cultured on poly(ε-caprolactone) (PCL) microfiber scaffolds, and cellular growth kinetics, morphology, and infiltration were assessed. Cell/scaffold constructs were then exposed to anticancer drugs for up to 16 days and drug response was compared to 2D controls. Ewing sarcoma cells were capable of attachment and proliferation on PCL scaffolds and dense scaffold infiltration up to 200 micrometers. Constructs could be maintained in culture for up to 32 days, and high density 3D cell growth conferred an increased resistance to anticancer drugs over 2D controls. This 3D tumor model shows potential for use in future studies of bone tumor biology, especially as it pertains to the development of new anticancer drugs.

Tissue Engineering

3D Cancer Models

Ewing Sarcoma

Cancer Drug Discovery

Agarose Spot as a Comparative Method for in situ Analysis of Simultaneous Chemotactic Responses to Multiple Chemokines

Ahmed, Mohaned S.A., Basheer, Haneen A., Ayuso, J.M., Ahmet, Djevdet S., Mazzini, Marco, Patel, Roshan, Shnyder, Steven, Vinader, Victoria, Afarinkia, Kamyar

20 March 2017

Yes / We describe a novel protocol to quantitatively and simultaneously compare the chemotactic responses of cells towards different chemokines. In this protocol, droplets of agarose gel containing different chemokines are applied onto the surface of a Petri dish, and then immersed under culture medium in which cells are suspended. As chemokine molecules diffuse away from the spot, a transient chemoattractant gradient is established across the spots. Cells expressing the corresponding cognate chemokine receptors migrate against this gradient by crawling under the agarose spots towards their centre. We show that this migration is chemokine-specific; meaning that only cells that express the cognate chemokine cell surface receptor, migrate under the spot containing its corresponding chemokine ligand. Furthermore, we show that migration under the agarose spot can be modulated by selective small molecule antagonists present in the cell culture medium.

Drug screening

Chemotactic migration

Agarose gel

Chemokines

Cancer models

Development of tumour therapies : from target validation of TTLL12 to tests of a small molecule XRP44X in pre-clinical models of cancer / Développement de thérapies antitumorales : caractérisation de TTLL12 comme cible thérapeutique et effet du composé XRP44X dans des modèles cancéreux pré-cliniques.

Semenchenko, Kostyantyn

21 May 2014

Les modifications post-traductionnelles de la tubuline sont des cibles attrayantes pour la thérapie du cancer. TTLL12 est impliqué dans la détyrosination de la tubuline, la triméthylation de l’histone H4K20 et le cancer de la prostate. La thèse porte sur les effets de la surexpression de TTLL12 sur ces modifications à différents stades du cycle cellulaire et sur la sensibilité à des agents ciblant les microtubules. Les résultats montrent que TTLL12 affecte ces modifications indépendant du cycle cellulaire et réduit la sensibilité des cellules à paclitaxel. XRP44X est un nouvel inhibiteur de la signalisation Ras-ERK-Elk3. Ses propriétés antitumorigène ont été montré in vitro et dans certaines études in vivo. Le projet de thèse était une continuation des études pré-cliniques sur XRP44X dans des modèles de cancer de la prostate de souris. Les résultats montrent que XRP44X est un inhibiteur efficace de la tumorigenèse et des métastases, ce qui peut être dû à son effet sur Elk3. / Tubulin posttranslational modifications are an attractive target for cancer therapy. TTLL12 isinvolved in tubulin detyrosination, histone H4K20 trimethylation and prostate cancer. The thesis addresses the effects of TTLL12 overexpression on these tubulin and histone modifications at different stages of the cell cycle and on sensitivity to microtubule-targeting agents. The results show that TTLL12 over expression affects tubulin detyrosination and H4K20 trimethylation independently of cell cycle phase and reduces cell sensitivity totaxanes.XRP44X is a novel inhibitor of Ras-ERK1/2-Elk3 signalling and tubulin-binding agent. Itsantitumorigenic properties had been shown in vitro and in initial in vivo studies. The thesis project was a continuation of pre-clinical studies on XRP44X in mouse prostate cancer models. The results show that XRP44X is an effective inhibitor of tumorigenesis and metastasis in prostate cancer, which may be due to its effect on Elk3.

Cancer de la prostate

TTLL12

Tyrosination de la tubuline

Elk3

Modèles de cancer de souris

Préclinique

Cible thérapeutique

Prostate cancer

TTLL12

Tubulin tyrosination

Elk3

Mouse cancer models

Pre-clinical

572.8

615.7

Zánět a rakovina v bezmikrobních vs. standardně chovaných zvířatech / Inflammation and cancer in germ-free vs. conventionally reared animals

Čaja, Fabián

January 2021

Inflammation is considered as one of the main defence mechanisms of the immune system against threats that occur in the body. When present in its acute form, minimal or no detectable subsequent damage of original affected tissue exists. The more pathological form, chronic inflammation, is associated with permanent damage of the tissue and typically a hallmark of various diseases such as ulcerative colitis or colon carcinogenesis. These two pathologies are evolving in the unique colon microenvironment, where intensive interaction between the host cells and bacteria is present. The aim of our study was to investigate the immunological (ELISA, FACS, RT-PCR) and structural (histology, confocal microscopy) changes in the colon mucosa of Wistar-AVN rats induced by dextran sodium sulphate (DSS) to produce colon colitis and by azoxymethane (AOM) to produce colon carcinogenesis. Conventional (CV) and also germ-free (GF) reared animals were used to investigate the effects of the mucosal inflammation activated by the administered inducers as well as the role of colon microbiota - as promoters of a continuous immune activation - in the modulation of immunity and collagen scaffold remodelling. Our results showed that even in the early period after the induction, both inducers produced a smouldering...

<b>Reprogramming the Pancreatic Cancer Stroma by Targeting Coagulation at the Tumor Microenvironment</b>

Sae Rome Choi (18392505)

17 April 2024

<p dir="ltr">Pancreatic ductal adenocarcinoma (PDAC) remains one of the most deadliest cancer and despite advancements in cancer therapy, remain highly refractory to treatment, largely due to its desmoplastic tumor microenvironment (TME) characterized by complex interactions among cancer cells and stromal components. Particularly, the PDAC associated coagulation system due to leaky tumor vasculatures plays a pivotal role in reshaping the PDAC stroma and its pathogenesis. Understanding the intricate interplay between tumor cells, stromal cells, and the elevated coagulation pathway elements, including tissue factor, thrombin, and fibrin, is essential for developing effective therapeutic strategies. To address these challenges, this research proposes the engineering of a novel PDAC-associated coagulation system using a microfluidic technology, known as coagulation-on-tumor-microenvironment-on-chip (cT-MOC). The study aims to integrate key coagulation pathways in cT-MOC to investigate pivotal interactions in the PDAC stroma: <i>i)</i> thrombin-protease-activated receptors (PARs) mediated promotion of PDAC fibrosis via activation of cancer-fibroblast cross-talk; <i>ii)</i> in-depth analysis of transport and mechanical properties of collagen-fibrin microstructure; <i>iii)</i> inhibited drug delivery in reprogrammed PDAC stroma due to pronounced fibrin deposition on collagen. By leveraging innovative microfluidic technologies and comprehensive experimental approaches, the research endeavors to provide a novel platform that bridges traditional <i>in vitro</i> and <i>in vivo</i> models to overcome the challenges posed by the desmoplastic TME and enhance therapeutic strategies for treatment by targeting the coagulation at the PDAC TME.</p>

Cancer cell biology

Cancer diagnosis

Chemotherapy

Solid tumours

Biofabrication

Biomaterials

Biomechanical engineering

Tissue engineering

pancreatic adenocarcinoma cancer ce...

lab on-a-chip device

preclinical cancer models

Tissue engineered cell culture models

drug delivery & targeting