eoe sub articles

EoE Sub Articles

<figure class='table' style='width:624pt;'><table class='ck-table-resized'><colgroup><col style='width:24.52%;'><col style='width:28.69%;'><col style='width:23.24%;'><col style='width:23.55%;'></colgroup><tbody><tr><td style='height:14.5pt;width:153pt;'>Biosafety cabinet</td><td style='width:179pt;'>ThermoFisher Scientific</td><td style='width:145pt;'>1300 Series Class II, Type A2</td><td style='width:147pt;'>&#160;</td></tr><tr><td style='height:14.5pt;width:153pt;'>CIM plates</td><td style='width:179pt;'>Cell Analysis Division of Agilent Technologies, Inc</td><td style='width:145pt;'>5665825001</td><td style='width:147pt;'>Cell invasion and migration plates</td></tr><tr><td style='height:14.5pt;width:153pt;'>Dulbecco&#8217;s modified eagle&#8217;s medium (DMEM)</td><td style='width:179pt;'>ATCC</td><td style='width:145pt;'>302002</td><td style='width:147pt;'>Culture medium used for cell culture</td></tr><tr><td style='height:14.5pt;width:153pt;'>Dulbecco's phosphate-buffered saline (DPBS)</td><td style='width:179pt;'>Gibco</td><td style='width:145pt;'>21-031-CV</td><td style='width:147pt;'>DPBS used to wash the cells</td></tr><tr><td style='height:14.5pt;width:153pt;'>Fetal bovine serum (FBS)</td><td style='width:179pt;'>Hyclone</td><td style='width:145pt;'>SH30910.03</td><td style='width:147pt;'>&#160;</td></tr><tr><td style='height:14.5pt;width:153pt;'>Heracell VIOS 160i carbon dioxide incubator</td><td style='width:179pt;'>ThermoFisher Scientific</td><td style='width:145pt;'>51030285</td><td style='width:147pt;'>Carbon dioxide incubator</td></tr><tr><td style='height:14.5pt;width:153pt;'>Matrigel</td><td style='width:179pt;'>BD Bioscience</td><td style='width:145pt;'>354234</td><td style='width:147pt;'>Extracellular matrix gel</td></tr><tr><td style='height:14.5pt;width:153pt;'>RTCA software</td><td style='width:179pt;'>Cell Analysis Division of Agilent Technologies, Inc</td><td style='width:145pt;'>&#160;</td><td style='width:147pt;'>Instrument used for experiment</td></tr><tr><td style='height:14.5pt;width:153pt;'>Scepter</td><td style='width:179pt;'>Millipore</td><td style='width:145pt;'>C85360</td><td style='width:147pt;'>Handheld automated cell counter</td></tr><tr><td style='height:14.5pt;width:153pt;'>Trypsin-EDTA</td><td style='width:179pt;'>Gibco</td><td style='width:145pt;'>25300-054</td><td style='width:147pt;'>&#160;</td></tr><tr><td style='height:14.5pt;width:153pt;'>U-118MG</td><td style='width:179pt;'>ATCC</td><td style='width:145pt;'>ATCC HTB15</td><td style='width:147pt;'>Cell lines used for experiments</td></tr><tr><td style='height:14.5pt;width:153pt;'>xCELLigence RTCA DP</td><td style='width:179pt;'>Cell Analysis Division of Agilent Technologies, Inc</td><td style='width:145pt;'>380601050</td><td>&#160;</td></tr></tbody></table></figure>

impedance-based measurements of brain cancer cell invasion

<a href='https://app.jove.com/v/60997/impedance-based-real-time-measurement-cancer-cell-migration'>Source: Mudduluru, G., et. al. Impedance-based Real-time Measurement of Cancer Cell Migration and Invasion. J. Vis. Exp. (2020)</a>This video demonstrates an impedance-based assay to measure glioblastoma cell invasion and migration. Cells degrade the extracellular matrix, move through microporous membranes, and adhere to electrodes, generating impedance. This real-time analysis reflects their invasive potential for cancer research applications.

Impedance-Based Measurements of Brain Cancer Cell Invasion

Source: Mudduluru, G., et. al. Impedance-based Real-time Measurement of Cancer Cell Migration and Invasion. J. Vis. Exp. (2020)This video demonstrates an ...

Take a cell invasion and migration plate containing upper and lower chambers.The upper chamber contains a microporous membrane with an impedance-measuring gold microelectrode array on its bottom. Coat the membrane with an extracellular matrix or ECM solution.&#160;Fill the lower chamber with high-serum media.Then, add low-serum media to the upper chamber and incubate to acclimate to culture conditions.Apply a weak electrical potential across the microelectrodes to measure the baseline impedance.Seed brain cancer cells in the upper chamber and allow them to settle on the ECM.&#160;The high-serum media acts as a chemoattractant, guiding the cells&#8217; movement toward it.&#160;The cells secrete proteases that degrade the ECM, enabling their movement through the membrane pores toward the chemoattractant.As the cells migrate, they adhere to the microelectrodes, increasing cellular impedance.Over time, more cells migrate and attach to the microelectrodes, further increasing cellular impedance, which reflects the invasive potential of these cells.

impedance-based-measurements-of-brain-cancer-cell-invasion

Nanyang Technological University

Research

JoVE Encyclopedia of Experiments

Neuroscience

Neuropathology

Tumors

40 Views. Source: Mudduluru, G., et. al. Impedance-based Real-time Measurement of Cancer Cell Migration and Invasion. J. Vis. Exp. (2020) This video demonstrates an impedance-based assay to measure glioblastoma cell invasion and migration. Cells degrade the extracellular matrix, move through microporous membranes, and adhere to electrodes, generating impedance. This real-time analysis reflects their invasive potential for cancer research applications. 

Video: Impedance-Based Measurements of Brain Cancer Cell Invasion - Concept

Stepwise Dosing Protocol for Increased Throughput in Label-Free Impedance-Based GPCR Assays

Label-free impedance-based assays are increasingly used to non-invasively study ligand-induced GPCR activation in cell culture experiments. The approach provides real-time cell monitoring with a device-dependent time resolution down to several tens of milliseconds and it is highly automated. However, when sample numbers get high (e.g., dose-response studies for various different ligands), the cost for the disposable electrode arrays as well as the available time resolution for sequential well-by-well recordings may become limiting. Therefore, we here present a serial agonist addition protocol which has the potential to significantly increase the output of label-free GPCR assays. Using the serial agonist addition protocol, a GPCR agonist is added sequentially in increasing concentrations to a single cell layer while continuously monitoring the sample&#39;s impedance (agonist mode). With this serial approach, it is now possible to establish a full dose-response curve for a GPCR agonist from just one single cell layer. The serial agonist addition protocol is applicable to different GPCR coupling types, Gq Gi/0 or Gs and it is compatible with recombinant and endogenous expression levels of the receptor under study. Receptor blocking by GPCR antagonists is assessable as well (antagonist mode).

This protocol demonstrates real-time recording of full dose-response relationships for agonist-induced GPCR activation from a single cell layer grown on a single microelectrode using label-free impedance measurements. The new dosing scheme significantly increases throughput without loss in time resolution.

Label-free impedance-based assays are increasingly used to non-invasively study ligand-induced GPCR activation in cell culture experiments. The approach ...

JoVE Journal

Biochemistry

Real-Time Detection and Capture of Invasive Cell Subpopulations from Co-Cultures

Invasion and metastatic spread of cancer cells are the major cause of death from cancer. Assays developed early on to measure the invasive potential of cancer cell populations typically generate a single endpoint measurement that does not distinguish between cancer cell subpopulations with different invasive potential. Also, the tumor microenvironment consists of different resident stromal and immune cells that alter and participate in the invasive behavior of cancer cells. Invasion into tissues also plays a role in immune cell subpopulations fending off microorganisms or eliminating diseased cells from the parenchyma and endothelial cells during tissue remodeling and angiogenesis. Real-Time Cellular Analysis (RTCA) that utilizes impedance biosensors to monitor cell invasion was a major step forward beyond endpoint measurement of invasion: this provides continuous measurements over time and thus can reveal differences in invasion rates that are lost in the endpoint assay. Using current RTCA technology, we expanded dual-chamber arrays by adding a further chamber that can contain stromal and/or immune cells and allows measuring the rate of invasion under the influence of secreted factors from co-cultured stromal or immune cells over time. Beyond this, the unique design allows for detaching chambers at any time and isolating of the most invasive cancer cell, or other cell subpopulations that are present in heterogeneous mixes of tumor isolates tested. These most invasive cancer cells and other cell subpopulations drive malignant progression to metastatic disease, and their molecular characteristics are important for in-depth mechanistic studies, the development of diagnostic probes for their detection, and the assessment of vulnerabilities. Thus, the inclusion of small- or large-molecule drugs can be used to test the potential of therapies that target cancer and/or stromal cell subpopulations with the goal of inhibiting (e.g., cancer cells) or enhancing (e.g., immune cells) invasive behavior.

We describe an approach to detect and capture invasive cell subpopulations in real-time. The experimental design uses Real-Time Cellular Analysis by monitoring changes in the electric impedance of cells. Invasive cancer, immune, endothelial or stromal cells in complex tissues can be captured, and the impact of co-cultures can be assessed.

Invasion and metastatic spread of cancer cells are the major cause of death from cancer. Assays developed early on to measure the invasive potential of ...

Cancer Research

Monitoring Influenza Virus Survival Outside the Host Using Real-Time Cell Analysis

Methods for virus particle quantification represent a critical aspect of many virology studies. Although several reliable techniques exist, they are either time-consuming or unable to detect small variations. Presented here is a protocol for the precise quantification of viral titer by analyzing electrical impedance variations of infected cells in real-time. Cellular impedance is measured through gold microelectrode biosensors located under the cells in microplates, in which magnitude depends on the number of cells as well as their size and shape. This protocol allows real-time analysis of cell proliferation, viability, morphology and migration with enhanced sensitivity. Also provided is an example of a practical application by quantifying the decay of influenza A virus (IAV) submitted to various physicochemical parameters affecting viral infectivity over time (i.e., temperature, salinity, and pH). For such applications, the protocol reduces the workload needed while also generating precise quantification data of infectious virus particles. It allows the comparison of inactivation slopes among different IAV, which reflects their capacity to persist in given environment. This protocol is easy to perform, is highly reproducible, and can be applied to any virus producing cytopathic effects in cell culture.

Reported here is a protocol for the quantification of infectious viral particles using real-time monitoring of electrical impedance of infected cells. A practical application of this method is presented by quantifying influenza A virus decay under different physicochemical parameters mimicking environmental conditions.

Methods for virus particle quantification represent a critical aspect of many virology studies. Although several reliable techniques exist, they are ...

Impedance-Based Measurements of Brain Cancer Cell Invasion

Transcript

Impedance-Based Measurements of Brain Cancer Cell Invasion

Stepwise Dosing Protocol for Increased Throughput in Label-Free Impedance-Based GPCR Assays

Real-Time Detection and Capture of Invasive Cell Subpopulations from Co-Cultures

Monitoring Influenza Virus Survival Outside the Host Using Real-Time Cell Analysis