Optimize Cryogenic Storage for Life Sciences
eBook
Published: December 4, 2024
![Close-up view of translucent cells with blue interiors, highlighted against a soft blue and purple gradient background](https://assets.technologynetworks.com/production/dynamic/images/content/393969/optimize-cryogenic-storage-for-life-sciences-393969-960x540.jpg?cb=13113590)
Credit: Azenta
In the dynamic world of life sciences, preserving the integrity of biological samples is essential. However, inconsistent storage strategies can compromise sample viability and lead to inefficiencies.
Organizations often struggle with scalability, compliance and cost-effectiveness when selecting the best cryogenic storage solutions.
This guide provides actionable insights into choosing the right storage solutions, leveraging automation to enhance accuracy and implementing scalable practices tailored to your lab’s unique needs.
Download this eBook to discover:
- Key factors to consider when choosing storage solutions tailored to your needs
- How automated systems reduce human error and enhance scalability
- Best practices for ensuring sample viability and regulatory compliance
A COMPREHENSIVE GUIDE
FOR DECISION MAKING
CRYOGENIC
STORAGE
SOLUTIONS
IN LIFE
SCIENCES
Introduction............................................................................................................................................3
Understanding Cryogenic Storage Options.......................................................................................4
Factors Influencing Storage Decisions...............................................................................................9
On-Site Cryogenic Storage..................................................................................................................11
Automated Cryogenic Storage Systems............................................................................................14
Off-Site Storage Solutions...................................................................................................................17
Choosing the Right Solution................................................................................................................19
Implementing and Managing Cryogenic Storage Systems............................................................21
Case Studies and Success Stories...................................................................................................24
Conclusion............................................................................................................................................28
CONTENTS
The National Institutes of Standards
in Technology defines cryogenic as
temperatures -150° C or lower.¹ These
extremely low temperatures influence
the rates of water transport and
nucleation of cells that maintain sample
integrity.² Such low temperatures also
ensure the stability of samples during
transportation and manufacturing.
Numerous studies suggest that even
brief instances of warming, arising
from temporary exposure to room
temperatures, can have detrimental
effects on the viability of cellular
materials, subsequently influencing
patient outcomes.³ ⁴ ,
3
In today’s life sciences industry, no company handling biological samples or
genetic material can afford to overlook the growing importance of creating a
scalable, dependable approach to cryogenic storage. Despite its important
role, sample management often takes a backseat due to more immediate
concerns, leading many companies to delay planning for its complex and specific
requirements.
Maintaining sample integrity at ultra-low and cryogenic temperatures entails
more than simply employing freezers capable of reaching a specific temperature.
It demands a comprehensive plan that takes into account the right type of
containers, equipment, and facilities that are equipped with proper ventilation
and back-up power supplies. Staff training and labor requirements, as well as
maintaining supplies of essential chemicals like liquid nitrogen, must also be part
of any plan. These considerations should be factored in from the very beginning to
ensure effective decision-making.
While most companies recognize the importance of scalable cryogenic storage,
they may not fully comprehend the long-term effects that manually accessed
storage with limited documentation and traceability could impose on their
operations. Additionally, they may overlook potential scalability issues that
can arise as they shift from R&D to large-scale clinical trials. By the time they
acknowledge the need for space, equipment, and funding, their choices may be
limited.
That’s why it’s critical to consider all factors that might impact your development
and manufacturing process before selecting a cryogenic storage system.
This comprehensive guide explores various options, examines the pros and cons of
each, and discusses other influential factors that will affect your decision-making.
The Science Behind Cryogenics:
Why It Matters
INTRODUCTION
UNDERSTANDING CRYOGENIC 1 STORAGE OPTIONS
5
Understanding Cryogenic Storage Options
Manually Accessed or Automatic Cryogenic
Storage Systems?
MANUALLY ACCESSED CRYOGENIC STORAGE
Manual on-site storage, a common choice for small life sciences companies
due to its lower startup costs, requires labor-intensive tasks. Personnel are
responsible for loading samples, monitoring environmental conditions such
as temperature and humidity, recording data, and refilling compartments with
liquid nitrogen. Although initially cost-effective, it’s time consuming and prone
to human error, risking sample loss or damage.
Additionally, manual handling of cryogenic materials poses safety risks.
Without adequate protection, employees face exposure to extremely
cold temperatures, and potential spills or leaks can create a hazardous
environment.
From an ergonomic standpoint, manual storage is challenging. The need to
use bulky safety equipment, climb ladders, and bend over tanks not only
increases the risk of physical injury, but is also time consuming. Locating the
correct sample often entails visually searching through multiple racks, possibly
exposing other samples to ambient temperatures. This process also increases
the risk of samples being misplaced, removed, or damaged. Furthermore,
manual systems often lack robust access control, increasing the risk of
When it comes to the cryogenic storage of materials, you typically have two
choices: house them on-site or establish an agreement with another entity
to store them off-site. Both options come with their own set of pros and
cons. Wherever you choose, the facility could either be manually operated or
equipped with an automatic cryogenic system. Each of those systems also
presents its own benefits and drawbacks.
unauthorized access or mishandling of samples. The absence of reliable audit
trails further complicates matters, making it difficult to accurately track the
history of samples.
AUTOMATED CRYOGENIC STORAGE
Automated cryogenic storage systems leverage software to oversee tasks
related to biological sample management. These systems use advanced
robotics, automated sample handling, computerized monitoring, and control
systems to manage cryopreserved materials. Unlike manually accessed
storage freezers, automated cryogenic systems offer heightened precision,
significantly minimizing the occurrence of errors due to human oversight.
They are also capable of identifying potential bottlenecks and pinpointing
opportunities for improved efficiency.
The initial investment for these systems can be substantial due to the
complex machinery required for automation. However, the long-term benefits
– including reduced human error, increased efficiency, and sample integrity –
often justify the expense. Particularly when dealing with
high-value, critical, or fragile samples, automated systems can provide the
best return on investment (ROI). Equipped with sensors and alarms, they
maintain stable temperatures even during sample selection and alert users
to any irregularities. While the initial investment is higher, the long-term
benefits and efficiency gains tend to outweigh these upfront expenses.
Space is another key consideration: will an automated system fit in the space
allocated? Some automated systems demand larger rooms, additional floor
space, special ventilation, utility connections, access aisles, or double-wide
doorways. They might also require additional IT management. By taking these
factors into account, labs can ensure smooth operation and optimal use of
automated cryogenic storage systems.
On-Site vs. Off-Site Cryogenic Storage Systems
Life sciences companies face a crucial decision on where to store
their biological samples: on-site or off-site? Both options offer distinct
advantages and disadvantages, necessitating a strategic evaluation
based on the company’s specific needs and resources.
The decision to either invest in building an in-house facility versus
outsourcing, particularly for companies developing novel therapies, is
largely influenced by their philosophy and strategy. Many organizations
lack the resources and infrastructure to manage all their clinical trial
materials, which can range from proteins, cells, and viruses to blood
products and bacteria, each with different storage conditions and
temperature requirements.⁵
6
Labor Safety Costs Space
Automated
Manual
Requires
personnel to
be responsible
for loading
samples,
monitoring
temps and
humidity levels,
recording
data, refilling
compartments.
Poses safety risks
such as exposing
personnel to
extremely cold
temperatures
and creating
a potentially
dangerous
environment due
to the risk of spills
or leaks.
Low initial
startup costs.
Low initial
startup costs.
Leverages software
to manage
tasks related to
biological sample
management.
This includes
advanced robotics,
automated
sample handling,
computerized
monitoring, and
control systems
to manage
cryopreserved
materials.
Heightens
precision,
significantly
minimizing the
occurrence of
errors resulting
from human
oversight, detects
bottlenecks,
and identifies
opportunities
for increased
efficiency.
Higher upfront
cost that may
offer a return
on investment
only after scaleup or when a
large volume of
samples are being
managed.
May require
extended height
rooms, increased
floor space,
ventilation
systems, utility
connections,
access aisles,
double-wide
doorways, and
additional IT
management.
Erica Waller
Senior Product Manager
Azenta Life Sciences
One of the most critical aspects of on-site storage is data management and tracking. Investing in IT
infrastructure and sample management tools empowers sample managers to spend less time maintaining their
collection and more time focusing on their research.
7
Sue Holland-Crimmin
Ph.D., Scientific Consultant
Thus, it’s crucial to conduct a comprehensive cost analysis upfront, factoring in
hidden expenses like real estate per square foot, facility expenses, automation,
labor, and training. This thorough analysis often dictates whether to keep
storage in-house or entrust it to external partners. Moreover, certain types
of materials might be more suitable for off-site storage due to their specific
requirements or the limitations of the organization’s in-house capabilities.⁵
On-Site Storage Offers Convenient Access
Biotech and pharma companies often opt for on-site storage of their
biological samples, appreciating the convenience and efficiency it
provides, especially for highly transacted critical materials. On-site
storage is recommended for materials requiring frequent access,
assuming that the proper storage conditions, labeling, tracking, and
training are in place. In addition, investing in IT sample and inventory
management tools can enable scientists to effectively manage and
access these materials.
However, running an in-house storage facility requires careful planning.
Companies must maintain suitable storage conditions and ensure that
Compared to small molecules, cells are highly
labile. They’re only viable over a narrow range of
time and temperature and therefore require justin-time delivery to patients or cryogenic storage
to preserve those cells. A lot of organizations
haven’t developed that skill in-house.
all materials are accurately labeled and tracked. Providing adequate
training for staff is also key to managing these materials safely. Investing
in IT sample and inventory management tools can provide great value,
granting scientists real-time access and control over their inventory,
ensuring they have the materials they need, exactly when needed.⁵
Off-Site Storage Provides Process
Rigor and Backup
Establishing an Optimal Strategy for Biological
Sample Storage: A Hybrid Approach
Conversely, off-site storage offers advantages like cost savings and improved
data integrity. However, a comprehensive cost analysis—considering factors
like real estate, facility expenses, automation, manpower, and training—is
essential before outsourcing.
Materials accessed less frequently or those reserved for disaster recovery,
could be better suited for off-site storage with a reliable partner. Numerous
organizations specialize in the management, access, and transportation of
these materials. Off-site sample management providers often have robust IT
infrastructures for material tracking and state-of-the-art automation systems,
which are crucial for maintaining and monitoring materials at low temperatures.⁵
To establish an optimal strategy for storing biological samples,
biotech and pharma companies may want to consider a hybrid
approach, combining both on-site and off-site storage solutions.
This method balances convenience and efficiency, especially for
frequently transacted critical materials.⁶ In the dynamic world of
clinical research, organizations must strategically identify areas
where their skill sets and resources can be most effectively utilized
to maximize impact.
*When choosing an off-site partner, be sure they have systems in place to mitigate any "cons".
8
Sue Holland-Crimmin
Ph.D., Scientific Consultant
A lot of clinical trials require you to hold
specimens for 10 or 15 years. You’re
probably not going to hold those within
your own facilities. It‘s best to find an
appropriate partner to maintain those, and
you can access them readily if you need to.
On-Site Off-Site
Cons
Pros
• Control
• Accessibility
• Customization
• Upfront costs
• Space requirements
• Operational responsibilities
• Expertise and compliance
• Scalability
• Predictable costs
• Latest technology and Informatics
• Limited control
• Transportation risks/dependency
• Data privacy/management
• Disaster backups
FACTORS INFLUENCING 2 STORAGE DECISIONS
Factors Influencing Storage Decisions
10
Key Takeaway
1
5
2
6
3
7
4
8
What types of samples will
you be using? What will
your sample volume be
like? What kinds of capacity
requirements do you have?
How easily can you scale
up?
How can this storage
option support your goals
of data integrity? How
securely can your solution
maintain the cryogenic
samples and how well can it
protect data?
Do you have budget for
cryogenic storage? How
much do you have budgeted
for operational expenses,
routine maintenance,
employees, and software?
What kind of consumables
and container types are
required for the cryogenic
samples? Will automation
be of interest in the future
and if so, what features will
support or prevent the use
of automation?
How reliable is your storage
solution? If something goes
wrong, how long will you have
to fix it, and will immediate
human intervention be needed?
What kind of maintenance
procedures need to be in
place? What power-failure
backups are in place?
What kinds of costs and
space considerations do
those containers take?
What kind of accessibility
do you need? How fast
do you need to retrieve
samples?
What regulations and laws
do you need to consider
with this type of storage?
Do you have compliant
data accessible? Do you
need to keep audit trails
that include temperature
excursion records?
When choosing an automated cryogenic
storage system, consider sample volume and
capacity, the budget available for upfront
and ongoing costs, reliability, accessibility,
data integrity, and regulatory compliance.
Biological samples, including tissues, cells, DNA, RNA, and proteins, require
appropriate cryogenic storage to ensure their integrity and prevent degradation.
Numerous factors should be considered when planning how they will be stored:
3 ON-SITE CRYOGENIC STORAGE
Considerations for On-Site Storage
Advantages of On-Site Cryogenic Storage
On-Site Cryogenic Storage
Considerations for Emerging Companies
On-site cryogenic storage consists of housing all of your cryogenic samples at
your company’s facilities. Rather than deploying a software system to regulate
all the freezing units, the process is conducted manually. This means that
tasks such as temperature monitoring, data collecting, and sample retrieval,
among others, are often carried out by personnel.
For successful on-site cryogenic storage, you’ll need to consider every
variable since you’ll be managing duties internally. Employees, who are the
backbone of operations and in high demand for their rare skillset as noted by
McKinsey,³ need a facility adequately equipped. Managing the entire process
requires you to factor in equipment and maintenance costs, since these
won’t be outsourced. Strict adherence to protocols, detailed record-keeping
of sample access, transportation locations, and times must be maintained.
Training staff on how to avoid transient warming of samples during the
selection process is also key.
With on-site cryogenic storage, you gain full authority over your samples,
letting you set up preferred conditions and specific access guidelines for your
team, in line with your facility’s requirements. This ensures any researcher
requiring daily access to certain samples can get it. Furthermore, on-site
storage offers boundless customization possibilities, enabling you to design
your facility according to your precise needs.
Small-scale operations have additional considerations to keep in mind. Budget
constraints often lead emerging life sciences companies to opt for manual
access on-site cryogenic storage, requiring careful allocation for protective
equipment, storage containers, and waste management. Despite these
financial limitations, safety and maintenance protocols must not be
compromised and should be strictly enforced. For smaller companies
in product development or preclinical stages, this on-site solution
could be adequate, given their typically lesser need for extensive,
long-term storage.
12
● Cryo gloves
● Face shields
● Cryo aprons
● Cryo carriers/carts
Types of Cryogenic Equipment and Accessories:
● Dry shippers
● Dewars
● LN2 transfer hoses
● Phase separators
Safety training for employees and emergency preparedness plans
Regular maintenance of machines
Adequate ventilation and insulation
Routine cleaning and defrosting
Regular calibrations and inspections
Proper containerization, filling, and labeling practices
Backup systems for power outages
Emergency process procedures
Handling and Maintenance Protocols Checklist:
For more insight on setting up your
own cryogenic facility, download our
guide “A Practical Guide to Planning a
Cryogenic Storage Facility”
Resources
Key Takeaway
Maintaining your own on-site cryogenic
storage means you have more control
and customization, but you also take on
the burden of creating and managing all
the protocols yourself.
13
AUTOMATED CRYOGENIC 4 STORAGE SYSTEMS
Additional Reading
Automated Cryogenic Storage Systems
15
For companies with more extensive storage needs or rigorous digital
record-keeping requirements, automated cryogenic storage systems can
be game-changing. These systems leverage technology and software
to execute numerous tasks, including temperature monitoring, sample
retrieval, sample labeling and locating, data recording, and integration,
as well as issuing alerts. They provide audit trails that support digital
transformation and regulatory compliance.
Automated systems also provide an optimal solution for scaling. Their
software can detect bottlenecks and identify areas for optimization, thereby
fostering rapid growth. Furthermore, automated cryogenic storage systems
are available in different sizes, enabling you to select a product that aligns
with your company’s size and current scale.
For example, Azenta provides automated storage systems that span
the spectrum from small enough to fit into a clinical space, such as the
CryoArc™ Pico -190°C LN2-Based Automated Storage System, to larger
systems such as the CryoArc™ Tera -190°C LN2-Based Automated Storage
System, that fulfill larger capacity storage needs. With options designed
to cater to collections of various sizes, you can find one that fits your
needs the best. Recognizing both your current and future sample storage
requirements, along with an awareness of your present and anticipated
spatial constraints, is crucial in selecting the optimal system for your needs.
An important advantage of automated storage systems is the control of
sample exposure to ambient temperatures. Maintaining consistent cryo
temperatures during the picking process and avoiding the exposure of
innocent samples to transient warming supports greater cell viability.⁴
Read our blog “Cryostorage for Cell Therapies:
Addressing Standardizaton Obstacles”
to understand how automated cryogenic
storage could benefit your company.
Why automate? Read our blog to explore
the benefits of automated sample storage.
Additional Reading
Considerations for Types of Compatible Containers
When opting for automation, consider the type of containers
used in your facility. Automation can be container specific,
requiring the use of vials, tubes, bags and racks. Historically, a
lack of standardization in cryogenic storage has led to challenges
in developing and maintaining consistent handling protocols
and thawing processes. For companies considering automation,
selecting packaging that adheres to new standards such as those
being developed by the International Standards Organization
Technical Committee 276 can help ensure a smooth transition
and future scalability.
Scott Reeves
Senior Technical Sales Leader,
Azenta Life Sciences
Automated cryogenic storage systems revolutionize
storage needs and digital record-keeping, enhancing
efficiency, scalability, and cell viability, making
them indispensable for companies aiming for digital
transformation and regulatory compliance.
Key Takeaway
Despite higher initial costs, automated
cryogenic storage systems are beneficial for
scalability due to their efficiency and reliable
audit trails for regulatory purposes, making
them a solid choice for companies in the
manufacturing phase of product development.
16
Key Components and Features of an Automated
Cryogenic Storage Solution
Storage for a variety of types of containers
Inventory management software
Temperature control, monitoring, and alert systems
LIMS connectivity
Sample retrieval mechanisms
Sample tracking software and integration with other kinds of software
OFF-SITE STORAGE 5 SOLUTIONS
18
Security and Risk Mitigation Strategies
Advantages of Off-Site Storage Solutions
Off-Site Storage Solutions
Off-site cryogenic storage is a practical option for organizations without
the right skill set or space in-house to manage their own storage. These
specialized facilities handle diverse cryogenic samples, accommodating
various containers, and product types, often storing samples for multiple
companies at once.
Despite the benefits of off-site storage, security concerns may arise from not
having full control over your products. To alleviate risks associated with offsite cryogenic storage facilities, it is crucial to investigate the following:
● The facility’s emergency preparedness and contingency plans
● Number of on-site personnel and their qualifications
● Reviews and experiences from other companies with this facility
● Types of documentation provided by the facility
● Data gathering methods, analysis processes, and reporting procedures
● Insurance policies and associated costs
● Audit and inspection schedules and requirements
● Data security and encryption measures
● Communication tools for disseminating general repository operations
and policies to stakeholders6
Off-site storage facilities can significantly lighten the load of managing
intricate, sensitive samples. Companies can entrust them with
responsibilities like temperature monitoring, sample retrieval, and data
management. These facilities excel in managing daily security details
and compliance. They’re not just adept at handling the specifics but also
possess robust backup systems, power redundancies, and stringent
protocols. Thus, they’re well-prepared for power outages or unexpected
situations, ensuring your samples’ safety and integrity through their
well-planned contingencies.
CHOOSING THE RIGHT 6 SOLUTION
Finding the right cryogenic storage solution is not a one-size-fits-all
solution. Companies may require a mix of manual access high-efficiency
freezers and automated systems, depending on their needs for long-term
storage and frequent retrieval. The best choice will depend on various
factors such as budget, product development stage, and growth pace.
Flexibility will be key to accommodate future expansion and growth.
20
If... And... Then...
Your company is in the discovery
product development phase.
Your company is in the
discovery phase.
Your primary goal is immediate
scalability and maximum
efficiency.
You’re great at developing
products.
The company is at an
inflection point.
The company’s main facility is
far away from other facilities.
Automated storage may be
the right choice.
An automated solution can
significantly expedite your
growth. This technology
can pinpoint bottlenecks,
highlight areas for efficiency
improvements, and
oversee inventory and data
management.
Off-site cryogenic storage is
a great option. Facilities that
specialize in cryogenic storage
offer expertise in compliance
and security. They are skilled so
you don’t have to be.
An automated system is the
most effective way to scale
quickly if you already have a
product in the manufacturing
phase and have the capital to
invest in a robust system.
Having a cryogenic storage
facility off-site, closer to your
raw materials suppliers, might
reduce expenses. However,
the risks and potential high
costs involved in transferring
materials from your central labs
to this cryogenic storage facility
should not be overlooked.
You have the budget and desire
to future proof.
You are ready to invest
in the company to move
from the clinical research
phase to manufacturing and
commercialization/post-market.
You are lacking expertise in
security or compliance and
could use support.
You have the resources to fuel
explosive growth.
Transportation costs are a
large factor.
Your budget is tight. On-site, manual access
cryogenic storage options
may be right for you. You’ll
need continuous testing
and monitoring by a human.
Choosing automation-friendly
containers to store in can be a
good compromise to prepare
for future needs.
Choosing the Right Solution
IMPLEMENTING AND MANAGING 7 CRYOGENIC STORAGE SYSTEMS
Plan Logistics: Identify storage needs, product types, scaling speed, supply chain logistics, container needs, and desired storage options before starting.
Choose a Location: Opt for a location with minimal exposure to temperature variations, sunlight, and potential hazards.
Design the Facility: Ensure sufficient space, ventilation, and insulation to maintain cryogenic temperatures in your facility’s design.
Complete Paperwork: Handle insurance, compliance documents, regulatory reviews, and industry protocols early in the process.
Acquire Equipment: Invest in top-notch cryogenic storage equipment like freezers, LN2 tanks, cryogenic carriers, and monitoring systems.
Implement Software: Install necessary software, including temperature sensors and security systems, and test thoroughly.
Establish Routine: Set maintenance schedules, create SOPs, organize cleaning and employee shifts, among other routines.
Incorporate Product: Begin with low-risk products testing and ensure system functionality before operating at full capacity.
Build Team: Hire personnel for product development, manufacturing, security, etc., as needed.
Gather Data: Collect data once product processing begins to identify bottlenecks, improve processes, maintain product quality, and reduce costs.
Continuously Improve: Make data-driven decisions and adapt to market changes to enhance product quality and efficiency.
When planning and implementing a cryogenic storage system, every detail is important. Your strategy might range from choosing the right storage type
to its installation, setup, and regular upkeep. Here’s a possible breakdown of what your plan could include:
Plan
Logistics
Acquire
Equipment
Build
Team
Choose
Location
Implement
Software
Gather
Data
Design
Facility
Establish
Routine
Continuously
Improve
Do the
Paperwork
Incorporate
Product
1
5
9
2
6
10 11
3
7
4
8
22
Implementing and Managing Cryogenic Storage Systems
Cold Chain Management
An article outlining best practices in the Journal of Assisted Reproduction
and Genetics recommends that personnel routinely perform spot-check
assessments to ensure that LN2 levels are above canister/sample
device levels whenever a sample is removed from or placed into a tank.⁷
Companies should also maintain equipment records on-site for the
lifespan of equipment like cryogenic storage tanks.⁸
International Society for Biological and Environmental Repositories
(ISBER) provides further suggestions for best practices. If your cryogenic
facility houses repositories, the organization advises developing clear
guidelines that detail the services provided, costs, operating hours, and
contact information for stakeholders during regular hours as well as
after-hour emergencies.⁶ They also recommend installing O₂ monitoring
in areas where LN2 is used.⁶
When it comes to sample tracking and personal protective equipment
(PPE), protocols are crucial for ensuring safety and accuracy in labs or
research facilities. Precise tracking of samples helps prevent mix-ups and
contamination. Every individual involved in the handling of samples must
ensure that tracking protocols are followed to the letter. PPE protocols,
which protect workers from hazardous materials, must also be taken
seriously. Consistent use of proper PPE, in conjunction with appropriate
handling and disposal of hazardous materials, can greatly reduce the risk
of injury or harm.
Cold chain management is an essential part of cryostorage processes.
Biological samples are often stored in liquid nitrogen vapor phase (LN2)
to maintain temperatures below -135°C, known as the glass transition
temperature of water (Tg). It is believed that enzymatic activity stops or is
significantly reduced when biosamples are frozen below Tg and remain below
Tg until thawed, thus preserving their viability until needed.
Currently available commercial LN2 freezers have the capacity to preserve
samples at temperatures as low as -190°C. However, once samples are taken
out of these storage units, options for their safekeeping and monitoring are
limited. It’s crucial that these samples maintain temperatures below their
glass transition temperature (Tg) even when they are being handled within
the lab environment. The majority of LN2 carriers in the market are bulky
and difficult to maneuver, and the sample carriers could potentially present
safety hazards.
In the absence of automation and software, researchers must carefully time
their procedures and have a solid grasp of the warming and cooling rates
of cryogenic samples. This knowledge is vital for predicting and managing
sample temperatures throughout the entire workflow, enabling researchers
to adjust their procedures strategically to prevent samples from crossing the
Tg. Samples can cross Tg from -190°C in as few as 45 seconds when exposed
to an ambient environment. Insulating the rack and samples during transient
exposures helps to slow warming.⁹
Training and education for personnel is always recommended. If you don’t
have or need full-time employees for all tasks, service and support plans for
preventative maintenance and remote monitoring can be purchased.
23
Monitoring and Maintenance Best Practices
● Check LN2 levels
● Maintain equipment records
● Establish written guidelines
● Install O2 monitoring
● Track samples
● Staff training
Best Practice Highlights:
CASE STUDIES AND 8 SUCCESS STORIES
25
Automated Cold Chain Infrastructure Boosts Efficiency and Quality in Cryogenic Sample Management
In cryogenic storage, cold chain management is the critical component
for ensuring long-term sample viability and consistent outcomes,
particularly for patients treated with advanced cell and gene therapies.
Automation helps support more rigorous, consistent, and repeatable
process development. Cold chain management is essential and having
an automated system can help manage it more effectively. Despite
certain views that automated cold chain infrastructure is an expensive
alternative to manual methods, recent research by the Advanced
Regenerative Manufacturing Institute (ARMI) BioFab USA proves the ROI
value in sample cold chain rigor.⁴
In a workflow involving a manual LN2 dewar, samples from two
different shelf locations in a standard rack were monitored during 20
extractions from the freezer over 16 days. The procedure was replicated
Figure 1. Experimental Setup. The two experimental conditions: One rack in the Pico and one in an LN, dewar. Each rack had two boxes: a blank box that does not contain cells, and the target box containing
the cells to be thawed at the end of the experiment. The blank box was used during each transaction with the target box being removed from the freezer at the beginning and end of the experiment.
0.00
Time (Minutes)
5.00
10.00
15.00
20.00
25.00
2.56
Azenta Dewar
23.77
Target Box Ambient Exposure Time - Cumulative
Cryogenic Storage Type
Figure 1. Sample Box Placement Within Freezer Racks
Experimental Setup and Cell Morphology Results
Case Study 1
using Azenta’s CryoArc Pico -190°C LN2-Based Automated Storage System.
Following these operations, three vials of induced pluripotent stem cells
(iPSCs) from both systems were thawed, expanded, and assessed for cell
morphology differences.⁴
The findings suggest that automated storage retains sample quality at least
as well as manual methods, while reducing time for sample access, personnel
requirements, and PPE usage. Automation significantly minimizes the risk of
sample exposure to ambient conditions, as it doesn’t necessitate removing
the full rack to access a target location. These results underscore the notable
benefits of data accuracy, time savings, and enhanced sample quality through
automation, refuting common misconceptions.⁴
Retrieval time for one vial in
automated freezer vs manual
cryogenic workflow: 2 minutes
(automated) vs. 11 minutes (manual).
2VS
minutes 11
minutes
Get the Poster
Figure 3. Moreover, the system safeguards samples in lower shelves from excessive
warming by keeping them inside the freezer when accessing boxes in higher shelves.¹¹
Figure 1. The system demonstrated 70% slower warming rates for the first 30 seconds
of exposure compared to manual methods, indicating better preservation of sample
integrity. The rate of warming in shelf 1 is the highest, but whereas the automated
system has relatively linear warming rates for lower shelves, the manual rack has
significant differences between different shelves.
Figure 2. Sample rate of warming of each shelf from extraction to -120°C (past
the glass transition temperature) and the average time to reach -120°C.
Another case study from Azenta revealed that automation slows the rate of
warming for samples pulled from cryo storage. Liquid nitrogen vapor phase
freezers, which keep temperatures below -135°C, are essential for preserving
sample viability in biobanking and cell therapy industries. “Innocent samples,”
unintended for thawing, can suffer damage due to repeated exposures and
thaw/freeze cycles during routine operations. Recent studies compared
manual retrieval of cryoboxes to automated handling using Azenta -190°C
automated cryogenic storage systems in terms of workflow, time, and warm
up rates.¹¹
The study’s findings showed that the automated the system significantly
streamlined the process of cryobox removal, compared to manual techniques.
Upon rack extraction, the automated system decreased the sample warming
rate by 70% within the first half-minute. This system also enabled “innocent
samples” to warm across Tg at a 51% slower pace than manual processes.
1
0.00
°C/Minute
5.00
10.00
15.00
20.00
25.00
Manual
CryoArc
4 7 9 13
Rate of Warming - First 30 Seconds
Shelf Position
1
0.00
°C/Minute
5.00
10.00
15.00
20.00
25.00
Manual
CryoArc
4 7 9 13
Rate of Warming from Pull -
(~ -180°C) to -120°C
Shelf Position
Average Time to Warm to -120°C
Manual
CryoArc
184 Seconds
343 Seconds
Case Study 2
26
10
50
80
30
70
100
0
0 1 2 3 4 5 6 7
40
20
60
90
% Confluence
Average Confluence
Day of Process
Control Thaw Averages Manual Thaw Averages
Azenta Thaw Averages
Read The Full Case Study
Sample Warming During Innocent Exposures From
an LN2 Freezer: Comparing Temperature, Time &
Workflow Using Manual vs. Automated Systems
During a 2-minute exposure, the temperatures of all 5 'innocent samples' were compared between manual and automated workflows. The study showed that lower
shelf samples warmed less when using the Azenta automated system, especially during the retrieval of a cryobox from the top (shelf 1) and shelf 7.
Sample Temperatures Sample Temperatures
27
Time (seconds)
Auto Rack Pull #5
120 180 240
Tg at
258s
0 60
-2000
-180.0
-160.0
-140.0
Temperature °C
-120.0
-100.0
-80.0
13
10
7
4
1
Time (seconds)
Manual Rack Pull #3
120 180 240
Tg at
126s
0 60
-2000
-180.0
-160.0
-140.0
Temperature °C
-120.0
-100.0
-80.0
13
10
7
4
1
Time (seconds)
Remove Box 7
0 60 120 180 240
-2000
-180.0
-160.0
-140.0
Temperature °C
-120.0
-100.0
-80.0
13
10
7
4
1
Time (seconds)
Retrieve Box 7
0 60 120 180 240
-2000
-180.0
-160.0
-140.0
Temperature °C
-120.0
-100.0
-80.0
13
10
7
4
1
28
Conclusion
Whatever you choose, recognize that cryogenic storage is a journey, not a destination. Implementation is a
significant milestone, but maintenance will be a constant. The company will scale, markets will change,
regulations will be implemented, and new technologies will become available. You’ll need to adapt
with ongoing evaluation and adaptation, not just to the outside world, but also to the data you
gather to optimize your own facility for continuous improvement. Change is inevitable, so let
best practices guide your way.
For guidance on making informed decisions about cryogenic storage solutions,
discuss your plans with an Azenta expert today.
References
1. Dr. Ray Radebaugh. NIST. The MacMillan Encyclopedia Of Chemistry. https://trc.nist.gov/cryogenics/aboutCryogenics.html (2002)
2. Jang, Tae Hoon, Sung Choel Park, Ji Hyun Yang, Jung Yoon Kim, Jae Hong Seok, Ui Seo Park, Chang Won Choi, Sung Ryul Lee, and Jin Han. "Cryopreservation and its clinical applications." Integrative \medicine research 6, no. 1(2017):12-18.
3. Meneghel, J., Kilbride, P. and Morris, G.J. Cryopreservation as a key element in the successful delivery of cell-based therapies—A review. Frontiers in medicine. (2020)
4. Azenta Blog. Considerations for Protecting Cell Viability During Cryopreservation. https://www.azenta.com/resources/benefits-automation-cold-chain-infrastructure (April 2023)
5. Sue Holland-Crimmin, Ph.D. Azenta Resources. The Evolution of Sample Management and Automation in Drug Discovery. https://www.azenta.com/resources/evolution-sample-management-and-automation-drug-discovery (2023)
6. McKinsey & Company. Technology Trends. https://www.mckinsey.com/~/media/mckinsey/business%20functions/mckinsey%20digital/our%20insights/mckinsey%20technology%20trends%20outlook%202023/mckinsey-technology-trends- outlook-2023-v5.pdf. (July 2023)
7. Azenta. Publications & Posters. Benefits of Automation of Cold Chain Infrastructure. https://www.azenta.com/resources/benefits-automation-cold-chain-infrastructure.
8. ISBER. Best Practices: Recommendations for Repositories Fourth Edition. https://cdn.ymaws.com/www.isber.org/resource/resmgr/best_practices_4th_edition/isber_best_practices_recomme.pdf (2018)
9. Azenta. Whitepapers & eBooks. Preserving the Innocents: Biosample Storage at -190ºC. https://www.azenta.com/resources/preserving-innocents-biosample-storage-190-c
10. Azenta. Storage, Automation & Logistics | White Paper. https://web.azenta.com/hubfs/_Current%20Azenta%20Resources/37006-WE-1221-Sample-Warming-During-Innocent-Exposures.pdf (2022)
11. Schiewe, M. C., M. Freeman, J. B. Whitney, M. D. VerMilyea, A. Jones, M. Aguirre, C. Leisinger et al. "Comprehensive assessment of cryogenic storage risk and quality management concerns: best practice guidelines for ART labs." Journal of assisted reproduction and genetics 36 (2019 ): 5-14.
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