Name: 视频: 基于阻抗的细胞检测法测量流感病毒感染的复数 - 概念
Uploaded: 2023-04-30T15:06:03.000+00:00
Duration: 1 min 59 s
Description: 115 次观看. 来源:Labadie， T. 等人，使用实时细胞分析监测流感病毒在宿主外的存活。J. Vis. Exp. （2021 年） 在本视频中，我们讨论了 CIT50 与病毒感染多样性之间的相关性。病毒感染的细胞表现出细胞病变效应，导致它们死亡并从金微电极上脱离，进而降低阻抗。

eoe sub articles

EoE Sub Articles

1. Correlation between CIT50 values and multiplicity of infection
<ol>
	<li>Add 100 &#181;L of sterile 1x MEM culture medium in each well of the E-plate. Insert the E-plate into the cradle pocket of the instrument at 35&#176;C.</li>
	<li>Measure the background as described:</li>
	<li>Open the software.
	<ol>
		<li>In &#34;Default experiment pattern setup&#34;, choose the selected cradle(s) and double-click on the top page, then enter the name of the experiment. Click &#34;Layout&#34; and enter the necessary sample information for each selected well of the plate; then, click &#34;Apply&#34; when finished. Click &#34;Schedule&#34; | &#34;Steps&#34; | &#34;Add a step&#34;. The software automatically adds a step of 1s to measure the background impedance (CI).</li>
		<li>Click on &#34;Start/Continue&#34; in the &#34;Execute&#34; tab. Click on &#34;Plot,&#34; add all samples by selecting the appropriated wells, and ensure CI is between -0.1 and 0.1 before proceeding to the next step.</li>
	</ol>
	</li>
	<li>Remove the E-plate from the cradle.</li>
	<li>Seed 3 x 104 of freshly split MDCK cells on each well of the electronic microtiter plate and grow them for 24h at 35&#176;C with 5% CO2 so that they are in a replicative phase during IAV infection.</li>
	<li>Infect MDCK cells with different 10-fold dilutions of a known 6log10TCID50/mL titer of H1N1 virus, using reverse pipetting for reproducibility by following the steps below:
	<ol>
		<li>Rinse MDCK cells 2x with 100 &#181;L of MEM with no FCS (virus propagation media). Be aware of removing all media after the second wash to avoid further dilution of the inoculum.</li>
		<li>Add 100 &#181;L of viral suspension in each well using a single-channel pipette. To avoid contamination, proceed by starting from left to right, then top-to-bottom in the plate while covering the remaining wells with the lid.</li>
		<li>Insert the plate into the cradle pocket of the instrument at 35&#176;C. Be gentle to avoid sudden movements potentially leading to contamination.</li>
		<li>Start to monitor cell impedance every 15 min during at least 100 h as described:
		<ol>
			<li>Insert the E-plate into the cradle pocket. Click &#34;Schedule&#34; | &#34;Add step&#34; in the software and enter values to monitor cells every 30 min for 200 repetitions. Then, select &#34;Start/Continue&#34;.</li>
		</ol>
		</li>
		<li>After the two cycles of measurements (i.e., 30 min), pause the apparatus by clicking on &#34;Pause&#34; in the &#34;Execute&#34; tab and remove the E-plate from the cradle.</li>
		<li>Add 1&#181;g/mL TPCK-trypsin to the virus propagation media to cleave the viral hemagglutinin.</li>
		<li>Add 100 &#181;L of virus propagation media containing TPCK-trypsin into each well and insert the E-plate into the cradle pocket.</li>
		<li>Click &#34;Start/Continue&#34; in the &#34;Execute&#34; tab. 
		NOTE: Do not forget to create a negative control corresponding to mock-infected cells by replacing viral suspension with virus propagation media.</li>
	</ol>
	</li>
</ol>

<table><tbody><tr><td>E-Plate 16 (6 plates)</td><td>ACEA Biosciences, Inc</td><td>5469830001</td><td>E-plates are available in different packaging</td></tr><tr><td>MEM 1X</td><td>Life technologies (gibco)</td><td>31095029</td><td></td></tr><tr><td>TPCK-Trypsin</td><td>Worthington</td><td>LS003740</td><td></td></tr><tr><td>xCELLigence Real-Time Cell Analysis Instrument S16</td><td>ACEA Biosciences, Inc</td><td>380601310</td><td>The xCELLigence RTCA S16 instruments are available in different formats (16-well, 96-well, single or multi-plate)</td></tr></tbody></table>

impedance-based cellular assay to measure multiplicity of infection of influenza virus

Source: Labadie, T., et al., <a href="https://app.jove.com/v/61133">Monitoring Influenza Virus Survival Outside the Host Using Real-Time Cell Analysis.</a> J. Vis. Exp. (2021)
In this video, we discuss the correlation between the CIT50 and the multiplicity of viral infections. The virus-infected cells display cytopathic effects, causing their death and detachment from the gold microelectrode, which in turn, reduces the impedance.

Impedance-Based Cellular Assay to Measure Multiplicity of Infection of Influenza Virus

Source: Labadie, T., et al., Monitoring Influenza Virus Survival Outside the Host Using Real-Time Cell Analysis. J. Vis. Exp. (2021)
In this video, we ...

During influenza virus infection, the virus enters the cell through endocytosis and hijacks the host cell machinery, producing progeny virions. These get released, infecting neighboring cells, causing a cascade of infection.
To measure infectious influenza virus to cell ratio in culture &#8212; multiplicity of infection &#8212; add an appropriate density of freshly-obtained mammalian cell suspension into a microtiter plate.
The plate contains impedance-measuring gold microelectrodes embedded in the well bottom. Incubate, allowing cells to adhere to the well bottom and reach the exponential growth phase prior to infection.
Apply a small electrical potential between the microelectrodes. Cells adhered on the microelectrodes act as insulators, restricting current flow and increasing electrical resistance &#8212; impedance &#8212; which is measured.
Remove the media. Pipette the influenza virus suspension into the wells. Supplement with a suitable serine endoprotease.
During incubation, the serine endoprotease cleaves and activates the viral glycoprotein hemagglutinin, facilitating its binding to specific host cell receptors and subsequent virus cell entry.
Using host cell machinery, new viral particles are produced and released, infecting neighboring cells. As a result, the virus-infected cells undergo morphological changes and display cytopathic effects, leading to cell death &#8212; cells detach from the microelectrode surface, decreasing the impedance over time.
Determine the time taken for the impedance to reduce to half the initial impedance before virus addition. A shorter time frame suggests a higher multiplicity of viral infection.

impedance-based-cellular-assay-to-measure-multiplicity-infection

Universidad San Sebastian

Research

JoVE Encyclopedia of Experiments

Biological Techniques

Assay Techniques

Cell-based assays

115 次观看. 来源:Labadie， T. 等人，使用实时细胞分析监测流感病毒在宿主外的存活。J. Vis. Exp. （2021 年） 在本视频中，我们讨论了 CIT50 与病毒感染多样性之间的相关性。病毒感染的细胞表现出细胞病变效应，导致它们死亡并从金微电极上脱离，进而降低阻抗。 

视频: 基于阻抗的细胞检测法测量流感病毒感染的复数 - 概念

Impedance-based Real-time Measurement of Cancer Cell Migration and Invasion

Cancer arises due to uncontrolled proliferation of cells initiated by genetic instability, mutations, and environmental and other stress factors. These acquired abnormalities in complex, multilayered molecular signaling networks induce aberrant cell proliferation and survival, extracellular matrix degradation, and metastasis to distant organs. Approximately 90% of cancer-related deaths are estimated to be caused by the direct or indirect effects of metastatic dissemination. Therefore, it is important to establish a highly reliable, comprehensive system to characterize cancer cell behaviors upon genetic and environmental manipulations. Such a system can give a clear understanding of the molecular regulation of cancer metastasis and the opportunity for successful development of stratified, precise therapeutic strategies. Hence, accurate determination of cancer cell behaviors such as migration and invasion with gain or loss of function of gene(s) allows assessment of the aggressive nature of cancer cells. The real-time measurement system based on cell impedance enables researchers to continually acquire data during a whole experiment and instantly compare and quantify the results under various experimental conditions. Unlike conventional methods, this method does not require fixation, staining, and sample processing to analyze cells that migrate or invade. This method paper emphasizes detailed procedures for real-time determination of migration and invasion of glioblastoma cancer cells.

Cancer is a lethal disease due to its ability to metastasize to different organs. Determining the ability of cancer cells to migrate and invade under various treatment conditions is crucial to assessing therapeutic strategies. This protocol presents a method to assess the real-time metastatic abilities of a glioblastoma cancer cell line.&#160;

基于阻抗的癌细胞迁移和入侵的实时测量

Cancer arises due to uncontrolled proliferation of cells initiated by genetic instability, mutations, and environmental and other stress factors. These ...

科研

JoVE Journal

癌症研究

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.

实时检测和捕获共培养物中的侵袭细胞亚群

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 ...

A Real-time Potency Assay for Chimeric Antigen Receptor T Cells Targeting Solid and Hematological Cancer Cells

Chimeric antigen receptor (CAR) T-cell therapy for cancer has achieved significant clinical benefit for resistant and refractory hematological malignancies such as childhood acute lymphocytic leukemia. Efforts are currently underway to extend this promising therapy to solid tumors in addition to other hematological cancers. Here, we describe the development and production of potent CAR T cells targeting antigens with unique or preferential expression on solid and liquid tumor cells. The in vitro potency of these CAR T cells is then evaluated in real-time using the highly sensitive impedance-based xCELLigence assay. Specifically, the impact of different costimulatory signaling domains, such as glucocorticoid-induced tumor necrosis factor receptor (TNFR)-related protein (GITR), on the in vitro potency of CAR T cells is examined. This report includes protocols for: generating CAR T cells for preclinical studies using lentiviral gene transduction, expanding CAR T cells, validating CAR expression, and running and analyzing xCELLigence potency assays.

We describe a quantitative real-time in vitro cytolysis assay system to evaluate the potency of chimeric antigen receptor T cells targeting liquid and solid tumor cells. This protocol can be extended to assess other immune effector cells, as well as combination treatments.

Impedance-Based Cellular Assay to Measure Multiplicity of Infection of Influenza Virus

成績單

Impedance-Based Cellular Assay to Measure Multiplicity of Infection of Influenza Virus