The ubiquitous -80°C freezer is, without a doubt, the workhorse freezer of cryopreservation labs across the world. Rows and rows of these freezers are lined up in labs, research areas, hospitals, universities, bio banks and more, humming round-the-clock, day-in and day-out. Protecting and preserving countless samples of irreplaceable specimens is their mien, proud soldiers on the front lines of research.

Compressor based mechanical freezers such as the -80ºC certainly have their benefits. They also have a few major drawbacks that many lab managers and supervisors are well aware of. Mechanical freezers for cryopreservation utilize power, a lot of power, like any other freezer, to maintain the given temperature parameters for the storage of the specimens contained within. Mechanical freezer manufacturers assert that a uniform low temperature in their freezers provides the same reliability as their counter part, an LN2 system. Part of this may be true, but at what expense can mechanical freezers make this claim. Mechanical freezers are just that, mechanical. They, like hard drives, will fail at some point for any variety of reasons. Electrical power loss, compressor failure, motor failure, or more will quickly take a freezers required freeze temperature down very quickly, and, in the cryopreservation industry, failure is not an option. It has been reported that the probability of failure in a mechanical freezer is 1:100 to 1:1,000 while the probability of failure in an LN2 system is 1:10,000 to 1:100,000, that’s a 100-to-1 ratio.

Mechanical freezers have long been the paradigm for cryogenic storage facilities, but few are ready to admit that they are challenging their own fate. In 2012, a major Boston brain bank repository had a failure event that caused one-third of their stored brain specimens to be rendered useless. The loss of this priceless collection was said to have pushed back research on a variety of brain disorders at least ten years. That same year, a freezer failure in Chicago lost the sperm samples of forty individuals, resulting in not only millions of dollars of monetary damages, but also a resulting negative public and professional perception. The list and incidences of mechanical freezer failures is long and unfortunately has its blemishes, but despite technological advances, they will unfortunately continue. Lab directors worldwide are acutely aware of the possible, and maybe imminent, dangers of mechanical freezers.

Lab directors are also constantly reminded how much it costs to keep these freezers running. Depending on the model, size, and manufacturer, mechanical freezers are expensive to run just by their very nature. In most labs with a redundant emergency plan in place, a freezer will require a dedicated 120 amp circuit, drawing power around the clock, 24/7/365. Additional alarms, backup systems, monitoring devices and more electrical needs also drive the power needs and electric costs up. Additionally, because mechanical freezers throw off a large amount of heat, interior climate control costs have to be factored in. A recent self-assessment report conducted at The Mayo Clinic reported that it would cost upwards of $100,000 to keep 150 upright -80º freezers up and running, and that doesn’t factor in other ambient power needs. Just as lab directors are looking at power needs and costs, so too are state and federal environmental agencies.

California’s Global Warming Solutions Act – the harbinger of global warming policies, was launched in 2006 and brought into full force in January of 2013, has become the most extensive mandate for carbon dioxide emissions control regulations in the US. Originally aimed at large manufacturers, power plants, and other high-energy users, the act was a comprehensive set of carbon-cap guidelines that has now been adopted by many other states as well as the Environmental Protection Agency. Recently as part of the over-arching policies, the focus of these agencies has been moving towards a second tier of high-energy users, specifically, data centers, marijuana growers and most importantly, cryogenic storage facilities. While these market sectors are not considered manufacturers, they are by their nature grouped together in an auspicious category of high-energy users. State and federal regulators are now looking closely at these entities and are requiring a new set of standards and practices for labs to reduce their power usage. Cryogenic storage manufacturers have already begun to address the issue of reducing the energy consumption in their products, but many ask if that’s a viable long-term solution.

Many forward thinking labs are already adopting plans to convert their mechanical freezers over to safer, less power hungry freezer systems that utilize either liquid LN2 or vapor phase storage. In many cases, storage facilities already have a number of LN2 freezers in their labs as a backup system for if, or when, a mechanical freezer malfunctions, allowing for exposed specimens to be manually removed and safely stored until repairs or replacement can be made. This backup plan does have it’s own drawbacks. The process of removing vial boxes from drawers in the freezer takes precious time that exposes the specimens to ambient temperatures that may further degenerate the integrity of the specimens. If a lab has a number of freezers that are affected, the process can literally take hours to transfer specimens from a mechanical freezer to an LN2 freezer from the racks they reside in. A new rack and frame system developed by ColdStash helps speed up the process because the vial boxes are snuggly self-contained, allowing for whole drawers of boxes to be transported as opposed to individual boxes. The transition from one freezer to the other is seamless, and can be a long-term permanent solution for storage, but it doesn’t completely address the need for labs to convert their freezer storage methodologies.

While many labs are looking at the inevitable change over from mechanical freezers to an LN2 system, the change may be hampered by the cost of new freezers and how aggressive state and federal agencies clamp down on new regulations. Today’s need to minimize carbon emissions and reduce ozone damage means it is important to ensure that any laboratory is as environmentally friendly as possible. Therefore, providing equipment for long-term low-temperature storage that requires minimal energy without emitting any noise or heat pollution enables researchers to concentrate on the complexities of the freezing process with the knowledge that their cryogenic experiments are extremely environmentally friendly. Liquid nitrogen storage enables convenient in-lab placement with no noise or heat pollution. Furthermore, they maintain low temperatures for very long storage periods without consuming electricity. This cost-effective method not only saves on laboratory resources, maintains a higher level of specimen security, reduces carbon emissions, but also is extremely friendly to the environment.

Tim Claflin
President
OneTen Communications Group
Saunderstown RI

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