Essential Guidelines For Medical Lab Freezers: Ensuring Optimal Safety And Efficacy

Medical Lab freezers play a crucial role in safeguarding the safety and efficacy of stored materials in healthcare settings. Whether it’s vaccines, medications, or biological samples, maintaining proper storage conditions is paramount to preserving their integrity and effectiveness. By adhering to essential guidelines for proper freezer usage, healthcare professionals can ensure that these valuable materials remain safe, potent, and reliable when needed. In this blog post, we will explore the significance of medical freezers and the importance of following key guidelines to maximize the safety and efficacy of stored materials. Let’s delve into the essential practices that healthcare providers should implement for optimal freezer usage and the preservation of vital resources. 

Temperature Control and Monitoring 

Proper temperature control is crucial for preserving the integrity of vaccines, medications, and samples stored in medical freezers. Each material has specific temperature requirements that must be followed to maintain stability and effectiveness. Vaccines typically need to be stored between 2°C and 8°C (36°F to 46°F), known as the cold chain temperature range. Deviating from this range can compromise vaccine potency and render them ineffective. 

Medications and temperature-sensitive drugs have different temperature requirements, which can be found on product labels or guidelines provided by pharmaceutical manufacturers. Biological samples, such as blood or DNA samples, often require ultra-low temperatures below -70°C (-94°F) for preservation. 

Accurate temperature control is essential as fluctuations can lead to loss of potency, chemical degradation, or spoilage. Temperature monitoring systems are crucial for continuous monitoring and early detection of temperature deviations. These systems use sensors and alarms to alert healthcare staff if the temperature goes outside the desired range. Temperature monitoring systems also generate temperature logs for record-keeping and regulatory compliance. 

Segregating Items Based on Temperature Requirements and Compatibility: 

* Separate materials based on their specific temperature requirements. 

* Store vaccines, medications, and samples that require similar temperature ranges together to maintain proper storage conditions. 

* Avoid storing materials with incompatible temperature requirements in close proximity to prevent cross-contamination or compromise of integrity. 

Proper Labeling, Dating, and Inventory Management: 

* Clearly label each item with essential information, including the name, expiration date, lot number, and any other relevant details. 

* Use waterproof and durable labels to withstand the freezer’s low temperatures and prevent fading or peeling. 

* Implement a system to track and monitor inventory, ensuring accurate records of items entering and leaving the medical freezer. 

* Regularly check expiration dates and remove expired materials promptly to maintain inventory freshness and avoid using compromised items. 

Following these guidelines enhances the organization, traceability, and effectiveness of medical freezer storage. Effective inventory management and clear labeling ensure easy identification and tracking, reducing errors and ensuring the safe utilization of stored materials. 

Lab Freezers Calibration 

 Lab calibration are vital for optimal performance and reliability of medical freezers. Follow these key practices to ensure the proper functioning of your freezer: 

Scheduling professional inspections and calibrations is essential: 

* Professional inspections identify and address potential issues before they escalate. 

* Calibration verifies and adjusts temperature accuracy for precise temperature control. 

* Compliance with regulatory standards is ensured. 

* Documentation is available for audits and quality assurance purposes. 

By following these maintenance and calibration practices, healthcare professionals can maintain the cleanliness, functionality, and accurate temperature control of their medical freezers, ensuring the safe storage of materials. 

Emergency Preparedness and Backup Plans 

Contingency plans are crucial for maintaining material safety during emergencies. Install backup power sources like generators or battery backups to ensure an uninterrupted power supply. Designate trained personnel to execute emergency protocols, monitor temperature readings, and prioritize critical materials. Assess stored material condition post-emergency and take necessary steps for recovery. 

By having contingency plans, backup power sources, and following emergency guidelines, healthcare professionals can ensure material safety during emergencies. 

Adhering to essential guidelines for medical freezer usage ensures optimal safety and efficacy. By controlling temperature, organizing materials, conducting maintenance, and having contingency plans, healthcare professionals safeguard vaccines, medications, and samples. These practices promote accuracy, ease of identification, and inventory management, reducing errors and ensuring safe utilization. Prioritizing these guidelines upholds quality and safety, contributing to better patient care and public health outcomes. 

Ready to optimize your medical freezer storage and get a new Lab freezer?  Contact us today to know more about our high-quality medical freezers, and our Calibration Services!

Large Capacity Forced Air Ovens for Various Industries: Efficiency and Versatility Unleashed

Large-capacity forced air ovens have become indispensable in today’s industries, offering numerous benefits and applications. With precise temperature control and uniform heating, these ovens are ideal for drying, curing, aging, testing, and more. Stay tuned to discover how these versatile ovens revolutionize manufacturing processes and deliver reliable results. 

Forced air ovens are high-performance equipment widely used in various industries. They are designed to provide efficient and uniform heating through the circulation of heated air within a spacious chamber. These ovens offer multiple benefits including accurate temperature control, uniform heat dispersion, and application adaptability. They are well-suited for a wide range of sectors because of their huge capacity and multi-purpose functionality, making them a useful tool for different industrial processes. 

Applications of Large Capacity Forced Air Ovens 

Large-capacity forced air ovens find extensive applications in a diverse range of industries, revolutionizing processes and delivering exceptional results. Here are some key industries where these ovens are highly beneficial: 

Food Industry: They play a crucial role in drying, baking, cooking, and preserving various food products. With their precise temperature control and efficient airflow, these ovens ensure uniform heating and consistent results. 

Pharmaceuticals: Forced air ovens are indispensable for sterilization and the curing of pharmaceutical products. With precise temperature control and uniform airflow, these ovens ensure that pharmaceutical equipment and products are free from contaminants, meeting stringent quality standards. 

Battery & Semiconductor: Forced air ovens dry and cure battery components, ensuring performance and longevity. In semiconductor manufacturing, they enhance film adhesion and stability.  

Materials Science: Forced air ovens are versatile tools used in various industries for heat treatment, polymer curing, and accelerated aging tests, enhancing material properties and providing valuable insights. 

With precise temperature control, uniform airflow, and spacious chambers, these ovens deliver efficient and reliable results. They are critical drivers of innovation and productivity in sectors such as food processing, pharmaceuticals, electronics, and materials research. 

Benefits and Advantages 

Large-capacity forced air ovens provide distinct advantages that set them apart in various industries. With their ability to deliver uniform heating, these ovens ensure consistent temperature distribution across all samples, minimizing experimental variability and optimizing overall quality. 

Precise temperature control is a key feature of large-capacity forced air ovens, allowing researchers and operators to maintain accurate temperature settings and tight control. This precise control enables the creation and maintenance of stable thermal conditions, enhancing the reliability and repeatability of experiments and production processes. 

Efficient airflow is another standout feature of these ovens, thanks to the internal fans that facilitate the circulation of heated air. This efficient airflow promotes even heat distribution and faster heating rates, significantly reducing processing times and boosting operational efficiency. Researchers and operators benefit from quicker turnaround times, enabling them to complete experiments and production cycles more efficiently. 

The combination of uniform heating, precise temperature control, and efficient airflow in large-capacity forced air ovens leads to improved productivity, reduced processing times, and high-quality results. These ovens serve as indispensable tools across industries, ensuring optimal performance and reliable outcomes for a wide range of applications. 

How to Choose Industrial Forced Drying Oven :

Firstly, assess the temperature range offered by the oven. Consider the temperature range needed for your applications and ensure that the oven can reach and maintain the desired temperature levels effectively. 

Capacity is another crucial factor to consider. Evaluate the size and volume of the oven chamber to ensure it can accommodate your sample sizes and quantities. Consider the flexibility needed for future expansion or changes in your experimental or production needs. 

Safety features should not be overlooked. Look for ovens that are equipped with features such as temperature and overheat protection, door interlocks, and alarms to ensure the safety of personnel and samples during operation. 

Energy efficiency is an important consideration to minimize operational costs and environmental impact. Look for ovens with energy-saving features such as insulation, efficient airflow design, and programmable temperature controls. These features can help optimize energy consumption and reduce operating expenses. 

Additionally, consider factors such as ease of use, control interfaces, reliability, and service and support options provided by the manufacturer. Reading customer reviews and seeking recommendations can also provide valuable insights into the performance and reliability of specific oven models. 

Large-capacity forced air ovens offer unparalleled efficiency and versatility, making them indispensable across various industries. With precise temperature control, uniform heating, and efficient airflow, these ovens revolutionize manufacturing processes, reduce processing times, and deliver high-quality results. From food processing to pharmaceuticals, and electronics to materials science, the applications of these ovens are vast and impactful. When selecting the right oven, consider factors such as temperature range, capacity, safety features, and energy efficiency to ensure optimal performance.  

Contact us to explore our wide range of forced air ovens and to discuss your specific requirements, we also offer Calibration Services for a wide range of products. Unleash efficiency and versatility in your industry! 

How Can Maintain and Safely Clean Biosafety Cabinets in Labs?

When lab managers need to work with contagious and deadly pathogens, they need a safe and clean environment. Biosafety cabinets are an excellent Lab equipment because they offer various amenities while keeping both the human being and the surrounding area clean and hazard-free.

Biosafety cabinets are so vital for working with pathogens, we wanted to take a closer look at how they operate and what steps lab people and employees can take to keep them clean.

What is a Biosafety Cabinet (BSC)?

A biosafety cabinet (BSC) is a primary containment device used with biological material. While handling biological agents, it is the biological equivalent of using hazardous chemicals inside a fume hood. Like a chemical fume hood, a biosafety cabinet protects the user from hazardous material using directional air flow.  Biosafety cabinets differ in that the air is also HEPA filtered, which removes biological contaminants.

The most common biosafety cabinet is the Class I ,Class II Type A2 biosafety cabinet, though there are many other types of ventilation equipment

Class I Cabinet

These cabinets are the least used because they don’t offer any “product” protection, with the product being the bacteria or virus sample. Although HEPA filters ensure that the air coming out of the cabinet is clean, unfiltered air comes in, contaminating the product. Usually, Class I cabinets are used to house specific equipment like a centrifuge.

Class II Biosafety Cabinets

This class offers product protection, and these cabinets can be broken down into various sub-classes, including A1, A2, B1, B2, and C1. The different subcategories of Class II cabinets refer to the amount of airflow and recirculation inside the unit. The most common type of Class II Biosafety cabinet is A2, but each subcategory has a particular application. For example, B2 cabinets don’t recirculate air, instead they use a duct exhaust system to remove contaminants and pathogens. These cabinets are primarily found in toxicology labs because they’re expensive to operate.

Class III Biosafety Cabinet

This class is the most secure, offering gas-tight seals and built-in gloves for working. Class III cabinets are often called glove boxes because of this setup. To prevent lab contamination, these cabinets use a dunk tank or double-door autoclave to trap pathogens and harmful particles. Class III cabinets are only used in maximum containment labs, such as those that work with BSL-4 pathogens (the most dangerous kind).

Which Industries Use BSCs?

Industries that work with pathogens and biological agents need to use biosafety cabinets. Examples can include:

* Universities and Institutes

* Research Labs

* Toxicology Labs

* Criminology Labs

Common Types of Contamination Found in a BSC

As you can imagine, it’s essential to maintain a sterile work environment inside a biosafety cabinet. Unfortunately, unsafe practices can cause various types of contamination, such as:

* Spills

* Cross-Contamination of Products

* Dirt and Grime

* Mislabeled Materials

Also, because most BSCs create an “air curtain” to prevent pathogens from escaping, any biological elements in the air can wind up on all surfaces within the cabinet. For that reason, it’s crucial to replace filters and clean the cabinet regularly. In most cases, human error is the cause of contamination, which is why it’s so vital to have a biosafety cabinet cleaning procedure in place.

Safety Measures and Best Practices When Using Biosafety Cabinets

Because biosafety cabinets are used for delicate and hazardous materials, workplaces must implement various best practices and cleaning procedures. Here’s a rundown of how to use BSCs safely to protect both workers and products.

Use Checklists

A checklist is an essential tool for many complex jobs with multiple steps. Having workers follow a checklist system ensures that they don’t forget crucial steps. Even if workers have done procedures many times before, it’s easy to miss or forget something.

Test Airflow and Ventilation Before Use

BSCs should have sensors and warning systems in case the airflow gets interrupted or stops suddenly. Workers should run the air for a few minutes to ensure that these systems are working properly. If they are not functioning, the employee should notify a supervisor immediately.

Only Use BSCs as Intended

As we mentioned, there are different classes of BSC, which can be divided further into subcategories. Workers should be aware of the capabilities and limitations of a biosafety cabinet before performing any work inside of it.

Don’t Disrupt the Air Curtain

The cabinet’s airflow is crucial for maintaining a safe work environment. If employees disrupt the air curtain too much, they could potentially cause contamination of both the lab and the products. As a rule, employees should move perpendicular to the front of the cabinet as much as possible. This way, they don’t break the airflow too much at one time.

Replace Air Filters Often

HEPA filters are essential for a well-functioning BSC, but these filters can get contaminated quickly. There should be a replacement schedule based on the amount of use a cabinet receives. Be sure to read up on manufacturer recommendations as well.

Shut Off UV Lights Before Working

While UV lights can provide some level of sterilization, they can also be a health and safety hazard while working inside the BSC. Employees should shut off all UV lights before working to prevent potential risks.

Store Supplies and Equipment Outside the BSC

Before employees start working within the cabinet, they should know which items to bring in. According to OSHA, workers should only bring the items necessary for immediate use. The cabinet is not designed for long-term storage, as doing so could interrupt the airflow and lead to contaminated surfaces.

Use the Correct Biosafety PPE

The type of personal protective equipment necessary for use in a BSC depends on the nature of the work involved. However, here’s a rundown of the various PPE options that should be available to workers at all times:

1.Gloves

2.Full-Body Coveralls

3.Face Mask and Face Shield

4.Eye Protection (e.g., goggles or glasses)

Although the cabinet itself provides adequate airflow, some situations may require a self-contained breathing apparatus (SCBA). These devices should be worn in cases where pathogens may escape into the lab environment.

Dispose of PPE Properly

Once employees are finished working inside the cabinet, they should dispose of their PPE according to CDC and OSHA waste guidelines. Workers should never reuse PPE. Some materials, like an SCBA, must be cleaned thoroughly before reuse because they are not disposable.

Clean and Decontaminate the Cabinet Regularly

One question to ask employees is, “what steps should you take to decontaminate a BSC after you finish working?” Typically, the best option is to wipe down all surfaces with cleaning materials while the blower is still running. In many cases, workers should use a solution of 10 percent bleach, followed by a solution of 70 percent ethanol. It’s crucial to put these liquids on a sterile pad or wipe. No one should spray bleach or ethanol inside the cabinet.

While wiping the surfaces works well for everyday use, you’ll also need gas decontamination for a more comprehensive solution.

What is Gas Decontamination?

Instead of using wipes and cleaning solutions to sterilize surfaces, gas decontamination uses aerosolized gas to permeate the cabinet and kill any bacteria or viruses that may be present. This decontamination method works well for ensuring that the cabinet stays sterile at all times. However, the gas will not remove surface dirt or grime.

Several gases can be used for decontamination, but chlorine dioxide is the most common.:

No Condensation – Since this is a “true” gas, it won’t bind to water vapor in the air and create condensation.

No Toxic Byproducts – Chlorine dioxide produces oxygen and salt, so workers don’t have to worry about secondary contamination after spraying the gas.

Fast Application and Cleaning – Typically, chlorine dioxide decontamination takes up to 90 minutes for application and another 30 minutes for scrubbing afterward.

That said, chlorine dioxide can potentially lead to some metal corrosion, so workers have to be careful to avoid corroding the inside of the cabinet. If chlorine gas is present, this problem can be much worse.

When Should Workers Use Gas Decontamination for BSCs?

There are several reasons why gas decontamination may be necessary, such as:

* Relocating the Biosafety Cabinet

* Disposing of a BSC

* After a Large Spill

* Before Filter Changes

Because of the nature of gas decontamination, regular workers should not conduct the procedure themselves. Instead, it’s better to use a third-party provider that can guarantee their work. Professional gas decontamination companies will also have the right tools to complete the job correctly.

Contact AiMedical for Your Biosafety Cabinet Today for further details.

Choosing, upgrading, and maintaining a biosafety cabinet is critical to ensure safety for laboratory workers and the environment.

By evaluating factors such as the type of agents or materials used, risk level of the work, volume of materials, and work practices and procedures, laboratory managers can choose the most suitable biosafety cabinet.

Additionally, it’s crucial to have the biosafety cabinet certified regularly and conduct routine maintenance to ensure it’s running properly. Contact us for NSF49 Certified BSC Equipment, we also offer the calibration service for more laboratory equipment.  

Importance Of Ultra Low Freezers Calibration For Vaccine Storage In Labs

Vaccine temperature monitoring is crucial when it comes to storing any vaccine in Ultra Low Freezers. Storing the vaccine properly protects its ultimate potency. Think about it this way, nobody wants a vaccine that doesn’t have full capability.

Ultra-low freezers are used to store biological samples, such as blood, tissue, and cells, at very low temperatures, typically -80°C or below. This is necessary to preserve the integrity of the samples and prevent them from degrading.

Ultra-low freezers are precision instruments and require regular calibration to ensure that they are operating accurately. Calibration is the process of comparing the accuracy of a measurement device to a known standard. This ensures that the device is reading correctly and that the samples are being stored at the correct temperature.

There are several factors that can affect the accuracy of an ultra-low freezer, including:

* Temperature drift

* Vibration

* Power fluctuations

* Environmental factors, such as humidity and dust

Temperature Calibration helps to identify and correct any of these factors that may be affecting the accuracy of the freezer.

It is important to have your ultra-low freezer calibrated on a regular basis, typically every 6-12 months. This will help to ensure that your samples are being stored at the correct temperature and that the integrity of the samples is being preserved.

Here are some of the benefits of having your ultra-low freezer calibrated:

* You can be confident that your samples are being stored at the correct temperature.

* You can avoid the risk of sample degradation.

* You can comply with regulatory requirements.

* You can extend the life of your freezer.

If you have an ultra-low freezer, it is important to have it calibrated on a regular basis. This will help to ensure that your samples are being stored safely and that your freezer is operating accurately.

To ensure the proper calibration of your lab equipment, seek expert calibration services from Across International.

We’re an ISO 17025-accredited calibration and testing laboratory that offers on-site thermal calibration for refrigerators, freezers, ovens, furnaces, and other lab equipment.

We ensure that each machine and instrument is on par with industry standards to deliver accurate results for your lab. Request a quote for our calibration services.

How To Properly Use A Biosafety Cabinet (BSC) In Labs

In the market several kinds of Biosafety cabinets are available and selection is based on the nature of the research/application. Biosafety Cabinets (BSCs) are divided into classes (I, II, and III) and types (A, B, C).

Class II cabinets are designed to protect the research material as well as the worker and the environment. Both the supply air and the exhaust pass through a HEPA filter.

There are four types of Class II cabinets. Class II Type A2 cabinets (formerly labeled Type A/ B3) have a number of design features that make them more useful in research laboratories than other Class II cabinets.

A Class II biosafety cabinet (BSC) is a ventilated cabinet that provides personnel, product, and environmental protection. It is designed for use with biological agents that pose a moderate or high risk of infection.

There are three types of Class II BSCs:

* Type A2 cabinets have a unidirectional airflow pattern that provides product protection.

* Type B1 cabinets have a turbulent airflow pattern that provides personnel and environmental protection.

* Type B2 cabinets have a unidirectional airflow pattern that provides personnel, product, and environmental protection.

All Class II BSCs have an open front with a sash that can be raised or lowered. The sash is designed to create a negative pressure inside the cabinet, which helps to prevent the escape of airborne contaminants.

The air inside the cabinet is drawn through a HEPA filter, which removes 99.97% of airborne particles. The filtered air is then exhausted from the cabinet through the back or top.

Class II BSCs also have a work surface that is covered with a non-porous material, such as stainless steel. This helps to prevent the spread of contaminants from the work surface to other areas of the laboratory.

Here are some additional details about how a Class II BSC works:

* The air flow rate inside the cabinet is typically between 75 and 100 linear feet per minute (FPM). This helps to keep the cabinet under negative pressure and to prevent the escape of airborne contaminants.

* The HEPA filter in the cabinet removes 99.97% of airborne particles that are 0.3 microns or larger. This helps to protect the user from exposure to harmful biological agents.

* The non-porous work surface in the cabinet helps to prevent the spread of contaminants from the work surface to other areas of the laboratory.

* Class II BSCs are an important tool for the safe handling of biological agents. They can help to protect users from exposure to harmful pathogens and to prevent the spread of contamination.

Here are some additional safety tips for using a Class II BSC:

* Always wear personal protective equipment (PPE) when working in a Class II BSC, such as gloves, a lab coat, and safety glasses.

* Never reach into the cabinet with your bare hands.

* Always use a pipettor or other safe transfer device to transfer materials in and out of the cabinet.

* Never open the sash when the cabinet is in use.

* Inspect the cabinet regularly for leaks and damage.

* Report any problems with the cabinet to the laboratory supervisor.

By following these safety tips, you can help to ensure the safe use of a Class II BSC.

How to Properly Use a Biosafety Cabinet (BSC) in Labs

Installation. Choose a location away from pedestrian traffic, doors, and air currents generated by room ventilation, all of which can disrupt airflow.

The BSC must be re-certified after movement and installation at the new location.

NOTE: Even small moves can disturb the HEPA filter and therefore, re-certification is necessary.

Certification. The certification process ensures that the Biosafety Cabinet is working as designed. Annual re-certification is required for all BSCs used for work with biohazards, and is the responsibility of the laboratory or the department office. Contact us for NSF49 Certified BSC Equipment.

Choosing Right Biosafety Cabinet For Your Laboratory

For many laboratory owners seeking to effectively dry their samples, forced air ovens have become a popular option. Forced air ovens, which have forced, blower-assisted ventilation designs, provide better temperature consistency and quick heat recovery than other varieties of drying ovens.

Continue reading to find out what a Forced Air Oven is and in which industries will Forced Air Ovens be commonly utilized.

What are the Forced Air Ovens?

Forced air drying ovens are essential equipment in laboratory and industrial settings for various thermal processing applications such as drying, curing, and baking. The blower-assisted airflow design of these ovens ensures excellent temperature uniformity and fast recovery. These ovens come equipped with a turbo blower and heavy-duty motor that directs air over the shelves and samples, resulting in even, constant drying. They are particularly useful for drying glassware and oxide carbonization, among other applications. On the other hand, vacuum drying ovens are used to conduct thermal processes in an airtight chamber under a desired level of vacuum. They are useful in preventing surface reactions, decontaminating samples, and speeding up the outgassing process. When selecting a laboratory vacuum oven, it is crucial to consider the appropriate chamber size, desired vacuum level, and the necessary pump size to meet the application requirements.

In which industries will Forced Air Ovens be utilized?

Forced air ovens are extensively used in a variety of sectors where thermal processing is required. Their sophisticated features and design make them versatile instruments for a wide range of uses, from R&D to manufacturing and quality control. The following are some of the sectors that frequently use forced air ovens:

1. Pharmaceutical industry: In the pharmaceutical industry, forced air ovens are widely used for a variety of applications such as drying, sterilizing, and dehydrogenation of glassware, containers, and instruments used in drug manufacturing. Forced air ovens are also used for the stability testing of drug products and for the preparation of drug samples for testing.
2. Food industry: Forced air ovens are extensively used in the food industry for various applications such as baking, drying, roasting, and dehydrating food products. They are commonly used for the production of baked goods such as bread, cakes, and cookies, as well as for the drying of fruits, vegetables, and herbs.
3. Automotive industry: In the automotive industry, forced air ovens are used for various applications such as the curing of paint, drying of coatings, and curing of composite materials. The ovens are used to heat parts and components to a specific temperature to cure coatings or adhesives, and to remove moisture or solvents from painted or coated surfaces.
4. Electronics industry: In the electronics industry, forced air ovens are used for the curing of conformal coatings and encapsulating materials used in electronic components. They are also used for drying and curing of printed circuit boards (PCBs) after washing and for the removal of moisture from electronic components.
5. Aerospace industry: In the aerospace industry, forced air ovens are used for various applications such as curing of composite materials used in aircraft structures, drying of paints and coatings, and testing of aerospace components. They are also used for the preparation of spacecraft components for launch by removing moisture and other contaminants.

Ai High-Quality Lab Forced Air Drying Ovens:

The process of drying is a fundamental operation carried out in various research laboratories. Hence, it is essential to carefully choose a drying oven that delivers an excellent drying performance without incurring high operating costs.

Ai Air Forced Air Drying Ovens Features:

• Great for medical device drying and sterilization.
• Built-in temperature calibration.
• Forced-air circulation combined with digital temperature control achieves a dependable and uniform environment for a variety of laboratory applications.
• Corrosion-resistant stainless steel interior finish with toughened double-glazing observation window.
• Gentle downward flow along the chamber wall provides less disruption to sample material.
• Adjustable moisture escape port.
• Overheat protection automatically cuts power when the temperature is beyond the limit or the sensor fails.
• UL/CSA certified, CE certified, cGMP ready

See the chart below for unit-specific features

Investing in a high-quality lab oven from a trusted manufacturer is crucial for any laboratory’s success. Ready to upgrade your lab with a high-quality lab oven? Look no further than Across International. Our selection of top-of-the-line lab ovens is designed to meet the demands of professionals like you, providing the reliability and precision you need to complete your research and processes with ease. Don’t settle for subpar equipment. Request a quote today and take the first step towards enhancing the efficiency and accuracy of your lab.

Choosing Right Biosafety Cabinet For Your Laboratory

Working with biohazardous materials in a laboratory requires the use of a biosafety cabinet to ensure the safety of lab personnel and the environment. Selecting the right biosafety cabinet for your laboratory is crucial and requires a thorough evaluation of the risks and hazards associated with the work being done. In this blog post, we will discuss the key factors that should be considered when choosing a biosafety cabinet for your laboratory.

Choosing the Right Biosafety Cabinet:

Choosing the right biosafety cabinet involves evaluating factors such as the type of materials used, the risk level of the work, the volume of materials, and the work practices and procedures. Physical characteristics of the cabinet, including size, airflow patterns, and filter type, should also be taken into account. Evaluating these factors will help laboratory managers select the most appropriate biosafety cabinet for their laboratory, ensuring the safety of personnel, the environment, and the integrity of research.

Key Factors to Consider When Buying or Upgrading:

When buying or upgrading a biosafety cabinet, primary considerations should always be safety and preservation of samples. Size, price, and operating costs are also important considerations. Ergonomics, usability, customization, and available options should also be taken into account. Modern Class II BSCs have more stringent design requirements and may provide increased safety compared to older models. Look for a cabinet that compensates for normal filter loading and alarms if airflows change too much. Reconsider the need for external exhaust, which can be expensive and complex to operate safely. Consider energy efficiency and the total cost of ownership. 

• Primary considerations should always be the safety and preservation of samples. 
• Factors such as size, price, and operating costs are also important considerations. 
• Ergonomics, usability, customization, and available options should also be considered. 
• Modern Class II BSCs have more stringent design requirements and may provide increased safety compared to older models. 
• Look for a cabinet that compensates for normal filter loading and alarms if airflows change too much. 
• Reconsider the need for external exhaust, which can be expensive and complex to operate safely. 
• Consider energy efficiency and the total cost of ownership. 

To make an informed selection and select a biosafety cabinet that best matches your laboratory’s unique demands, it is critical to thoroughly analyze all of these criteria. Keep in mind that safety should always come first. 

Maintaining and Using Biosafety Cabinets:

To keep biosafety cabinets running smoothly, proper maintenance and use are crucial. Have your Class II cabinet certified regularly to ensure it follows the NSF/ANSI Standard #49-2009, which ensures both the safety of the user and the sterility of the work. The “Biosafety in Microbiological and Biomedical Laboratories (BMBL) 5th Edition” by the CDC and NIH is an excellent resource for understanding the unique features of your cabinet. Routine maintenance should include field certification of your Class II BSC at least once a year.

Selecting a Biological Safety Cabinet:

When purchasing a biological safety cabinet, it is important to consider the type of work that will be conducted within it. Table 1 provides an overview of Ai Biosafety Cabinets’ specifications for all size units to help you make an informed decision. Thoroughly evaluating these factors will help ensure that you choose a biosafety cabinet that is the right fit for your laboratory’s specific needs.

Choosing, upgrading, and maintaining a biosafety cabinet is critical to ensure safety for laboratory workers and the environment. By evaluating factors such as the type of agents or materials used, risk level of the work, volume of materials, and work practices and procedures, laboratory managers can choose the most suitable biosafety cabinet. Additionally, it’s crucial to have the biosafety cabinet certified regularly and conduct routine maintenance to ensure it’s running properly. Contact us for NSF49 Certified BSC Equipment, we also offer the calibration service for more laboratory equipment.  

One of the major causes of deterioration of vaccines in the USA is improper refrigeration. Moreover, accidental freezing destroys temperature-sensitive vaccines in many cases. Today, research laboratories and pharmacies have recognized the differences between scientific and standard cold storage solutions.

At AI Medical, we provide innovative pharmacy and vaccine cold storage solutions designed specifically to store vaccines, biological specimens, and samples. It is also important to place vaccines at the right place inside the refrigerator or freezer for optimal temperature control. This helps in protecting the vaccines from potential damage and errors.

Unlike the standard refrigerators and freezer models, our scientific cold storage solutions are high-performing, giving precise temperature control to store high-value and critical storage like vaccines. This specialized equipment meets the CDC requirements for cold storage of temperature-sensitive samples and products.

How to Select the Right Storage?

Selecting the right cold storage solution is critical to the integrity and safety of pharmacy products and vaccines. When you need to equip your laboratory or pharmacy with a refrigerator, you need to consider certain things.

What To Know When Choosing a Medical Refrigerator

Several medical refrigerator choices are available in various styles, so there is no one-size-fits-all solution. Here are some factors which you should consider when selecting the right vaccine cold storage solution.

• Consider the type of refrigerator or freezer
• Size of refrigerator or freezer
• Placement in the laboratory or pharmacy
• Other features such as self-closing doors, medical-grade cords, etc.
• Requirements of temperature for storing vaccines
• Shelving for ensuring proper flow of air

The Right Freezer for Your Needs

According to the CDC recommendations, the right freezer is purpose-built and pharmaceutical-grade units designed specifically for storing vaccines and samples. These freezers can have under-the-counter style, compact or large, depending on your storage and placement needs.

Purpose-built units usually offer maximum temperature control via the microprocessor and have a digital sensor for temperature. Plus, they also have powerful fan-forced air circulation or multiple vents for cool air. This helps in promoting uniform and fast recovery of temperature when the temperature is out of range. In order to ensure the full safety of your costly vaccines, your freezer should have ample space to accommodate the maximum number of inventory without overcrowding.

AI Medical provides a wide range of state-of-the-art refrigeration and freezer units designed to protect and safely store your vaccines. Our latest technology ensures to minimize your costly vaccine losses and maximize your cold storage.

The Coronavirus outbreak has negatively affected many places around the world. Efforts are underway to introduce vaccines in response to the Coronavirus pandemic. As vaccines are ready to get into the distribution phase, the medical world expects a severe cold storage crisis.

Now the question is how cold storage units such as ultra-low freezers safeguard vaccines and biological substances that the demand for them is on the rise. 

So, Why are Ultra-low Freezers in Demand, and How Do They Help? 

When it comes to vaccines or other biological substances, their chemical structures are such that they share a strong resemblance with dairy products in terms of storage requirements. Hence, it is very important to comply with these storage requirements so as to keep their integrity and effectiveness intact. 

It is for this same reason that ultra-low freezers are in demand as it helps when it comes to retaining the chemical structure of these vaccines and biological substances. 

These ultra-low freezers cater to vaccines. They have pharmaceutical approval to store vaccines, whether they need to be refrigerated or frozen. Dormitory or bar-styled refrigerators are don’t have the temperature regulation for vaccines. 

Moreover, ultra-low freezers come with a microprocessor in combination with digital sensors. This something that vaccines require as it is important to probe their temperature levels every now and then. 

In addition to this, cold storage units such as ultra-low freezers have such a design that they are spacious enough to accommodate a maximum number of vaccines without any overlap or overcrowding.

The vaccines comprise a particular set of active ingredients that is responsible for providing immunity to patients. These ultra-low freezers come with cooling systems that help in preserving these active ingredients. When a vaccine is at room temperature, even for just an hour or two, the active ingredients can lose their potency. 

This is why ultra-low freezers are important throughout both the production and distribution phase in order to keep the active ingredients effective.

These freezers come with multiple features, including alarms, such as to facilitate the remote opening of doors and to notify immediately should a power failure occurs. They are also equipped with alarms that notify in case a compressor failure occurs.

The drawers to facilitate the storage of other biological substances such as plasma and human cells are removable to easily access them. 

Conclusion

Even the slightest mismanagement of these vaccines can result in serious consequences. Considering that the vaccines are on their way and demand for these cold storage units is only soaring with each passing day, we cannot stress enough how important it is for the medical facilities to focus on buying them. If you don’t know where to go, don’t worry at all!

Feel free to reach out to Ai Medical Tech Team. We assure you that you won’t be disappointed as customer satisfaction is what our business thrives on. We are just a call away! 

While thousands of Americans look forward to the distribution of the Covid-19 vaccine, it just boils down to one pressing question: do medical facilities have enough freezers to store them?

With healthcare facilities such as pharmacies, clinics and hospitals turning into vaccination sites, very few of them have deep or ultra-low freezers to facilitate storage. This is creating a mad rush and the public-health and logistics industry is working hard to devise a cold storage chain that can facilitate the delivery of vaccines without losing their integrity and effectiveness.

Vaccine Storage Equipment 

When it comes to vaccines, their storage requirements are similar to that of dairy and meat variants, such as ice creams and steaks in marts. They need a particular temperature range for storage. The ultra low temperature retains its chemical structure.

The drug industry seems to have lots of information when it comes to knowing the ideal temperature range to store vaccines for chickenpox as well as shingles. However, when it comes to the COVID-19 vaccine, researchers lack the data as clinical trials with respect to storage requirements are still in progress.

The reason that deep freezers are turning into a hot commodity is that vaccines are the only key to stop the spread of the deadly coronavirus. And, as these vaccines start making their way into the markets, a terrible cold-storage shortage is set to come up. As clinical trials and testing approach phase 3, pharmaceutical companies expect to distribute vaccines to different vaccination sites by the end of 2020 or as 2021 commences. Considering that the time of distribution is fast approaching, many clinical facilities have yet to make the necessary arrangements to store the vaccines when they arrive.

The two largest pharmaceutical companies in the vaccination race, have worked towards vaccines bearing special technology, which they call mRNA. It is a gene-based technology that requires storing the vaccine shots at ultra-low temperatures. To make this possible, medical sites need to be well-equipped in terms of deep freezers or, to put it exactly, ultra-low freezers.

However, ultra-low freezers are not really a common sight in healthcare facilities as most medications and vaccines don’t as such need them. While chickenpox vaccines are stored in the freezer, flu vaccines require simple refrigeration.

With COVID-19 vaccines, it is important to acquire deep freeze facilities in order to maintain its effectiveness. After all, the vaccine already comes with a short shelf life, regardless of meeting ultra low-temperature requirements. In fact, they must be utilized within six months.

It is important to have the right facility in terms of storage for COVID-19 vaccines. These preparations will determine the course of distribution.

A lack of deep or ultra low freezer will mean that the access to these vaccines shall vary from country to country. This is because experts intend to target countries based on appropriate storage facilities when it comes to vaccine distribution.