Year: 2025

When it comes to lab work, the handling of liquids is a process that needs to be done with maximum precision and safety at all times, whether you’re conducting routine tests or handling highly volatile compounds. Part of this handling is measurement and transfer. How do you make sure this is done with absolute precision? This is where the automatic pipette comes into play. It’s an indispensable tool that helps scientists immensely, streamlining workflow and mitigating human error.

In this blog, we’ll go over exactly what it is, how it works, and how your lab can benefit from its use.

What Is an Automatic Pipette?

Much more precise than a manual pipette, an auto pipette aspirates and dispenses highly precise amounts of liquid on a consistent basis, with minimal manual input required. Whereas a manual version relies on human dexterity, its automatic counterpart utilizes mechanical and electronic functions to maximize precision and speed on a consistent basis.

There are various types of automatic pipettes that are ideal choices for a variety of work types.

• Single-Channel: Used to transport liquid one channel at a time. This is a common type, used in most general lab environments.
• Multi-Channel: This allows for simultaneous dispensing through multiple channels, which is ideal for high-throughput tasks.
• Electronic: These have various electronic functions that can be programmed by the user. Digital displayed and motorized dispensing allows for incredibly accurate control.

Key Components

When you understand the basic components of an automatic pipette, you can use and maintain it properly. Let’s go over the primary parts:

• Plunger/Button Mechanism: This feature initiates aspiration and dispensing. Note that electronic models may have programmable buttons in place of a plunger.
• Tip Ejector: A mechanism that allows the user to dispose of tips without touching them.
• Digital Volume Display: Exclusive to electronic pipettes, this displays vital information such as target volume.
• Disposable Pipette Tips: Vital for preventing cross-contamination. These should be disposed of after one use.

How Does an Automatic Pipette Work?

An auto pipette functions by utilizing air or positive-displacement mechanisms. If you’re operating one, here is the general process:

• Adjust the volume dial, or input it on the digital display if you’re using an electronic pipette.
• Place a sterile tip on the end of the pipette. This tip will be disposed of when you’re finished.
• Press the plunger to the first stop, place the tip into the liquid, and release to draw the proper amount of liquid.
• Place the tip into the opening of the target container and press the plunger. This will dispense the liquid.

Air displacement is one of two main operation mechanisms, using an air cushion that sits between the piston and the liquid. Positive displacement, on the other hand, sees the piston contact the liquid directly, which minimizes evaporation and improves performance with volatile and viscous liquids.

Benefits of Using Automatic Pipettes

There are various advantages to using an automatic pipette in your lab, such as:

• Enhanced Accuracy and Repeatability: The possibility of human error and variability is kept to a minimum.
• Improved Ergonomics: Less force is required, which mitigates strain on the hand and reduces injuries from repetitive stress.
• Increased Efficiency: Automation greatly speeds up workflows, which leads to high productivity. This is especially useful in high-volume lab environments.

Lab Applications

There are several scientific disciplines that lend themselves to the use of an auto pipette. For example, it’s an invaluable tool in clinical diagnostics where patient samples and reagents need to be handled with the utmost care. In pharmaceutical research, dosing requires maximum precision, which can’t be achieved consistently through the use of a manual pipette. In the field of molecular biology and chemistry, there are various uses—a primary one being in PCR, ELISA, and titration, in which exact measurements are vital to the research.

Find the Perfect Automatic Pipette at BaneBio

The importance of the auto pipette in a laboratory cannot be understated. It’s a vital tool in many types of research and lab procedures, offering maximum precision and efficiency. Your researchers will save valuable time through their use, freeing them up to focus on tasks that require more manual processes.

If your laboratory doesn’t yet have these pipettes, we know the perfect place to get them. Get in touch with BaneBio and stock up on these vital tools!

A laminar flow cabinet (or hood) is an essential addition to any laboratory that needs to prioritize contamination control. It helps maintain a sterile environment that serves various research endeavors—handling sensitive electronic components, conducting microbiological research, prepping pharmaceuticals, and more.

Not all of these cabinets are the same, though. Choosing between the two main configurations can have a significant impact on the efficiency, comfort, and safety of your work. So here’s the big question: Does your lab need a vertical laminar flow hood or a horizontal laminar flow hood? The answer depends on a few factors, which we’ll get into in this blog.

What Is a Laminar Flow Cabinet?

First off, let’s take a look at what this kind of cabinet is, as well as the purpose it serves. It’s essentially a workspace that’s designed to protect samples from contamination by using a constant flow of uninterrupted, filtered air. The air passes through a HEPA filter, sweeping away any airborne contaminants before they can reach vulnerable samples.

These cabinets are versatile in their applications, from electronics and optics manufacturing to medical labs and pharmaceutical compounding. These are all environments in which microscopic contaminants can post a risk to safety and results.

Vertical Laminar Flow Hood

Vertical cabinets draw air from above the unit, pushing it downward through the HEPA filter and creating a vertical flow of air across the work surface.

Benefits include:

• Enhanced safety for powders or aerosols: Because of the downward direction of the air, particles are generally being pushed away from the user’s face, thus offering more protection when working with airborne materials.

• Compact design: Counter space needs to be optimized in a lab environment, allowing enough space for equipment to sit and research to take place. A vertical hood helps you make good use of space when you only have so much to work with.

Common applications include:

• Pharmaceutical compounding
• Cell culture and microbiology labs
• Environments that deal with hazardous airborne particles

Horizontal Laminar Flow Hood

Rather than moving air downward, a horizontal laminar flow cabinet pulls it through a HEPA filter situated at the back of the unit. It then pushes the air horizontally across the work surface in the direction of the user.

Benefits include:

• Reduced turbulence on work surfaces: Thanks to the airflow being smoother and overall more consistent, delicate or static-sensitive components are more protected in a horizontal laminar flow cabinet.

• Improved user comfort: Because the air is flowing away from the user’s face, horizontal cabinets are ideal for longer work sessions thanks to increased comfort.

Common applications include:

• Medical device assembly
• Handling of electronic and optical equipment
• Laboratory environments that require gentle, uniform airflow

Key Factors to Consider When Choosing

If you’re having trouble choosing between a horizontal and vertical cabinet, there are some key considerations that should make the decision a bit easier.

• The nature of your work: Are you frequently dealing with biohazards, sterile preparations, or volatile substances? If so, consider this: Vertical cabinets are ideal for hazardous or powder-based materials, while cleaner, more-sensitive operations will go more smoothly with a horizontal hood.

• Space and layout: If your lab has limited space, a laminar flow cabinet that stands vertically is likely the better option.

• User comfort and workflow: If you’re looking for a more ergonomic user experience—especially when working for long periods of time—a horizontal cabinet is your best bet.

• Regulatory compliance: Make sure the unit you choose aligns with industry standards and guidelines. As an example: USP <797> and <800> for sterile compounding.

Which Laminar Flow Cabinet is Right for You?

When it comes down to it, the best laminar flow cabinet depends on the applications you wish to use it for, your comfort preferences, and workspace constraints. If you want to prioritize safer handling of powders and biohazards, as well as space efficiency, a vertical cabinet is ideal. On the other hand, if you’re working with clean, non-hazardous materials that demand smooth airflow and ergonomic setups, a horizontal cabinet is likely the better choice.

Make Your Choice

Choosing the right laminar flow cabinet for your needs is more than a simple technical decision—it’s about safety, productivity, and compliance. All of these things are contributing factors in your laboratory’s success, so it’s important to weigh your options carefully. By understanding the differences between vertical and horizontal cabinets, your decision will be more informed and you can set yourself up for success.

If you still need some help making your selection—or if you’re ready to pull the trigger on a purchase—the team at BaneBio is ready to help you in the process. Get in touch with us today!

Biological Safety Cabinets—or BSCs—are unsung heroes of the laboratory. They’re not as exciting as microscopes or centrifuges, but they’re vital components of scientific safety, nonetheless. They play a role in protecting not only laboratory personnel, but also the samples within the lab and the environment overall. But as with any other equipment type, not every biosafety cabinet is created equal; there are types, applications, maintenance practices, and more to take into consideration. In this blog, we want to take a look at all the options so you might be better informed when it’s time to purchase one for your own lab.

Biosafety Cabinet Types

Class I Biological Safety Cabinet

These provide environmental and personnel protection, but be warned that they don’t safeguard their actual contents. The primary role of a Class 1 cabinet is to prevent exposure to hazardous aerosols.

Some common applications include handling of biological materials that post low or moderate risk, procedures that include aerosol-generating processes, and the protection of lab employees working with non-sterile substances.

Class II Biological Safety Cabinet

This is where you’ll find the most variety. A combination of HEPA filtrations and controlled airflow results in the protection of people, the environment, and the product.

• Class II, Type A1: 70% of the air within these cabinets is recirculated, making it suitable for low-risk operations.
• Class II, Type A2: This is similar to A1, the main difference being greater inward air velocity. As a result, it’s much more suitable for handling hazardous agents.
• Class II, Type B1: Type B1 expels 60% of its air, making it a good choice for any work that involves biological hazards and other volatile chemicals.
• Class II, Type B2: This is a fully exhausted system that doesn’t allow any recirculation. It’s highly recommended when dealing with high-risk pathogens and toxic chemicals.

Regardless of subtype, a class II biological safety cabinet is an essential part of microbiology and pharmaceutical labs. It allows for the safe manipulation of infectious agents, cell-culture research, viral studies, and the preparation of sterile products.

Class III Biological Safety Cabinet

If you’re looking for the highest possible level of containment, you should be prioritizing class III cabinets. They operate as fully enclosed units with glove ports, and are meant for handling the most hazardous biological materials—including Biosafety Level 4 (BSL-4) pathogens.

Typically, class III cabinets are found serving the following industries and areas of research:

• High-containment labs and bioweapons research
• Highly infectious virus studies, such as research into Ebola
• The development of vaccines and biopharmaceutical manufacturing

Common Biological Safety Cabinet Uses

To say these cabinets are important to several fields of research may be an understatement. In many cases, proper research can’t be conducted without them. Their common applications are plenty, but here are the primary uses:

• Infectious agent containment in microbiology and virology
• Drug formulation within the biotechnology and pharmaceutical industries
• Diagnostic procedures in clinical and hospital laboratories
• COVID-19 testing and research

Maintenance and Best Practices

With so many substances being handled within these cabinets, a bit of maintenance is to be expected. Here’s a short rundown of the bases you should be covering.

Regular Cleaning and Decontamination

Make sure you’re cleaning every surface with the appropriate disinfectants, such as 70% ethanol and bleach solutions. Do this before and after use. When cleaning is complete, autoclave or safely dispose of any contaminated waste materials.

Importance of Annual Certification

To ensure that your biosafety cabinet meets all industry standards (and functions properly), an annual certification is necessary. The tests involved in this certification include airflow validations, containment efficiency, and HEPA filter integrity checks.

Proper Airflow Management

When choosing a spot for your cabinet, ensure you allow plenty of space near the airflow grills to maintain circulation. In addition, train all personnel to follow proper hand and arm movement techniques to prevent turbulence.

Common Troubleshooting Tips

If you’re experiencing issues with your biosafety cabinet, here are some troubleshooting tips we suggest:

• Low Airflow Alarms: Ensure no filters are clogged and inspect the blower motor.
• HEPA Filter Saturation: Stick to a timely schedule of filter replacements for optimal airflow. Manufacturer guidelines should detail how frequently filters need to be changed.
• Inconsistent Air Velocity: Minimize external airflow disturbances (like HVAC changes).

Choosing the Right Biosafety Cabinet for Your Needs

Before you make a final decision on which cabinet to purchase, you should carefully consider your research needs.

• Work Type: Do you require protection for your people, the environment, your product, or a combination of the three?
• Containment Level: It’s vital to get a biological safety cabinet that can handle the biosafety level (BSL-1 to BSL-4) of the substances you’ll be working with.
• Lab Space and Configuration: Make sure you have enough space in your laboratory for the cabinet to have a permanent placement.
• Regulatory Compliance: Make sure you adhere to standards set by OSHA, CDC, and NSF.

A Laboratory Necessity

The biosafety cabinet is an essential tool for any laboratory researching hazardous biological agents. By familiarizing yourself with different cabinet types, biosafety levels, and maintenance requirements, you can make an informed purchase for your lab’s needs. Whether you’re in the market for biosafety cabinets or you have some you need to sell, get in touch with us at BaneBio—the Scientific Supermarket.

Throughout the ages, fire has been both friend and foe to humankind. We need it, and we want it around, but only at specific times and in specific places. The laboratory is one of those places where there’s probably more chance of the unwanted variety than most, given that so much of the work there is done with flammable materials. But unwanted fire isn’t just a concern for laboratories. In medical facilities and industrial settings, the safe storage of flammable materials is equally crucial to preventing accidents and ensuring the well-being of employees. Flammable storage refrigerators are specifically engineered to safely store volatile substances, maintaining controlled environments that minimize risks. In today’s blog, we’ll explore in-depth how to go about choosing the right kind of storage refrigerator for your particular needs.

Key Considerations

Compliance With Regulations

The first step in selecting a refrigerator like this is ensuring compliance with relevant safety regulations. The Occupational Safety and Health Administration (OSHA) and the National Fire Protection Association (NFPA) have set forth guidelines that govern the storage of flammable materials. OSHA requires that flammable liquids be stored in approved containers and cabinets. NFPA provides specific classifications for the storage of flammable liquids, including recommendations on the type of refrigeration unit to use. Understanding these regulations will go a long way toward keeping your facility compliant and keeping potential hazards at bay.

Storage Capacity

Before purchasing a flammable storage refrigerator, assess the volume of flammable materials you need to store. This requires a thorough inventory of your current stock, as well as your best estimate of future needs. Choosing the right size is crucial; a unit that’s too small may be overcrowded, while a unit that’s too big may lead to excessive energy costs. Do your best to find a refrigerator that accommodates your current inventory with room for growth.

Temperature Control

Consistent and reliable temperature control is vital in a storage refrigerator. Flammable materials often require specific temperature ranges to maintain their integrity and prevent dangerous reactions. As such, look for refrigerators that offer precise temperature settings and stable performance, ensuring that your materials are stored safely. Additionally, consider models with built-in temperature alarms that notify you of any fluctuations outside of acceptable ranges.

Explosion-Proof Features

A good flammable storage refrigerator is also an explosion proof refrigerator. This means it will have a spark-free interior and sealed electrical components, to reduce the risk of ignition of whatever flammable material you’re storing inside of it. When selecting a flammable storage refrigerator, then, make sure it’s also an explosion proof refrigerator—meeting the necessary explosion-proof standards to protect against hazards associated with volatile materials.

Durability & Material

Durability is another critical factor in choosing a flammable storage refrigerator. Look for models constructed from sturdy materials that can withstand harsh environments. Corrosion-resistant materials are essential, especially in settings where spills may occur or humidity levels are high. A durable refrigerator will enhance safety and extend the lifespan of your unit.

Additional Features to Look For

When evaluating flammable storage refrigerators, consider additional features that enhance usability and safety:

• Adjustable Shelving
  Flexible shelving options allow you to customize the interior space to fit different container sizes, maximizing storage efficiency and making the most of your investment.
• Lockable Doors
  Security is paramount when storing hazardous materials. Lockable doors help prevent unauthorized access, protecting your inventory and potentially even your facility.
• Alarms and Monitoring Systems
  Advanced refrigerators may include alarm systems that alert you to temperature fluctuations or door openings, providing an added layer of security and peace of mind.

Common Pitfalls to Avoid

When choosing a flammable storage refrigerator, be aware of common mistakes that can lead to safety hazards:

• Using Standard Refrigerators for Flammable Materials
  A big no-no. Standard refrigerators are not designed to handle the risks associated with flammable materials. Always use a specialized refrigerator for this highly specialized job.
• Ignoring Certification Labels and Testing
  Due your due diligence. Always check for certification labels that confirm compliance with safety standards. Units that are not certified may pose significant risks.

Keep Fire Where It Belongs: Elsewhere

No matter where it pops up, unwanted fire is, well, unwanted. You can’t keep the world safe, but you can keep your laboratory, medical facility, or industrial space safe. Choosing the right flammable storage refrigerator is crucial for maintaining a safe environment when volatile materials are involved. By considering factors such as regulatory compliance, storage capacity, temperature control, explosion-proof features, and durability, you can make an informed decision that protects your employees and your assets. For tailored advice, make sure you work with suppliers who specialize in such storage solutions. At BaneBio, we’re always ready to provide insights and recommendations to ensure you select the best refrigerator for your needs.