logo
搜索
菜单

Real-Time Monitoring of Human Glioma Cell Migration on Dorsal Root Ganglion Axon-Oligodendrocyte Co-Cultures

作者: John P. Zepecki1, Kristin M. Snyder2, Nikos Tapinos1,3 1Molecular Neuro-oncology Laboratory,Brown University, Rhode Island Hospital, 2University of Minnesota, College of Veterinary Medicine, 3Department of Neurosurgery,Brown University
简介:

Overview

This article presents an ex-vivo mixed monolayer culture system designed for real-time observation of human glioma cell migration. The model allows for the study of interactions between glioma cells and axons in a compartmentalized environment.

Key Study Components

Area of Science

  • Neuroscience
  • Cell Biology
  • Oncology

Background

  • Human glioma cells (hGCs) are critical in understanding glioma progression.
  • Real-time observation of cell migration can reveal important biological mechanisms.
  • Interactions between glioma cells and axons are essential for studying tumor behavior.
  • Ex-vivo models provide a controlled environment for experimentation.

Purpose of Study

  • To develop a co-culture system for studying hGC migration.
  • To identify cellular and molecular mechanisms involved in glioma cell behavior.
  • To facilitate in vitro drug efficacy testing.

Methods Used

  • Assembly of compartmented culture dishes using collagen.
  • Real-time imaging of hGC interactions with axons.
  • Co-culture techniques to maintain cell viability.
  • Assessment of migration patterns and cellular responses.

Main Results

  • Successful establishment of a mixed monolayer culture system.
  • Real-time observation of hGC migration dynamics.
  • Identification of key interactions between glioma cells and axons.
  • Potential applications in drug testing and therapeutic strategies.

Conclusions

  • The ex-vivo model is a valuable tool for glioma research.
  • Real-time analysis enhances understanding of glioma cell behavior.
  • This system may lead to novel therapeutic approaches for glioma treatment.

Frequently Asked Questions

What is the main advantage of this co-culture system?
The main advantage is the ability to study interactions between human glioblastoma cells and axons in real time.
Who demonstrates the procedure in the article?
John Zepecki, a graduate student from the lab, demonstrates the procedure.
What is the purpose of using collagen in the culture dishes?
Collagen provides a supportive matrix for cell attachment and growth in the culture system.
How can this model be used in drug testing?
The model can be used to assess the efficacy of drugs on glioma cell migration and interaction with axons.
What types of axons are studied in this model?
Both myelinated and non-myelinated axons are studied to understand their interactions with glioma cells.
Is this model suitable for other types of cancer research?
While designed for glioma, the principles may be adapted for studying other cancers involving similar cellular interactions.

Here we present an ex-vivo mixed monolayer culture system for the study of human glioma cell (hGC) migration in real-time. This model provides the ability to observe interactions between hGCs and both myelinated and non-myelinated axons within a compartmentalized chamber.

标签: Real-time Monitoring,    Human Glioma,    Cell Migration,    Dorsal Root Ganglion,    Axon-oligodendrocyte Co-cultures,    Ex Vivo,    Drug Efficacy Testing,    Human Glioblastoma,    Collagen Solution,    Compartmented Culture Dishes,    Sterile Techniques,    Neuronal Basal Medium,    Silicone Grease,    Hemostatic Forceps,   
Murine Model of Metastatic Liver Tumors in the Setting of Ischemia Reperfusion Injury 10.3791/59748-v 05:59 min
Murine Model of Metastatic Liver Tumors in the Setting of Ischemia Reperfusion Injury
Detection and Monitoring of Tumor Associated Circulating DNA in Patient Biofluids 10.3791/59721-v
Detection and Monitoring of Tumor Associated Circulating DNA in Patient Biofluids
Assessing Cell Viability and Death in 3D Spheroid Cultures of Cancer Cells 10.3791/59714-v 10:33 min
Assessing Cell Viability and Death in 3D Spheroid Cultures of Cancer Cells
Physiologic Patient Derived 3D Spheroids for Anti-neoplastic Drug Screening to Target Cancer Stem Cells 10.3791/59696-v 10:03 min
Physiologic Patient Derived 3D Spheroids for Anti-neoplastic Drug Screening to Target Cancer Stem Cells
A Human Peripheral Blood Mononuclear Cell (PBMC) Engrafted Humanized Xenograft Model for Translational Immuno-oncology (I-O) Research 10.3791/59679-v 08:17 min
A Human Peripheral Blood Mononuclear Cell (PBMC) Engrafted Humanized Xenograft Model for Translational Immuno-oncology (I-O) Research
Micromanipulation of Circulating Tumor Cells for Downstream Molecular Analysis and Metastatic Potential Assessment 10.3791/59677-v 05:17 min
Micromanipulation of Circulating Tumor Cells for Downstream Molecular Analysis and Metastatic Potential Assessment
Spatial and Temporal Control of Murine Melanoma Initiation from Mutant Melanocyte Stem Cells 10.3791/59666-v 06:09 min
Spatial and Temporal Control of Murine Melanoma Initiation from Mutant Melanocyte Stem Cells
Assessing Tumor Microenvironment of Metastasis Doorway-Mediated Vascular Permeability Associated with Cancer Cell Dissemination using Intravital Imaging and Fixed Tissue Analysis 10.3791/59633-v 09:42 min
Assessing Tumor Microenvironment of Metastasis Doorway-Mediated Vascular Permeability Associated with Cancer Cell Dissemination using Intravital Imaging and Fixed Tissue Analysis
返回顶部