Our high-content imaging (HCI) systems offer adaptable scalability, ensuring seamless alignment with the progression of your research. These systems empower comprehensive cellular imaging of a wide variety of samples, encompassing live cells, stem cells, plants, tissue slices, whole organisms, and intricate 3D organoids. Leveraging cutting-edge software solutions, our platforms facilitate robust image and data analysis with powerful tools. At the same time, their flexibility and scalability cater to a diverse range of assays for comprehensive screening capabilities.
Features
Essential Features of the Live Cell Analyzer
- The image analysis solution excels in performance, utilizing cutting-edge techniques and impressive optical resolution to capture dynamic biological processes with precision and clarity, enhancing analysis workflows.
- The exceptional quality and remarkable spatial resolution ensure accurate and reliable results across diverse imaging applications.
- Built to last, the durability of the live cell analysis system guarantees consistent and long-lasting high-resolution optical performance.
- With extensive customization and automation options, this live cell imaging solution seamlessly adapts to specific research needs.
- Furthermore, its compatibility with a wide range of complementary products and technologies enhances experimental possibilities, providing a comprehensive imaging solution.
Applications
Applications of the Live Cell Analysis System
- Cytotoxicity assessment using automated imaging and live/dead assays allows for comprehensive evaluation of cell health and viability, as well as gaining insights into cellular functions.
- In cancer research, imaging and analysis of cancer spheroid cultures using 3D cell culture imaging enable the comprehensive study of the effects of potential cancer therapeutics on tumor behavior, accelerating advancements in oncology.
- This can aid in the development of monoclonal antibodies (mAbs) through targeted cell line engineering, followed by rigorous antibody screening and bioassay screening for activity testing.
- Leveraging advanced cellular imaging, scientists can expedite cell line development and evaluate the impact of antisense oligonucleotide interventions. This enables accurate visualization and analysis of gene expression modulation within engineered cell lines, thereby streamlining the process of antisense oligonucleotide development.
- Researchers can achieve accurate quantitation of fluorescent proteins using cell fluorescence imaging, enabling the quantitative analysis of protein expression levels and dynamics within live cells.
FAQs
What does 3D imaging mean for cancer drug discovery?
3D live cell imaging transforms cancer drug discovery by offering a true-to-life portrayal of tumor dynamics in complex three-dimensional settings, allowing researchers to precisely evaluate drug interactions with cancer cells and their microenvironment, thereby advancing the efficacy and efficiency of identifying promising therapeutic candidates.
Which system is used for live cell imaging?
Our cellular imaging systems are used for high-resolution live cell imaging, enabling researchers to visualize and analyze dynamic cellular processes with precision, driving advancements in life sciences research.
What are the benefits of live cell imaging in research?
Live cell imaging offers real-time insights into dynamic cellular processes, enabling the observation of physiological responses, kinetics, and interactions, thus enhancing our understanding of complex biological phenomena and facilitating advancements in various research fields.
How to select which cell imaging to use?
Selecting the appropriate cell imaging involves considering factors such as the research objectives, imaging modalities required (e.g., fluorescence, confocal, live cell imaging), resolution needs, sample compatibility, throughput, automation capabilities, software analysis tools, and budget constraints, to ensure that the choice aligns with the specific experimental goals and technical requirements.
What are the two different categories of cell imagers with advanced imaging techniques?
Automated Cell Imager: This 3D cell imaging system empowers researchers to access the benefits of automated imaging and analysis of images, ensuring enhanced laboratory automation and simplified remote access to cope with the ever-changing research environment.
High-content imaging (HCI) system: This image acquisition system is utilized to screen numerous cells with high precision, enabling the detection of subtle variations in morphology and phenotypic traits.