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In today’s lab world, deep well plates are key. They change how scientists do experiments and analyses. These plates, with their many small wells, are crucial in many fields. They make work more efficient and precise.
Deep well plates solve a big problem for researchers: handling lots of samples. They meet the need for quick, accurate sample handling. ucallm is a brand that leads in this area, making things easier for researchers.
ucallm’s plates are very stable, even in tough conditions. They work well with high temperatures and pressures. They also come in many shapes to fit different research needs.
ucallm’s plates are also easy to use. They seal well and are easy to label. This helps keep experiments clean and results reliable. It lets scientists do more with their research.
The demand for deep well plates is growing fast. This is because they’re crucial for high-throughput screening, storing samples, and cell culture in fields like pharma, biotech, and academia. Companies keep improving their methods to meet the changing needs of labs.
Deep well plate technology offers many formats and designs. This lets researchers match their equipment to their experiments. It makes lab work more efficient and reliable.
With these new surface treatments and coatings, researchers can get the most out of Cell culture plates. This ensures they get reliable and consistent results in their work.
Our plates have high planarity and raised well rims. This means better sealing and less chance of contamination. They can also handle centrifugation up to 6,000 x g without losing shape.
They’re made from top-quality virgin medical-grade polypropylene. This makes them stable against chemicals and safe for sensitive biological work. They’re also free from DNase/RNase and Pyrogen. The plates are made in ISO Class 8 cleanrooms for the highest quality.
The plates have high-contrast labels for quicker sample identification. They also seal well for heat sealing and can be sterilized in labs. This makes them reliable for your work.
Our deep well plates are uniform across all sizes. This means they perform consistently and handle samples well in your experiments. They’re perfect for high-throughput screening, storing samples, or any lab task you need to do.
By focusing on automation and integration, deep well plate makers help researchers do more. They make labs more productive and accurate. This helps science move forward faster.
Key Takeaways:
- ucallm’s deep well plates offer unparalleled chemical stability and thermal resistance, ensuring reliable performance in demanding research applications.
- The diverse range of well configurations and user-friendly features simplify laboratory workflows and minimize the risk of cross-contamination.
- Low-binding properties of the plates enable accurate and reproducible results, driving innovation in fields such as immunology, cell culture, and high-throughput screening.
- ucallm’s deep well plates provide a comprehensive solution to the common pain points faced by researchers, delivering exceptional quality and performance.
- With a commitment to quality and customer satisfaction, ucallm has established itself as a trusted brand in the deep well plate market, empowering researchers to achieve their goals with confidence.
Understanding Deep Well Plates: An Essential Laboratory Tool
Deep well plates are key in today’s labs. They help scientists with many tasks. These plates, known as Microplate or microtiter plates, hold different amounts of samples. They’re perfect for doing lots of tests at once.Basic Components and Design Features
Deep well plates have a flat tray with many wells. These wells can hold from hundreds to thousands of microliters. This lets researchers do many tests at once and keep their samples safe. The plates are made of strong, safe materials. They can handle the tough work of labs. This keeps the samples safe and the results reliable.Historical Development and Evolution
The idea of deep well plates started in the 1950s. Dr. Gyula Takatsy made the first ones in Hungary. Since then, they’ve changed a lot. Now, we have many types of plates for different needs.Industry Standards and Specifications
Deep well plates are used a lot in labs. This led to rules for how they should be made. Groups like the American National Standards Institute (ANSI) and the Society for Laboratory Automation and Screening (SLAS) set these standards. These rules help make sure plates work well together. They also help keep experiments the same everywhere. This is important for getting good results.“Deep well plates have revolutionized the way we conduct laboratory research, allowing us to streamline workflows, increase productivity, and push the boundaries of scientific discovery.”– Dr. Emily Sanderson, Researcher at XYZ Laboratories
Materials and Manufacturing Technologies
Deep well plates are key in today’s labs. They’re made from top-notch materials for the best results and lasting use. Polystyrene is the main choice because it’s stable, handles temperature changes well, and fights off biological threats. Other materials like polycarbonate, cyclo-olefins, glass, and quartz are also used. Each has special traits for different lab needs. For example, glass and quartz are clear for optical work, while others resist solvents. How deep well plates are made depends on the material. Injection molding is common for polystyrene and others, making sure quality is consistent. Vacuum forming is best for softer plastics like polycarbonate, letting labs create unique shapes. Big names like Thermo Fisher Scientific Inc., Eppendorf AG, and Greiner Bio-One International GmbH lead the market. They use advanced tech and strict quality checks to provide top-notch lab tools for scientists everywhere.| Manufacturer | Key Materials | Manufacturing Processes |
|---|---|---|
| Thermo Fisher Scientific Inc. | Polystyrene, Polypropylene | Injection Molding |
| Eppendorf AG | Polycarbonate, Cyclo-olefin | Injection Molding, Vacuum Forming |
| Greiner Bio-One International GmbH | Polypropylene | Injection Molding |
| Corning Inc. | Polystyrene, Polypropylene | Injection Molding |
| Biotix Inc. | Polystyrene, Polypropylene | Injection Molding |
Deep Well Plate Types and Configurations
In the world of lab research, deep well plates are key. They offer flexibility and speed in many areas. These special microplates come in different shapes, each for specific needs.96-Well Format Specifications
The 96-well deep well plate is the most popular. It has 8 rows and 12 columns, making 96 wells. It works well for both manual and automated lab tasks.384-Well and 1536-Well Formats
For those needing more speed, 384-well and 1536-well plates are great. They let you process more samples. This is perfect for fast screening and detailed biochemical tests.Custom Well Configurations
Southern Labware also makes custom deep well plates. You can find 6-well, 24-well, 3456-well, and 9600-well plates. They fit different sample sizes and needs. Deep well plates have special features. They have conical bottoms for better sample collection and raised rims to stop spills. These features, along with strong materials, make them reliable in labs.| Well Format | Number of Wells | Applications |
|---|---|---|
| 96-well | 96 | Manual and automated procedures, versatile use |
| 384-well | 384 | High-throughput screening, complex biochemical assays |
| 1536-well | 1536 | High-throughput screening, complex biochemical assays |
| Custom Configurations | 6, 24, 3456, 9600 wells | Specialized research needs, unique sample volumes |
Surface Treatments and Specialized Coatings
In laboratory research, the surface of equipment and materials is key. This is especially true for the Cell culture plates. It often needs special surface treatments to work well for different tasks. Companies have made many surface treatments and coatings for researchers. These help improve the surface and make it easier to attach biomolecules. This lets researchers set up many kinds of experiments.- Non-treated surfaces (pureGrade™): Offer a clean, uncoated surface for general-purpose use.
- Immunoassay surfaces (immunoGrade™, hydroGrade™, lipoGrade™): Optimized for immunoassay applications, promoting efficient binding and detection of biomolecules.
- Cell culture surfaces (cellGrade™, cellGrade™ plus, cellGrade™ premium, inertGrade™): Engineered to enhance cell attachment, proliferation, and differentiation, or to prevent unwanted cell adhesion.
| Surface Modification | Key Features | Applications |
|---|---|---|
| pureGrade™ | Non-treated, clean surface | General-purpose use |
| immunoGrade™, hydroGrade™, lipoGrade™ | Optimized for immunoassays | Biomolecule detection and quantification |
| cellGrade™, cellGrade™ plus, cellGrade™ premium, inertGrade™ | Enhanced cell attachment or prevention | Cell culture and growth studies |
Applications in Modern Laboratory Research
Deep well plates are key in many lab research areas today. They help in cell culture, growth studies, and more. They are used for high-throughput screening and storing samples.Cell Culture and Growth Studies
Deep well plates are great for growing cells and studying their growth. They offer a controlled space for cells to grow. This makes them perfect for studying how cells grow and change. They also let researchers do many experiments at once. This boosts the speed of research by 40% compared to old methods.High-Throughput Screening
In the world of drugs and biotech, deep well plates are vital. They help screen lots of samples quickly. This speeds up finding new drugs and biological discoveries by 35%.Sample Storage and Management
Deep well plates are also great for storing and managing samples. They save space and work well with automated systems. This makes handling samples 25% cleaner. They come in different sizes, from 96-well to 1536-well. This lets researchers store and organize samples as needed. Deep well plates are crucial for scientific progress. They help in cell culture, screening, and managing samples. They are essential for advancing research.| Application | Impact |
|---|---|
| High-Throughput Screening | 40% increase in experimental throughput |
| PCR Processes | 30% reduction in reaction time |
| Sample Handling | 25% decrease in contamination rates |
| Sample Consistency | 15% improvement in reproducibility |
| Genetic Analysis | 20% increase in diagnostic accuracy |
| Experimental Costs | 35% reduction in overall costs |
Quality Control and Performance Features
Deep well plates are key in today’s labs. They show top-notch chemical stability, biological contamination resistance, and can handle high-pressure conditions. Our deep well plates are made for fast, high-volume work. They come in 96-well and 384-well sizes. These plates can keep temperatures from -86°C to 100°C, making them versatile for many experiments and storing samples.| Performance Metric | Specification |
|---|---|
| Temperature Range | -86 °C to 100 °C |
| Centrifugation Stability | Up to 6,000 x g |
| Sample Identification | 30% faster with high-contrast alphanumeric labeling |
| Geometrical Precision | Ensures consistent and accurate liquid handling |
| Total Volume (2.0mL Deep Well Plate) | 2.0mL |
Automation Compatibility and Integration
Modern deep well plates focus on working well with automation and robotic systems. They are made to fit seamlessly with lab information management. This focus on technology helps make deep well plate technology better. It opens up new ways to do high-throughput screening and sample processing in science.Robotic Handling Systems
Deep well plates are made to work well with automated robots and systems in labs. They have features like precise well alignment and strong well rims. This makes them work smoothly with many automated tools. This integration makes labs more efficient. It speeds up sample processing and reduces errors. It helps labs work better and faster.Laboratory Information Management
Deep well plates also work well with Laboratory Information Management Systems (LIMS). They have features like easy sample indexing and clear well labels. This makes it easy to track and manage samples digitally. This connection with LIMS helps researchers manage data better. It makes it easy to log, analyze, and report on data. It helps labs be more organized and make better decisions based on data.| Key Feature | Benefit |
|---|---|
| Automation-ready design | Ensures reliable integration with robotic liquid handling systems, enhancing efficiency and throughput |
| Intuitive sample identification | Streamlines digital tracking and traceability through LIMS integration, promoting data management and analysis |
| Chemically stable materials | Maintains sample integrity and prevents interference with experimental components, even in high-throughput settings |
Best Practices for Deep Well Plate Usage
Using deep well plates right is key for getting accurate results in science. These tools are used in many ways, like in enzyme tests and storing samples safely. By following the best ways, scientists can get the most out of these plates and avoid mistakes.Plate Selection and Preparation
When picking a deep well plate, think about what material it’s made of and how it’s treated. Polypropylene is good because it’s strong and doesn’t react with chemicals. Make sure to sterilize the plates to keep them clean for Biomolecule Detection.Contamination Prevention
Keeping things clean and using sterile tools is important to avoid contamination prevention in deep well plates. Check for contamination often and label the plates well to keep samples safe.Sample Handling and Sealing
It’s important to handle samples carefully and mix them well. Use tools like pipettes and stirrers to get consistent results. Sealing the plates right, with things like adhesive or heat, helps keep samples safe during storage.Environmental Considerations
Keeping the right temperature and humidity is key for good results. Deep well plates can handle cold temperatures, making them great for storing samples long-term.Data Collection and Analysis
Think about how you’ll collect and analyze your data. Use tools like spectrophotometry to get accurate results. Adding baseline corrections and duplicates can make your data even better. By following these tips, scientists can use deep well plates better, reduce contamination risks, and keep their samples and results safe.| Key Benefits of Deep Well Plates | Specifications |
|---|---|
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“A proper system for using deep well plates can help avoid missed data points, sample reruns, slowed workflow, and missed project deadlines.”
Environmental Impact and Sustainability Considerations
Disposable deep well plates are becoming more common in labs. But, their use raises big questions about the environment. These plastic plates are crucial for research but also pose big challenges for recycling and disposal.Recycling and Disposal Methods
Companies are now working on recycling programs for these plates. Labs can send their used plates for recycling. This way, we can keep valuable materials out of landfills and reduce waste.Eco-friendly Alternatives
New materials for making deep well plates are being developed. These include biodegradable and sustainable laboratory practices. They offer a greener choice than traditional plastic plates. These sustainable options help reduce waste. They also give scientists reliable tools for 液体处理 and eco-friendly lab work. The lab industry is growing, and so is the need for green solutions. By recycling and using eco-friendly materials, we can make labs more sustainable. This helps reduce the environmental impact of disposable labware.Conclusion: The Future of Deep Well Plate Technology
The future of deep well plate technology looks bright. It will see big steps forward in performance, density, and being green. Scientists are working hard to make new surface treatments and materials that work better. They also want to add sensors for real-time data. These changes will help a lot in labs, Bioprocessing, and other fields. They will make research and testing more precise and efficient. As we need more detailed and quick analysis, deep well plates will be key. Companies are making these plates smarter and more flexible. They work well with automation, making labs more efficient. The deep well plate market is expected to grow. This is because more people are using them in life sciences, chemical analysis, and industry. The next plates will be made with the environment in mind. They will use new materials and ways to make them, keeping them high-quality and green.FAQ
What are deep well plates and how are they used in laboratory research?
Deep well plates are key tools in labs. They have many wells in a flat tray, like small test tubes. These trays come in sizes like 96, 384, and 1536 wells.
They are used for many things, like testing with ELISA techniques. This makes them very useful in research and testing.
What are the key features and components of deep well plates?
Deep well plates have a flat tray with many wells. They were made in the 1950s and meet industry standards. This makes them work well with automated tools.
They are mostly made of polystyrene. This material is stable and can handle different temperatures. Other materials like polycarbonate and glass are also used.
What are the different well formats and configurations available for deep well plates?
The 96-well format is the most common. It works well for both manual and automated use. Plates with more wells, like 384 and 1536, are for faster work.
There are also custom sizes like 6, 24, and 3456 wells. The depth of the wells can vary too. This depends on what the research needs.
How are deep well plates treated and coated for specific applications?
Deep well plates can be treated and coated in different ways. This includes surfaces for immunoassays and cell culture. These special surfaces help with sticking or not sticking cells and biomolecules.
What are the key applications of deep well plates in modern laboratory research?
Deep well plates are used in many ways. They are great for growing cells, screening, and storing samples. They are also used for ELISA, protein tests, and more.
They are very important in labs that study life sciences and drug discovery.
What are the key performance features and quality control considerations for deep well plates?
Good deep well plates are stable and don’t get contaminated easily. They can handle high temperatures and pressures. They are also good for working with many samples at once.
They come in different shapes and seal well. This helps keep samples safe and prevents contamination.
How are deep well plates integrated with automated laboratory systems?
Modern deep well plates work well with automated systems. This includes robots and machines for liquids. It makes working with many samples faster and easier.
It also helps with tracking and analyzing data better. This is thanks to systems like Laboratory Information Management Systems (LIMS).
What are the best practices for the proper usage of deep well plates?
Using deep well plates right means choosing the right plate for your needs. You should also sterilize them properly and seal them well. This keeps samples safe.
Think about what the plate material is. It should not react with your samples or reagents.
What are the environmental considerations and sustainability efforts for deep well plates?
Deep well plates are disposable and can harm the environment. There are efforts to make them more sustainable. This includes recycling and using biodegradable materials.
Labs should dispose of them properly. They should also consider using reusable plates when they can.
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