Live Cell Imaging & Analysis

As we continue to push the boundaries of what is possible with live-cell imaging, we move closer to a future where we can predict and treat diseases with unprecedented precision and efficacy. The future of live-cell analysis promises even greater advancements, driven by AI, 3D sample analysis, and increased accessibility, paving the way for personalized medicine and improved healthcare outcomes. Live-cell imaging is a powerful tool in cell biology, offering unique advantages and presenting specific challenges. By leveraging innovative imaging and cutting-edge analysis techniques, we can move towards personalized medicine, where treatments are tailored to the individual needs of each patient. The ultimate goal is to use live-cell analysis to determine what treatment will effectively cure a patient’s disease.
With the insights gained from Incucyte® assays, you can make informed decisions, quickly optimize workflows, and efficiently study complex live-cell assays to accelerate your next discovery. From proliferation assays to the immunological killing of tumor spheroids, this flexible system allows users to observe and quantify complex biological changes in real-time. These advanced devices allow you to analyze your cells for days, weeks or even months as they sit stationary in the stable environment of your tissue culture incubator Power your research with the Incucyte® platform of real-time live cell analyzers.

Incucyte® Live-Cell Analysis System Supported Vessels List

In the pursuit of biologically relevant insights, the Incucyte® Live-Cell Analysis Systems empower scientists with simple workflows, powerful software, and unmatched throughput. Additionally, multiple assays can be run and imaged in different channels in parallel. Explore more than 50 reagents, kits and consumables developed for apoptosis, cytotoxicity, immune cell killing, neurite analysis, proliferation, tumor…

What is live-cell imaging and analysis?

This capability is essential for capturing transient events and understanding the temporal dynamics of cellular functions. Fluorescence microscopy allows for precise quantitative measurements of various cellular processes. This results in high-contrast images that clearly delineate different structures within the cell, making it easier to study their interactions and functions. Fluorescence microscopy enhances the visibility of cellular components by using fluorescent dyes or proteins that emit light when excited by specific wavelengths. Long-term live-cell imaging often involves repetitive tasks that can be efficiently managed through automation. Advanced environmental chambers and incubators are essential for creating stable and consistent conditions that support long-term cell culture.

• Maintain your cell health with non-perturbing image-based analysis and proprietary reagent formulations.
• Many technologies such as multi-mode readers and high-content imagers do not have the ability to maintain environmental control, meaning cells are not kept at physiologically relevant conditions.
• Traditional end-point assays only provide single measurement of cellular events.
• Cell density should be optimized to prevent contact inhibition, and cells should be allowed to settle post-seeding for even distribution.
• Long-term imaging can introduce various artifacts, such as phototoxicity and photobleaching, which can affect cell behavior and data quality.

What methods and techniques are available for live-cell imaging?

From the moment cells are placed in culture the learning opportunity begins. Gain real-time morphological and phenotypic insight for pathway and mechanistic studies by capturing time-dependent and cell-dependent treatment effects. An imaging system within the multi-mode reader can also image wells during the assay.
If imaged over time, real-time dynamic data can be collected and events that could be missed with endpoint, fixed cell assays are captured. However, fixed (dead) cells cannot provide dynamic insights into biological function and do not represent living systems. Efforts to reduce the cost and complexity of live-cell imaging systems, along with the development of user-friendly software, will help to make these technologies more widely available. This will provide more comprehensive insights into cellular behavior and interactions within complex tissue structures. High-resolution images provide more detail but may require longer exposure times, which can be harmful to cells. These systems use high-definition microscopy to capture detailed, time-lapse images of cellular processes while incorporating features like noise reduction and artifact correction to improve image quality.
More challenges arise when considering the complexity that automation and incubation, which are critical for long-term live-cell imaging, add to the process. Live-cell imaging of T cells engineered to target and kill GFP labelled tumor cells. As research demands grow, high-throughput, automated live-cell analysis helps streamline workflows, reduce errors, and improve data reliability.
Regular media exchanges every 2-3 days for long assays are essential, unless restricted by the assay. This ensures that the data collected is of high quality, reducing the need for extensive post-processing and increasing the reliability of the results. By controlling these variables, researchers can ensure that their findings are more reliable and reproducible, leading to more robust scientific conclusions.

Live-Cell Imaging and Analysis Applications

Live-cell imaging can provide real-time insights into how a patient's cells respond to different treatments, enabling the selection of the most effective therapy. Robotic systems can handle tasks such as media changes, cell feeding, and image acquisition, ensuring consistency and providing researchers the bandwidth to focus on data analysis and interpretation. Capture high-resolution fluorescence and bright-field images of 2D and 3D cell cultures in real time over hours, days, or weeks, directly from the incubator. Incucyte® devices for monitoring and analyzing live cells are designed for efficient recording of cellular changes in the incubator. Researchers can analyze a series of data-points over time, rather than a single time-point that does not provide the full picture of what their cells are doing.
The volume of data generated during long-term imaging experiments can be substantial, posing challenges in storage, processing, and analysis. Specialized software is vital for optimizing long-term live-cell imaging workflows. Careful optimization of imaging parameters and the use of advanced imaging techniques can mitigate these effects, preserving the integrity of the cells and the accuracy of the results. Long-term imaging can introduce various artifacts, such as phototoxicity and photobleaching, which can affect cell behavior and data quality. High-quality images are crucial for accurate analysis, as they provide clear and detailed visual information that can be quantitatively assessed. Continuous monitoring of live cells helps in identifying variables that could potentially confound the results.

Incucyte® S3 Applications

• Easy-to-use software to support all scientists across variety of cell models – turn complex assays into reliable and objective publication-ready data
• Fixed cells have been preserved by a fixation step that “locks” the cell in place.
• Fluorescence microscopy enhances the visibility of cellular components by using fluorescent dyes or proteins that emit light when excited by specific wavelengths.
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• Live-cell imaging and analysis is the combination of microscopy techniques and powerful analysis software that allows researchers to study spatio-temporal events within cells in real time.
• As such, it becomes easier to target internal cellular structures with dyes and antibodies.

These software solutions often include advanced features such as real-time image processing, customizable analysis, and detailed reporting tools. Purpose-built applications can integrate environmental monitoring, automated imaging, and data analysis, providing a seamless experience for researchers. Advanced imaging systems used in live-cell imaging are designed to minimize common issues such as focusing errors and image artifacts. Unlike single-timepoint assays, it enables real-time observation of health, behavior, morphology, and function as cells respond to their environment. The CX3 integrates confocal fluorescence imaging to enable comprehensive monitoring of multicellular 3D cell models throughout discovery and developme… This eBook explores biological live-cell imaging and analysis more deeply
This involves determining what specific cellular processes or behaviors will be observed and measured and establishing the criteria for success. Clearly defining the objectives and parameters of the study is the first step in setting up a live-cell imaging experiment. Surface coatings must be tailored to promote cell adhesion, and proper vessel handling, positioning, and condensation management are crucial for preventing image distortion. Cell density should be optimized to prevent contact inhibition, and cells should be allowed to settle post-seeding for even distribution.
Analyze the 3D maturation and 2D growth over time, capturing key biological processes like proliferation and morphological changes. Reduce photobleaching and phototoxicity with patent-pending compact spinning disk technology all while operating goatz casino no deposit bonus within the controlled environment of an incubator The Incucyte® CX3 Live-Cell Analysis System delivers cutting-edge capabilities for 3D cell culture applications. Live-Cell Imaging and Analysis – Real-time, Quantitative and Inside your Incubator Choose your preferred language and we will show you the content in that language, if available.

When is live-cell imaging and analysis used?

Discover how live cell imaging advances discovery with complex 3D cell models, ensuring artifact-free image acquisition and reliable insights. With continuous live-cell imaging and analysis, it is straightforward to temporally track network parameters and use the real-time data to judge when best to initiate treatment regimes. Live-cell imaging and analysis also provides the opportunity to make data driven decisions while the experiment is in progress. Live-cell imaging and analysis provides dynamic insights into the health, morphology, movement and function of cell models. The importance in live-cell imaging and analysis lies in the ability to resolve both spatial (through higher resolution) and temporal (through time-lapse imaging) information in cells.