Robotic Pipette Tips on Sale for Laboratory Liquid Handling

Baffled Erlenmeyer Flask with Vent Cap: 3L Size, PETG Material

Corning PETG Baffled Erlenmeyer Flask with Vent Cap Baffled; 3 L; None | Fisher ScientificCorning PETG Baffled Erlenmeyer Flask with Vent Cap Baffled; 3 L; None is a revolutionized product that has taken the scientific community by storm. Corning is a multinational company that is renowned for its innovation in the field of science and technology. It is no surprise that the Corning PETG Baffled Erlenmeyer Flask with Vent Cap Baffled; 3 L; None has achieved great success since its launch.The Corning PETG Baffled Erlenmeyer Flask with Vent Cap Baffled; 3 L; None is a high-quality product that is designed to meet the needs of scientists and researchers. Its unique design has made it stand out from other products in the market. The flask is made of PETG, a high-quality material that is known for its resistance to chemicals and breaking. It has also been designed to be baffle, which means it has baffles on the inside that help to prevent swirling of the contents during mixing.The flask has a volume capacity of 3 L, which makes it ideal for large experiments. It also comes with a vented cap that allows for better gas exchange during incubation. This feature is particularly important for cell culture and fermentation applications.One of the most important features of the Corning PETG Baffled Erlenmeyer Flask with Vent Cap Baffled; 3 L; None is its ease of use. The flask has a wide opening that makes it easy to add or remove contents. Its ergonomic design ensures that it is comfortable to handle and pour. It is also designed to be stackable, which saves space in the laboratory.The Corning PETG Baffled Erlenmeyer Flask with Vent Cap Baffled; 3 L; None has been extensively tested to ensure that it meets the highest standards of quality. It is autoclavable at 121 °C and can withstand temperatures as low as -40 °C. It is also free from DNase and RNase, which makes it ideal for molecular biology applications.The success of the Corning PETG Baffled Erlenmeyer Flask with Vent Cap Baffled; 3 L; None can be attributed to the company's commitment to innovation and excellence. Corning has a long history of creating products that have helped to advance the field of science. Its research and development process is focused on creating products that meet the needs of scientists and researchers.In conclusion, the Corning PETG Baffled Erlenmeyer Flask with Vent Cap Baffled; 3 L; None is a high-quality product that is ideal for researchers and scientists who need a reliable flask for their experiments. Its unique design and features make it stand out from other products in the market. Corning has once again demonstrated its commitment to innovation and excellence, and we can expect more groundbreaking products from them in the future.

Importance of Efficient Mixing for Anaerobic Digestion Feedstock

Anaerobic Digestion Feedstock: The Importance of Good Mixing in the Anaerobic ChamberAnaerobic digestion is an increasingly popular waste-to-energy technology that involves the microbial breakdown of organic matter in the absence of oxygen. The process yields biogas, a renewable fuel that can be harnessed for power and heat generation. While anaerobic digestion has proven effective in handling a wide range of feedstocks, from food waste and livestock manure to sewage sludge and energy crops, effective mixing is essential for maximizing biogas production and minimizing maintenance and energy costs.The anaerobic chamber, where the conversion process takes place, is designed to provide the ideal conditions for microorganisms to thrive and convert organic matter into biogas. However, poor mixing can lead to several problems that can negatively impact the process and its efficiency. For instance, incomplete digestion of the organic matter can lead to the accumulation of solids and the formation of scum, which can clog pipes, tanks, and other equipment. This can complicate maintenance and increase the risk of system failure.Good mixing in the anaerobic chamber is therefore crucial for efficient and effective operation. Proper mixing ensures that the feedstock is evenly distributed, creating a uniform environment that promotes consistent microbial activity. This helps to minimize the risk of dead zones, where little to no digestion occurs, and reduces the potential for clogging or blockage.There are several ways to achieve good mixing in the anaerobic chamber, each with its pros and cons. Mechanical mixing is the most common method and involves the use of agitators, mixers, or pumps to circulate the feedstock within the chamber. This can be achieved through various means, such as vertical or horizontal flow, which is determined by the type and viscosity of the feedstock. Mechanical mixing can be energy-intensive, however, and may require frequent maintenance to ensure proper functioning.Hydraulic mixing is another option, which utilizes the natural flow of the feedstock to achieve mixing. This can be achieved by modifying the geometry of the reactor, such as through the use of baffles, weirs, or cone-shaped bottoms. Hydraulic mixing is often combined with mechanical mixing to achieve optimum efficiency.Gas recirculation is another method used to achieve good mixing, which involves the recirculation of biogas within the reactor. This creates a mixing effect and helps to dislodge and break down solids while also promoting the growth of methanogenic microorganisms. This method can also enhance the production of biogas and reduce energy costs by using the biogas already produced in the process.In conclusion, good mixing is essential for efficient and effective operation of the anaerobic chamber in anaerobic digestion systems, regardless of the feedstock used. Proper mixing helps to ensure consistent microbial activity, reduce the risk of clogging or blockage, and enhance biogas production while minimizing maintenance and energy costs. Mechanical mixing, hydraulic mixing, and gas recirculation are all effective methods of achieving good mixing in the anaerobic chamber, and each has its pros and cons. Ultimately, the choice of mixing method will depend on factors such as the type of feedstock used, the size and design of the reactor, and the available resources and budget of the operator.

Revolutionary Liquid Handling Products for Improved Data Quality

Improving Your Data Quality with Biotix TipsIn the world of science and research, data quality is of paramount importance. Accurate and reliable data is essential for making informed conclusions and advancing scientific progress. However, data quality can be compromised by poor laboratory practices or suboptimal equipment. That's why it's essential to use the highest quality liquid handling products, such as Biotix Tips, to ensure the integrity and accuracy of your results.Biotix Tips are a critical component of liquid handling systems, used for precise measurement and dispensing of liquids. What sets Biotix Tips apart from other brands is their innovative design and strict quality control measures. Biotix Tips are made with high-quality materials and manufactured under best-class standards to ensure consistency and reproducibility.One of the primary advantages of Biotix Tips is their Universal Tip Compatibility. Biotix Tips are designed to fit most pipettes, making them a versatile option for laboratories that use multiple pipette brands. This compatibility reduces the need for stocking multiple types of tips and eliminates the risk of using an incorrect tip.Another significant advantage of Biotix Tips is their low retention feature. The unique design of the tips allows for minimal liquid loss, reducing sample waste and ensuring accurate measurements. With conventional tips, residual liquid can remain in the tip, leading to cross-contamination, carry-over, and inaccurate measurements. Biotix Tips reduce this risk, improving the accuracy and reliability of your results.Biotix Tips also come with pre-sterilized packaging, ensuring aseptic conditions and reducing the risk of contamination. The packaging is designed to minimize waste and preserve the integrity of the tips until they are used, enhancing the shelf life of the product.In conclusion, the quality of your data depends on the quality of the liquid handling products you use. Using high-quality products, such as Biotix Tips, can significantly improve the accuracy and reliability of your results. With their innovative design, strict quality control measures, and compatibility with most pipettes, Biotix Tips are an excellent choice for any laboratory looking to improve their data quality.

What is a Pipettor? Definition and Uses of Narrow Calibrated Tubes for Liquid Transfer and Measurement

(New York, NY) - Today, the renowned laboratory equipment manufacturer announced the release of their latest product - the Advanced Pipettor. This state-of-the-art pipettor is an indispensable tool for scientists and researchers in the medical, pharmaceutical, and chemical industries. The Advanced Pipettor is a highly accurate, easy-to-use liquid-handling instrument designed to streamline laboratory workflows and enhance productivity.The pipettor is a narrow, calibrated tube that is used to transfer small amounts of liquid with precision and accuracy. This vital piece of equipment is used in a wide variety of laboratory applications, including sample preparation, chemical analysis, and drug discovery. Pipettors are crucial for ensuring accurate and reliable results for experiments and analyses that require precise measurements of liquids.'s Advanced Pipettor is the latest addition to the company's lineup of laboratory equipment. It features cutting-edge technology that has been engineered with precision and accuracy in mind. The Advanced Pipettor is designed to make liquid handling as efficient and accurate as possible. With its easy-to-use interface, the pipettor can be operated by both experienced and novice users.The main advantage of the Advanced Pipettor is its accuracy. It features an advanced, motorized piston that automatically adjusts to changes in viscosity and temperature, providing highly accurate and repeatable results. The pipettor also has a range of volume settings, allowing users to handle a wide range of sample volumes with ease. Its ergonomic design ensures that users can handle the pipettor comfortably for extended periods of use, reducing the risk of errors and user fatigue.The Advanced Pipettor is the culmination of years of research and development. It has been designed to meet the needs of scientists and researchers in a wide range of applications, said a spokesperson for . We are confident that this innovative instrument will help our customers to reduce errors, increase productivity, and achieve more accurate results.The launch of the Advanced Pipettor is just the latest addition to the company's impressive lineup of laboratory equipment. is renowned for its commitment to innovation, quality, and precision, and its products are trusted by researchers and scientists around the world. The company offers a wide range of laboratory equipment, including centrifuges, balances, spectrophotometers, and more.At a time when researchers and scientists are facing unprecedented challenges, is committed to providing the best possible equipment and support. The Advanced Pipettor is just the latest example of the company's commitment to innovation and excellence. With its advanced technology and user-friendly design, the pipettor is poised to become a vital tool for researchers and scientists across a wide range of applications.

What is a Petri Dish and How is it Used in Cell Culture?

In the world of science and microbiology, Petri dishes are a crucial tool for researchers and biologists. A Petri dish, also known as a cell-culture dish or Petri plate, is a shallow cylindrical glass or plastic dish that is used to culture cells, bacteria, or small mosses. It is named after the German bacteriologist Julius Richard Petri, who invented it in 1887.Petri dishes are widely used for many different applications in the scientific field, such as testing the effectiveness of antibiotics and vaccines, studying microbial growth and behaviors, and researching diseases. These small dishes provide a sterile environment for cells and bacteria to grow in a controlled and contained setting.The basic design of a Petri dish includes a shallow, circular dish with a flat bottom and a loose-fitting, vented lid. The flat bottom allows for easy viewing under a microscope, while the vented lid allows for air circulation needed for bacterial and fungal growth.Petri dishes are often utilized in laboratories and research facilities, but they are also used in educational settings. They are an essential tool for high school and college-level biology students who are studying microbiology or genetic engineering. They allow students to experiment with growing bacteria and other microorganisms, which can help them better understand the mechanics of biology.However, not all Petri dishes are created equally. Some brands of Petri dishes are preferred over others due to their quality and reliability. One such brand is brand name removed. As a leading manufacturer of laboratory equipment and supplies, company name offers a wide variety of high-quality Petri dishes that are trusted by researchers and scientists across the globe.Company name Petri dishes are made from high-quality materials, ensuring that they are durable and long-lasting. They are designed to provide a sterile environment for cell culture, which helps to prevent contamination and maintain accurate research results.In addition to providing quality Petri dishes, company name also offers a range of accessories and equipment to streamline laboratory processes and improve accuracy. From pipettes and microscopes to sterilizers and incubators, company name has everything researchers need to conduct their experiments with ease and efficiency.Overall, Petri dishes are an essential tool in the world of microbiology and research. With the help of companies like company name, researchers and scientists have access to high-quality laboratory supplies that allow them to conduct accurate and groundbreaking research. As advancements in science and medicine continue, Petri dishes and other laboratory equipment will remain a vital part of the scientific process.

How to Use a Micropipette: Tips and Volume Range Explained

Microbiology is a field of study that deals with the identification and study of microscopic organisms, such as bacteria, viruses, fungi, and protozoa. One of the essential laboratory techniques in microbiology is the use of micropipettes. Micropipettes are precision instruments that are used to transfer small volumes of liquid from one container to another. Accurate measurements are important to ensure the success of any microbiological experiment or procedure.Micropipettes come in different sizes and configurations, depending on the volume of liquid being measured. One of the most commonly used micropipettes in microbiology is the P1000 micropipette. The P1000 micropipette is used to measure liquid volumes between 100 µL to 1000 µL, making it ideal for various microbiological experiments.To use a P1000 micropipette, an individual needs to follow a few steps. The first step is to ensure that the micropipette is correctly adjusted to the desired volume range. This adjustment is done by turning the plunger knob until the desired volume is displayed on the micropipette's digital display screen.After adjusting the micropipette's volume, the next step is to load the micropipette with the liquid to be transferred. The liquid can be loaded into the micropipette by dipping the micropipette's tip into the liquid and depressing the plunger to the first stop. This creates a vacuum that draws the liquid into the micropipette.Once the micropipette is loaded with the liquid, the next step is to transfer the liquid from one container to another. This is done by placing the micropipette's tip into the receiving container and depressed the plunger to the second stop. This releases the liquid from the micropipette's tip into the receiving container.It is important to note that the P1000 micropipette tips are further divided into micro white tips and medium white micropipette tips. Micro white tips are used for P2 and P10 size micropipettes, used for taking a volume from 0.2 to 10. Medium white micropipette tips are used for P20 micropipettes, measuring a volume range of 2 to 20.In microbiology, micropipettes are used for a wide range of applications. Some of the most common applications of micropipettes in microbiology include measuring the amount of culture to be inoculated in a medium, measuring the volume of reagents and solvents for various experiments, and transferring samples between containers with precision and accuracy.In conclusion, the use of P1000 micropipettes is a vital technique in microbiology. Accurate measurements are vital to the success of any microbiological experiment or procedure. Therefore, it is essential to follow the correct procedure when using micropipettes. By following the above steps, any microbiologist can confidently use the P1000 micropipette to measure and transfer liquids in their experiments, ensuring accurate results every time.

Wholesale Plastic Tubes and Centrifuge Tubes for Sale - Leading Suppliers from China

8-Slot Test Tube Rack for 50mL Centrifuge Tubes - Slant Design

Disposable Virus Sampling Tubes for Medical Use - High-Quality Sampling Reagents Available

The Importance of VTM Tubes in Disease TestingThe world has faced an unprecedented challenge in the form of the COVID-19 pandemic, which has underscored the importance of proper disease testing. One of the critical components in disease testing is the use of VTM or virus transport medium tubes. VTM tubes play a crucial role in the collection, transport, and storage of viral samples for disease testing.A VTM tube is a sterile tube that contains a buffered medium, which provides a suitable environment for the transport and survival of various viruses. These tubes come equipped with a swab that is used to collect samples from the nasal and oral cavities of patients suspected of having viral infections.These tubes are essential in ensuring the accuracy and reliability of viral testing. They protect the collected virus samples during transport and storage, ensuring that they remain viable for analysis. The buffered medium in the VTM tube is designed to prevent the growth of bacteria and preserve the viral RNA, which can quickly degrade in the presence of environmental factors such as heat and humidity.VTM tubes have become increasingly crucial in COVID-19 testing, where they are used to collect samples from suspected patients. COVID-19 has posed a unique challenge to the healthcare industry due to its high transmission rate and asymptomatic nature. This challenge has necessitated the use of VTM tubes, which can preserve and transport samples for accurate and timely testing.The advent of VTM tubes has revolutionized the healthcare industry's approach to viral testing, enabling healthcare providers to collect, transport, and store viral samples quickly and efficiently. These tubes have also helped to reduce the risk of infection transmission during sample collection and transportation, keeping both patients and healthcare providers safe.In conclusion, the importance of VTM tubes in disease testing cannot be overemphasized. These tubes have been critical in the COVID-19 pandemic, enabling healthcare providers to collect, transport, and store viral samples for accurate and timely testing. With their ability to preserve and transport viral samples, VTM tubes have revolutionized the healthcare industry's approach to viral testing, reducing the risk of viral transmission and ensuring the accuracy and reliability of disease testing.

Sterile Non-Treated U-Bottom 96-Well Cell Culture Plates - Pack of 100

IntroductionCell culture is an essential technique used in many fields, including biotechnology, medical research, and pharmaceutical research. It involves growing and maintaining cells from different organisms under controlled conditions in a laboratory setting. Researchers use cell culture plates to cultivate cells efficiently.In this blog, we will discuss 96-well cell culture plates, particularly U-bottom, non-treated, sterile plates, and their use in cell culture applications.What is a 96-Well Cell Culture Plate?A 96-well cell culture plate is a multi-well plate used to grow and maintain cells in vitro. It consists of a plastic plate with 96 individual wells, each with a capacity of 0.32 ml. The wells are arranged in a 12 x 8 matrix, which makes it easy for researchers to handle and analyze multiple samples simultaneously.U-Bottom vs. Flat-Bottom PlatesOne of the critical differences between cell culture plates is the shape of the bottom of the wells. U-bottom plates have a U-shape bottom, which provides more surface area for cell growth and better cell retention compared to flat-bottom plates. Additionally, U-bottom plates are useful for applications such as sedimentation assays and suspension cell culture.Non-Treated vs. Treated PlatesCell culture plates can either be treated or non-treated. Non-treated plates have no surface treatment, which allows researchers to covalently attach various coatings, such as extracellular matrix proteins or growth factors, to the wells. This feature makes non-treated plates ideal for cell differentiation studies and applications that require specific cell culture conditions.On the other hand, treated plates come with a surface treatment that enhances cell attachment. For instance, poly-L-lysine or collagen coatings improve adhesion, while poly-D-lysine coatings facilitate in suspension culture applications. Treated plates are suitable for standard cell culture and analysis experiments.SterilizationCell culture plates must be sterile to prevent contamination by unwanted microbes. Manufacturers use various sterilization techniques, such as gamma irradiation, ethylene oxide treatment, and autoclaving, to ensure sterility. Additionally, the plates are packaged in a controlled environment to prevent contamination during shipping and storage.ApplicationsCell culture plates have numerous applications in various fields. Here are some of the common applications of 96- well cell culture plates:1. Drug DiscoveryCell culture plates are used extensively in the drug discovery process to screen potential drug candidates for their efficacy and toxicity. The 96-well format allows for high throughput screening of multiple compounds simultaneously.2. Cell-Based AssaysCell-based assays are used to measure cellular responses to different stimuli, including drugs, toxins, and environmental changes. The 96-well format allows for the measurement of multiple assays simultaneously.3. Stem Cell ResearchStem cell research requires specialized culture conditions, such as specific extracellular matrix coatings, to maintain cell viability and differentiation. Non-treated 96-well plates provide researchers with the flexibility to coat the wells with their preferred coatings for better stem cell culture.Conclusion96-well cell culture plates are versatile tools in cell culture applications. The U-bottom, non-treated, sterile plates offer a high surface area for cell attachment, better cell retention, and flexibility to customize the culture conditions. In addition, the 96-well format allows for high-throughput screening and simultaneous analysis of multiple samples. When choosing the right cell culture plate, it's essential to consider the application, surface treatment, and shape of the bottom for optimal cell culture conditions.