Make informed decisions about your cultures, rapidly optimize and improve your workflows, plus study complex live-cell assays to fast track your next discovery! 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. With advancements in modern high-resolution imaging techniques and the synthesis of fluorescent probes, it is now possible to view labeled sub-cellular structures at the nm scale. The Incucyte® Live-Cell Analysis System automatically monitors cells for days, weeks or even months as they sit stationary in the stable tissue culture incubator environment. Get answers to the most common questions about about Sartorius image and analysis solutions including critical information regarding instruments, applications, software, service, and more. Making advanced live-cell imaging technology accessible to all researchers is of critical importance.
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- We are at a very exciting time in the world of science thanks to the advancement of AI software and the utilization of patient-derived samples.
- Easy-to-use software to support all scientists across variety of cell models – turn complex assays into reliable and objective publication-ready data
- As such, it becomes easier to target internal cellular structures with dyes and antibodies.
- 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.
- 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.
These systems typically do not sit within a tissue culture incubator and so are limited in terms of environmental stability and long-term studies. As such, it becomes easier to target internal cellular structures with dyes and antibodies. The fixation process kills the cells, which makes the outside cell membrane more permeable than living cells. While cellular composition is compromised, larger structures such as proteins, organelles and DNA are conserved. Fixed cells have been preserved by a fixation step that “locks” the cell in place.
Which is preferred – studies with live or fixed (dead) cells?
The integration of 3D cell culture further enhances this approach by mimicking the structural complexity of living tissues, offering deeper insights into development, disease, and therapeutic response. Live-cell imaging has become essential for studying the goatz casino no deposit bonus dynamic biology of living cells. Make new discoveries with a wide range of applications — from complex immune-tumor cell interactions, synaptic activity in neuronal co-cultures, metabolism in cancer cells, and much more.
- Maintain your cell health with non-perturbing image-based analysis and proprietary reagent formulations.
- Regular media exchanges every 2-3 days for long assays are essential, unless restricted by the assay.
- 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.
- Cell density should be optimized to prevent contact inhibition, and cells should be allowed to settle post-seeding for even distribution.
- 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.
- Long-term imaging can introduce various artifacts, such as phototoxicity and photobleaching, which can affect cell behavior and data quality.
- Traditional end-point assays only provide single measurement of cellular events.
Live-Cell Imaging and Analysis Applications
Request a complimentary sample of our ready-to-use transfection reagents for life science research involving most mammalian cell lines. Accelerate your next discovery with Incucyte’s® suite of live-cell applications. Reagents have been optimized for each application allowing easy assay preparation and intuitive software that guides the user through each step. These systems again lack proper environmental controls which will impact long-term studies. With increasing technical advancements comes increased complexity and costs; high-resolution microscopes often require extensive training and access is often limited. The timing of adjunct studies such as analysis of metabolites or secreted proteins in supernatants can also be guided.
Live-Cell Imaging and Analysis Handbook
Proper image optimization reduces noise and enhances the signal, making it easier to extract quantitative information from the images. This optimization process is crucial for obtaining clear and accurate images that can be reliably analyzed. A well-defined experimental plan ensures that the study is focused and that the data collected is relevant and meaningful.
Compare Incucyte® Live-Cell Analysis Systems
Imaging fixed cells allows high-resolution imaging of sub-cellular structures. See how your peers are using live-cell imaging and analysis Live-cell imaging continues this legacy by providing deeper insights into cellular processes, leading to advancements in medical research and biotechnology.
The integrated software simplifies data analysis to accelerate response time, including the creation of publication-quality graphs and charts. Capture high-resolution fluorescence and brightfield images, recording data in real-time over hours, days, or weeks. Cells are dynamic in nature, so it is important to have the ability to image in real time to gain access to deeper biological insights. Traditional end-point assays only provide single measurement of cellular events. Live-cell imaging and analysis should be used when studying any area of cell therapeutics.
To ensure accurate representation of cellular dynamics, it's important to optimize acquisition speed, resolution, and time intervals based on the specific biological phenomena being studied. However, over-collection of images can lead to excess data, increasing processing time and storage demands without necessarily enhancing biological insight. The ability to quickly capture images is crucial for studying fast kinetics in cellular activities.
The goal of this content is to serve as a resource for anyone wanting to learn more about long-term, live-cell imaging. Explore the resources below to learn more about how live-cell analysis outperforms other methods. Generate data rich information from every sample with fluorescent reagent combinations – compatible with a variety of cell culture models and applications Spend more time investigating and less time troubleshooting with lab-tested protocols and purpose-built, intuitive software Unlock 3D biology with ease using intuitive software and automated processes to acquire and analyze complex biology
The content of our website is always available in English and partly in other languages. See how the Incucyte® can support your research needs, from setting up an assay to analyzing and exporting your data. Incucyte® S3 shares the same highest maximum throughput as the Incucyte® SX5 but supports only the phase channel as well as green and red fluorescence. For the Incucyte® S3, an incubator larger than 200L is recommended.
Automated systems in live-cell analysis streamline image acquisition and processing, enabling efficient, accurate, and reproducible results. Fluorescence microscopy systems are designed to acquire images at high speeds, enabling researchers to observe rapid changes and dynamic processes in real-time. By tagging specific molecules with fluorescent markers, researchers can track their movement, concentration, and interactions within the cell, providing valuable data for understanding cellular mechanisms. The ability to selectively label and visualize specific molecules provides valuable insights into cellular processes that would otherwise be invisible. Efficient data management systems and advanced analytical tools are essential to handle this influx of information, enabling researchers to extract meaningful insights without being overwhelmed by the data.