• Unfeed newborn calves within 14 hours of birth
• 3 times filtered with 0.1um to remove bacteria, tested for comprehensive physical, chemical, microbiological indicators.
•  Pure domestic newborn bovine serum raw material, better than imported newborn bovine serum, cell culture effect and fetal bovine serum similar to conventional cell culture, non-delicate cell culture, tumor cell culture and so on.
• This product is divided into two directions: cell culture and diagnostic reagents, with different purposes and production processes.

Veridated culturable cells:

HEK293,293T,Vero,CHO,LLC,Hela,MDCK,Hybridoma cells, and mouse Tlymphocytes etc.

Example of applicable cells:

Various tumor cell lines, epithelial cells, fibroblasts, genetically modified cells, alloploid cells, etc

• This is high grade FBS,
• Widely used in a variety of cell cultures, including some stem cells, primary cells and other delicate cells.
• Blood was collected from the heart of fetal bovine at 6-8 months of gestational age.
• C + A class purification workshop automatic filling line production, batch 4000 bottles, batch difference is very small.
• After 0.1micron 3 times sterilization filtration, comprehensive physicochemical, microbial detection.
• Very low endotoxin, no mycoplasma, and no specific antibodies.

Veridated culturable cells:

HEK293,293T,293E, Vero, CHO, LLC, Hela Renal epithelial cells, primary B lymphocytes, etc

The MA900 from Sony Biotechnology is a powerful cell sorter designed to meet the demands of a wide range of research applications. With the ability to support 12 fluorescence parameters and facilitate 4-way sorting, the MA900 combines cutting-edge technology with intuitive design to streamline the cell sorting process. This system integrates modern advancements, such as a patented microfluidic chip, comprehensive fluidic controls, and advanced automation, to enhance the reliability and ease of use of cell sorting, making it less subjective and more consistent.

Flexibility with Up to 14 Parameters from 4 Lasers

One of the standout features of the MA900 is its ability to detect up to 14 parameters, offering researchers significant flexibility in experimental design. The system is equipped with four excitation lasers—488 nm, 405 nm, 561 nm, and 638 nm—arranged across two beam spots. This setup allows for the detection of up to 12 fluorescence parameters and two scatter parameters, enabling a comprehensive analysis of cell populations. The use of free-form PMTs (photomultiplier tubes) ensures that fluorescence signals from each beam spot are accurately detected, providing researchers with detailed and reliable data.

Automation Across the Workflow

The MA900 excels in automation, offering a streamlined workflow that minimizes the need for manual intervention. Key processes such as startup, aseptic cleaning, quality control (QC), and sort setup are all managed with the touch of a button, ensuring optimal daily alignment of the microfluidic chip to the lasers. This high level of automation not only simplifies the operation but also improves the consistency of results, as the system automatically handles precise targeting and quick recovery from clogs. The inclusion of wizard-based cleaning cycles further enhances ease of use, allowing users to customize maintenance routines for aseptic sorting.

User-Friendly Software for Seamless Operation

The software that drives the MA900 is designed with user experience in mind. It guides operators through every step of the sorting process, from system startup to data analysis, making it easy to learn and use. Advanced controls within the software enable customization, allowing researchers to focus on the biological aspects of their experiments rather than the intricacies of the cytometer. At startup, the software initiates connections between all subsystems and runs diagnostics to ensure everything is functioning correctly. Once verified, the system displays a green ready message on the LCD monitor, indicating that it is prepared for operation.

Automated Chip Loading and Positioning

Setting up the MA900 is a straightforward process, thanks to its automated chip loading and positioning features. With a single touch, the microfluidic flow cell chip is installed, and the setup wizard guides users through the selection of lasers and optical filters. The system’s actuators precisely position the chip within the loader, while patented CoreFinder™ technology automates key steps such as chip alignment, laser delay calculation, drop delay, side stream angle, and breakoff position. This automation ensures that the system is consistently aligned for optimal performance, reducing the potential for user error and enhancing overall reliability.

Customizable Cleaning Cycles

Maintenance of the MA900 is simplified through its wizard-driven cleaning cycles, which can be customized to meet the specific needs of different labs. Default cleaning cycles, such as those using bleach or ethanol, are available, and the software guides users through each step. For added convenience, administrators can set up cleaning reminders and customize protocols to define cleaning times. This ensures that the system remains clean and ready for use, reducing downtime and maintaining the integrity of the sorted samples.

Versatile Sorting Capabilities

The MA900 offers a variety of sorting options to suit different research needs. Once events are gated on plots, target cells can be sorted using one of eight default or five custom sort modes, which allow for varying levels of purity and yield. The system supports sorting into 2-way and 4-way tubes, as well as 6-, 12-, 24-, 48-, 96-, and 384-well plates. This versatility makes the MA900 suitable for a wide range of applications, from basic research to more complex sorting tasks that require high throughput and precision.

Experiment Settings and Data Analysis

Creating and managing experiments on the MA900 is straightforward, thanks to its user-friendly software. Researchers can choose from new templates, recent experiments, or shared (public) templates in the experiment window. Once a template is selected, the software guides users through the experiment settings, such as sample groups, tubes, and pulse parameters for data acquisition. The compensation wizard simplifies the process of acquiring compensation data, while the drag-and-drop feature allows for easy adjustment of uncompensated populations.

During data acquisition, information is displayed on worksheets as dot plots and histograms, with various tools available to select, adjust, label, and measure statistics of target populations. Once the data is collected, it can be easily exported in FCS formats for use with third-party analysis software. This seamless integration of data acquisition and analysis tools ensures that researchers can focus on their experiments without being bogged down by technical details.

Automated Sort Monitoring and High-Throughput Sorting

The MA900’s automated sort monitoring feature is designed to maintain consistent sort performance. The software continuously monitors and adjusts the drop drive to ensure a stable breakoff point, which is crucial for achieving reliable sorting results. This feature also supports walk-away operation, allowing researchers to focus on other tasks while the system operates independently. Additionally, the system is capable of detecting clogs and empty tubes, further enhancing its reliability.

For labs that require high-throughput sorting, the optional Sort Deposition System is an invaluable tool. This hardware feature facilitates the precise deposition of cells into 6-, 12-, 24-, 48-, 96-, and 384-well plates or PCR plates. The MA900’s advanced capabilities, such as precise plate positioning and custom angled plate holders, ensure that single cells can be deposited with high efficiency, making it ideal for applications such as genomics and single-cell analysis.

Index Sorting Software

The MA900 also includes powerful index sorting software, which records the X and Y coordinates of each event sorted into a multiwell device. This feature enables researchers to track the scatter and fluorescence intensity of individual cells sorted into each well, providing valuable insights into clonal variability and other aspects of cellular behavior. The index file can be exported in CSV format or analyzed directly on the cell sorter, offering flexibility in how data is managed and interpreted.

Biosafety Cabinet for Enhanced Protection

For labs working with biohazardous materials, the MA900 can be installed inside an optional custom Class A2 Level II biosafety cabinet. These cabinets, designed and tested by Sony Biotechnology’s manufacturers, meet international standards such as the National Sanitation Foundation Standard 49 (NSF49) and the European Standard 12469. The cabinets feature a built-in aerosol management system that operates independently to evacuate aerosols from the sort collection chamber, maximizing protection for both personnel and products.

Conclusion

The MA900 cell sorter from Sony Biotechnology is a versatile and powerful tool that meets the diverse needs of modern research labs. With its advanced automation, customizable sorting options, and comprehensive safety features, the MA900 simplifies the cell sorting process, allowing researchers to focus on the biological questions that matter most. Whether you’re conducting routine cell sorting or tackling complex, multi-parameter experiments, the MA900 provides the flexibility, reliability, and ease of use required to advance your research.

4o

The Sony SA3800 spectral cell analyzer represents a groundbreaking advancement in flow cytometry, integrating sophisticated electronics and patented optical technologies to deliver exceptional analytical performance. Designed to streamline the entire workflow, from instrument startup to system maintenance, the SA3800 offers unparalleled automation and simplicity, making it suitable for both seasoned experts and newcomers to flow cytometry.

Advanced Spectral Technology

At the core of the SA3800’s capabilities is its spectral analysis technology, which significantly enhances sensitivity and facilitates the detection of dim signals. By capturing photons across a broad wavelength range from 420 nm to 800 nm, the SA3800 optimizes the detection of fluorescent signals. This spectral approach not only improves sensitivity but also simplifies the design and analysis of multicolor applications. Unlike traditional flow cytometers that rely on color compensation to subtract overlapping fluorescence, the SA3800 employs spectral unmixing. This method combines the fluorescence data from all channels and then mathematically separates the colors, yielding clearer and more accurate data. This process simplifies workflow, improves the visualization of autofluorescence, and enhances overall data quality.

Innovative Optical Technologies

The SA3800 features a unique prism-based collection system that directs emitted light to a 32-channel photomultiplier tube (PMT). This setup allows for the detection of 34 data points, capturing a comprehensive spectral fingerprint of each fluorochrome. The result is precise and accurate visualizations of fluorescent populations, providing researchers with detailed information about each marker’s spectral characteristics.

Spectral Unmixing

One of the standout features of the SA3800 is its ability to perform spectral unmixing. This powerful capability allows for the separation of overlapping fluorophores into pure signals, enabling more accurate measurement of each fluorochrome. Unlike conventional systems where overlapping signals can obscure data, spectral unmixing captures the full range of emitted photons, enhancing the detection of dim signals and rare populations. This technique also effectively handles autofluorescence by isolating and subtracting it from the signal, resulting in cleaner and more reliable data.

Automated Workflow

Automation is a key aspect of the SA3800, ensuring a streamlined and accurate workflow. The system is designed to handle a variety of standard and deep-well plates, as well as 12 x 75-mm 5-mL tubes. The novel 3D AutoSampler technology further enhances efficiency by moving the sample plate in both horizontal and vertical directions. This reduces sample-to-sample cross-contamination and speeds up cleaning processes. The fixed probe, combined with sensors that calculate the height of the sample container and automatically adjust for any contact, minimizes the risk of cross-contamination and flow problems, ensuring a reliable and consistent sample acquisition process.

User-Friendly Software

The SA3800 is equipped with intuitive software that simplifies every aspect of operation. From setup and panel design to data acquisition and analysis, the software provides step-by-step guidance. The user interface allows for customization of instrument settings and experiment configurations, accommodating both novice and experienced users. Key features include the Experimental Designer, which assists in creating experiments, and the Spectral Library, which facilitates the management of reagent data for future use.

System Standardization

The SA3800 includes a novel standardization feature that automatically sets the system to a master specification with a single click. This function eliminates variability between instruments, ensuring consistent and reliable results across different setups and locations. By reducing the potential for setup subjectivity, the standardization mode supports collaborative research and long-term studies, providing accurate and reproducible data regardless of operator experience.

Efficient Sample Acquisition and Analysis

The system’s software supports a range of acquisition functions, including the ability to control instrument settings and adjust acquisition speeds. The Walk Away Event Checker monitors the integrity of the sample stream, detecting issues such as air bubbles or low event rates, and can automatically clear clogs or continue to the next sample. The Autofluorescence Finder feature helps identify and subtract autofluorescent signals, ensuring that researchers obtain accurate representations of their fluorescent populations.

FCS Express Integration

The SA3800 comes with fully integrated FCS Express™ software from De Novo Software, providing advanced analysis tools for detailed data interpretation. This software supports a range of functions, including live gating, spectral overlays, tSNE, Spade, and heat maps. Live gating enables users to quickly and accurately identify positive and negative populations, enhancing the reliability of target population detection.

System Shutdown and Maintenance

At shutdown, the SA3800 software guides users through pre-cleaning procedures and automatically shuts down the instrument. The system also includes software wizards for bleach cleaning and rinsing, ensuring that the instrument is properly maintained and ready for future use.

In summary, the Sony SA3800 spectral cell analyzer stands out for its integration of advanced spectral technology, robust automation, and user-friendly software. Its ability to handle complex multicolor workflows with precision and ease makes it an ideal choice for research facilities seeking a high-performance, versatile analyzer. By combining cutting-edge optical technologies with comprehensive automation and intuitive software, the SA3800 offers a powerful solution for cellular acquisition and analysis, facilitating groundbreaking research in cellular biology.

4o mini

Innovative Design for GMP Compliance

One of the key advantages of the CGX10 Cell Isolation System is its fully closed design, which is essential for maintaining GMP compliance during cell production processes. Traditional flow cytometers, which have been widely used in research laboratories and early-phase clinical studies, often fall short in GMP environments due to their complex design and the potential for inducing stress or damage to sorted cells. The CGX10 overcomes these limitations by providing a robust, closed system that minimizes the risk of contamination and ensures the highest cell viability during the sorting process. This makes it an ideal choice for environments where strict regulatory standards must be met.

Superior Cell Isolation with Multi-Marker Selection

The ability to isolate cells based on multiple biomarkers is a crucial feature of the CGX10 system. In cell and gene therapies, it is often necessary to identify and isolate specific immune cells that exhibit the desired phenotype, which may be defined by the presence of one or more biomarkers. Multi-marker-based cell isolation not only enhances the purity of the isolated cells but also allows for the selective elimination of non-target cells, such as over-differentiated T cells, which may be therapeutically ineffective. By ensuring that only the most relevant cells are selected, the CGX10 improves the overall efficacy of cell-based therapies.

In contrast to traditional flow cytometers, which are typically limited in their ability to handle complex multi-marker sorting in a GMP setting, the CGX10 is designed to excel in these environments. Its advanced technology allows for precise, high-purity isolation of target cells while maintaining their viability, making it a critical tool for researchers and manufacturers involved in the development of advanced therapy medicinal products (ATMPs), including cell and gene therapies.

Streamlined Operation for Efficient Cell Production

Ease of operation is another hallmark of the CGX10 Cell Isolation System. The system is designed to provide a seamless user experience, making it accessible to trained laboratory technicians who may not have specialized expertise in flow cytometry. This is particularly important in GMP-compliant environments, where the complexity and subjectivity of conventional sorter platforms can be a significant barrier to efficient cell production. The CGX10 simplifies the cell isolation process, reducing the need for extensive operator training and minimizing the potential for user error.

The system’s intuitive interface and automated processes allow for a smooth transition from process development to full-scale cell production. This flexibility is essential for laboratories and manufacturing facilities that are scaling up their operations to meet the growing demand for cell-based therapies. By streamlining the workflow, the CGX10 enables researchers and manufacturers to focus on the critical aspects of their work, such as optimizing cell culture conditions and ensuring the quality of the final product.

Application in Advanced Cell and Gene Therapies

The CGX10 Cell Isolation System is specifically designed for use in research, process development, and manufacturing environments related to advanced therapy medicinal products (ATMPs), including cell and gene therapies. These fields have seen significant progress in recent years, driven by the need to develop more effective treatments for a range of diseases. The ability to isolate specific cell populations with high precision is a key factor in the success of these therapies, and the CGX10 provides the tools needed to achieve this.

It is important to note that the CGX10 and its related products are intended for ex vivo cell separation processing only. They are not designed for therapeutic, diagnostic, or in vivo applications in humans. Any clinical use of the cells processed with the CGX10 must adhere to the relevant regulations, and it is the responsibility of the user to ensure compliance with these standards. The CGX10 system is not sold as a medical device, and its use in clinical applications is subject to the appropriate regulatory approvals.

Ensuring the Highest Standards of Cell Production

In the context of GMP-compliant cell production, the CGX10 Cell Isolation System offers unparalleled reliability and performance. Its closed design, multi-marker selection capabilities, and user-friendly operation make it an ideal choice for laboratories and manufacturing facilities that require precise, high-purity cell sorting. As the demand for cell and gene therapies continues to grow, the CGX10 provides the flexibility and efficiency needed to support the development of these innovative treatments.

Moreover, the system’s ability to maintain high cell viability throughout the sorting process is crucial for the success of cell-based therapies. By minimizing the potential for stress or damage to the sorted cells, the CGX10 ensures that the final product is of the highest quality, which is essential for both research and clinical applications. This makes the CGX10 an invaluable tool for advancing the field of regenerative medicine and for bringing new therapies to market.

Conclusion

The CGX10 Cell Isolation System represents a significant advancement in the field of cell sorting and isolation, particularly in the context of GMP-compliant environments. Its fully closed design, multi-marker selection capabilities, and streamlined operation set it apart from traditional flow cytometers, making it the ideal choice for laboratories and manufacturing facilities involved in the development of advanced cell and gene therapies. As the only fully closed system available for GMP-compliant cell production, the CGX10 offers the reliability, flexibility, and ease of use needed to support the growing demand for high-quality cell-based therapies.

In summary, the CGX10 Cell Isolation System is not just a tool for cell sorting; it is a comprehensive solution for researchers and manufacturers working at the forefront of regenerative medicine. With its ability to deliver high-purity, viable cells in a GMP-compliant environment, the CGX10 is poised to play a crucial role in the advancement of cell and gene therapies, ultimately improving patient outcomes and driving innovation in the field of medicine.

Unparalleled Spectral Technology for Advanced Sorting

At the heart of the FP7000 is Sony’s patented spectral technology, which sets it apart from conventional flow cytometry and cell sorting systems. Unlike traditional systems that rely on specific optical filters for each fluorochrome, the FP7000 employs spectral technology that captures the entire emission spectrum of each fluorochrome, enabling the detection of more than 44 colors simultaneously. This capability is further enhanced by the system’s ability to detect autofluorescence signals from 6 lasers—ranging from ultraviolet to near-infrared wavelengths. The FP7000 is equipped with 182 photomultiplier tube (PMT) detectors, ensuring comprehensive data acquisition and enabling researchers to analyze complex cell populations with high precision.

The system’s optical capabilities are closely aligned with Sony’s ID7000™ Spectral Cell Analyzer, allowing for smooth assay transfer between analysis and sorting. This feature is particularly beneficial for researchers who need to replicate their analyses on different instruments, ensuring consistency and reliability in their experiments. The FP7000’s optical system is also capable of detecting particles as small as 100 nanometers, making it suitable for a wide range of applications, from basic research to clinical diagnostics.

High-Performance Sorting for Diverse Applications

One of the standout features of the FP7000 is its high-speed, real-time spectral unmixing capability, which allows for the simultaneous detection and sorting of cell populations at rates of up to 25,000 events per second. This high throughput is achieved without compromising accuracy, thanks to the system’s patented unmixing algorithm. This algorithm is designed to resolve closely spaced fluorochromes with exceptional precision, eliminating the need for traditional compensation techniques, which can be subjective and prone to error. As a result, the FP7000 produces high-quality, reproducible data that is essential for complex multicolor experiments.

The FP7000 supports a wide range of nozzle sizes, which can be easily interchanged to accommodate different cell types and sorting requirements. This flexibility is crucial for researchers working with diverse samples, as it allows for optimized sorting conditions tailored to the specific needs of each experiment. The system’s sheath excitation technology ensures robust operation across different nozzle sizes, forming stable droplets at frequencies ranging from 12kHz to 100kHz and at pressures between 70 kPa and 600 kPa. This versatility enables the FP7000 to perform both bulk sorting into tubes and high-precision single-cell sorting into multiwell plates, making it suitable for a variety of downstream applications.

Automation and Workflow Integration

The FP7000 is designed with automation in mind, making it accessible to researchers of varying expertise levels. One of the key features of the system is the CoreFinder™ algorithm, which automates several critical steps in the sorting process. This includes optical alignment, laser delay optimization, droplet calibration, sort delay optimization, and side stream adjustment. By automating these processes, the FP7000 eliminates the subjectivity associated with manual adjustments, ensuring consistent performance and reducing the likelihood of operator error. This automation not only streamlines the workflow but also significantly reduces the time required for instrument setup, allowing researchers to focus on their experiments rather than on the technical aspects of the sorter.

In addition to CoreFinder™, the FP7000 features guided workflows that further simplify the operation of the system. These workflows include the Spectral Reference Library, which provides a comprehensive database of spectral signatures for commonly used fluorochromes. This library can be used to streamline the setup of experiments, making it easier for researchers to select the appropriate settings for their specific applications. The system also includes an autofluorescence unmixing feature, which enables the identification and removal of autofluorescence signals from the data. This is particularly important when working with heterogeneous samples that may contain cells or particles with high autofluorescence, as it improves the resolution of dim signals and enhances the overall quality of the data.

Real-Time Data Analysis and Flexibility

The FP7000 is not only a powerful sorter but also an advanced analytical tool. The system’s real-time spectral unmixing capability allows for the live analysis of data as it is being acquired, providing researchers with immediate feedback on their experiments. This real-time analysis is complemented by the system’s ability to perform 6-way sorting, which enables the isolation of multiple cell populations simultaneously. This feature is particularly useful for researchers who need to sort complex samples into multiple subsets for downstream applications, such as single-cell sequencing or functional assays.

The system’s flexibility extends to its data output formats, which are compatible with a wide range of third-party analysis software. This ensures that researchers can easily integrate the FP7000 into their existing workflows without the need for extensive reformatting or data conversion. The FP7000’s user-friendly interface and intuitive software design make it easy to learn and use, even for those with limited experience in spectral cell sorting. The software includes customizable wizards and guided protocols that assist users in setting up experiments, performing routine maintenance, and troubleshooting common issues.

Meeting the Needs of Modern Laboratories

The FP7000 Spectral Cell Sorter is designed to meet the diverse needs of modern laboratories, from basic research to complex, high-parameter applications. Its combination of advanced spectral technology, high-performance sorting, and automated workflows makes it an indispensable tool for researchers seeking to push the boundaries of cell sorting and analysis. Whether you are working with simple two-color assays or complex panels with more than 44 colors, the FP7000 provides the reliability, precision, and flexibility needed to achieve your research goals.

In conclusion, the FP7000 Spectral Cell Sorter represents a significant advancement in the field of flow cytometry and cell sorting. With its unparalleled spectral technology, robust performance, and user-friendly design, the FP7000 is well-equipped to handle the most demanding sorting applications, making it a valuable asset for any laboratory. Whether you are conducting basic research or pursuing cutting-edge applications, the FP7000 provides the tools and capabilities needed to deliver high-quality, reproducible results with confidence.

Live cell imaging is particularly well-supported by the CELENA® S, which offers a dedicated time-lapse mode for observing live cells in a controlled environment. This mode allows researchers to monitor cellular processes over time and generate time-lapse videos complete with annotations. The system’s onboard data analysis tools enable users to measure and annotate images directly, with data easily saved either to the system’s onboard storage or exported via a USB drive. For detailed imaging of cellular structures, the CELENA® S provides Z-stack imaging capabilities, allowing users to capture multiple focal planes and either stack them into a single composite image or compile them into a video for comprehensive analysis.

The CELENA® S is highly versatile and customizable, accommodating a wide range of imaging needs. It features an onstage incubation system that maintains precise control over the imaging environment, including temperature, humidity, and gas composition. The temperature controller separately heats the plate and lid of the stage incubator to prevent condensation and ensure accurate temperature regulation. Additionally, the CELENA® S offers a selection of interchangeable filter cubes and objectives, including over twelve hard-coated LED fluorescence filters and infinity-corrected objectives with magnifications ranging from 1.25X to 100X. A range of vessel holders and LED filter cube options are available to tailor the system to specific experimental needs, making the CELENA® S an adaptable and powerful tool for diverse cell imaging applications.

The CELENA® X excels in fully automated plate and slide imaging, featuring automated vessel handling and scanning through a motorized XYZ stage, filter cube stage, and objective turret. Its laser autofocus ensures rapid, reproducible focusing while minimizing phototoxicity and photobleaching, which is crucial for maintaining cell viability during imaging. For live cell assays, the onstage incubation system provides precise control over physiological and non-physiological conditions, supporting a variety of experimental setups. The system supports four imaging modes: fluorescence in four channels, brightfield, color brightfield, and phase contrast, accommodating diverse imaging needs and experimental requirements.

The CELENA® X’s powerful and user-friendly software interface simplifies the setup of imaging protocols and integrates seamlessly with data analysis processes. Its customizable high content analysis capabilities allow for the creation of tailored workflows that can handle both straightforward fixed cell assays and complex, time-lapse live cell assays. The system supports a wide array of applications, including cell counting, cytotoxicity assays, transfection efficiency, wound healing, apoptosis, confluency, calcium signaling, phagocytosis, cell cycle analysis, stitching, and 3D cell modeling. The CELENA® X is designed to be versatile and adaptable, with comprehensive vessel holder options, objective selection guides, and LED filter cube guides available to ensure that the system meets all of your cell imaging needs.

In the fast-paced world of cell biology, the ability to sort cells with precision and efficiency is crucial for advancing research. The SH800S Cell Sorter, a benchtop system designed with cutting-edge technology, offers researchers unparalleled flexibility and ease of use. Whether you’re working in an individual lab or a core facility, the SH800S adapts to a wide range of applications, making cell sorting more accessible and less complex.

Advanced Microfluidic Chip Technology

At the heart of the SH800S is its innovative microfluidic sorting chip, which comes in three sizes: 70 μm, 100 μm, and 130 μm. This versatility allows researchers to sort cells of varying sizes, catering to the specific requirements of different experiments. The chip-based design integrates seamlessly with the system’s fluidics controls, ensuring precise and consistent results. With the SH800S, the days of subjective and error-prone sorting are over. The system automates key steps, from setup to analysis, providing a level of precision that manual methods simply can’t match.

Intuitive System Software

The SH800S’s software is designed with the user in mind, featuring an intuitive interface that simplifies the entire sorting process. Researchers can sort cells into tubes, 96-well plates, or even 384-well plates with ease. The software supports the export of FCS 3.0 and FCS 3.1 files, which can be analyzed using third-party tools, ensuring that data can be easily integrated into existing workflows. The system’s flexibility is further enhanced by the option to use e-beam sterilized consumables, which replace the sample line and sorting chip, reducing the risk of cross-contamination—an essential feature for applications where sterility is paramount.

Comprehensive Biosafety Solutions

Safety is a top priority in any lab, and the SH800S addresses this with an optional Class A2 Level II biosafety cabinet. This cabinet, custom-designed for the SH800S, has been rigorously tested by The Baker Company to meet international biosafety standards, providing protection for both personnel and samples. This integration ensures that the SH800S can be used in a wide range of environments, including those where biohazardous materials are handled.

Flexible Optical Design for Diverse Applications

The optical design of the SH800S is another standout feature, offering up to four collinear excitation lasers (488 nm, 405 nm, 561 nm, and 638 nm) and six fluorescence detectors. This configuration allows for the detection of a broad range of fluorescence signals, giving researchers the flexibility to design experiments according to their specific needs. The six free-form PMTs enable the detection of signals from any laser, based on the selected filters, providing further customization options.

Unmatched Automation and Ease of Use

One of the most significant advantages of the SH800S is its high level of automation. Researchers can set up, calibrate, and monitor the system with just the push of a button, streamlining the workflow and reducing the potential for human error. The system’s patented CoreFinder™ technology plays a critical role in this automation, guiding users through the process of loading the sorting chip, selecting lasers, and inserting the required optical filters. The fluidics check ensures that the system is ready for operation, and the auto-calibration feature aligns the sorting chip with the lasers, calibrates the droplets, and estimates the drop delay using AutoSetup beads.

User-Friendly Data Analysis

Data analysis is a crucial aspect of cell sorting, and the SH800S makes this process straightforward. Data is displayed as dot plots and histograms, allowing researchers to gate events and mark target populations easily. The software provid