Insurance Today, For A Viable Future.
The BioArchive® System is the only fully robotic storage and retrieval system for cryopreserving stem cell samples.
By using a proven, computer controlled technology and tracking software, the BioArchive provides the best protection for today’s valuable stem cell samples that meet tomorrow’s stem cell therapy needs.
- Samples are stored at a consistent -196°C temperature
- Constant temperature control through closed-system sample handling with robotic storage and retrieval
- Integrated control rate freezing
- Delivers up to 94% post-thaw cell viability1*
- Individual storage and retrieval of cell samples results in minimal exposure to transient warming events (TWE)
- Automated tracking of individual sample freeze curves and storage in LN2 assures maximum confidence
Superior Design. Unsurpassed Viability.
- Viable CD34+ stem cell recovery is consistently > 97%, higher than other available systems1
- Fully automated, closed system maintains cell integrity
- Precise robotic storage and retrieval minimizes TWE
- Over 3600 sample capacity
Complete System Solution.
The BioArchive System consists of the following key components:
- Liquid nitrogen dewar with storage rack
- Liquid nitrogen control system for the dewar
- Controlled rate freezer (CRF) modules
- Sample retrieval cartridge
- Robotic arm consisting of a barcode reader and a periscope with a canister hook necessary for storage and retrieval
- Microprocessor control system which controls the automated functions and maintains records of the samples freeze profile and system inventory
- Sample Management Software (SMS)
- Computer and accessories (printer, barcode label scanner, barcode label printer, mouse, keyboard, monitor)
- One magnetic retrieval device
Controlled Freezing. Confident Results.
- STET controlled-rate freezing process, a sensor monitors the sample temperature
- This individual controlled-rate freezing maintains the sample’s cell integrity during the freeze cycle
- The CRF controls the rate of freezing based on temperature and time until the sample reaches -50°C
- Once the sample reaches -50°C it is then moved from the CRF and is placed in an unique location for storage. It can then be independently retrieved without compromising other samples cell viability
- Three-dimensional, 25mL, dual-compartment blow-molded freezing bag and a stainless steel canister ensures precise, uniform freezing
- An overwrap bag adds further sample protection during storage in LN2
Tracking with Certainty. Storing with Confidence.
- Software provides accurate, individualized, fully documented freeze and sample tracking, history, and inventory
- Robotic arm retrieves sample via integrated bar code reader
- Data acquisition storage information is accessed via the sample’s unique barcode
- Software helps comply with cGMP and cGTP Requirements
Safety for Samples. Safe for the Operator.
- Multiple safety controls protect cell preservation and operator
- Magnetic stainless steel canisters firmly house overwrapped freezing bags, enabling precise robotic insertion, and retrieval from liquid nitrogen
- Vacuum-insulated Dewar helps maintain constant temperatures and a safe environment
- Robotic arm identifies and retrieves only the desired sample, protecting all other samples from TWE
- Robotic functions and minimal dewar access points reduce operator exposure to liquid nitrogen
- Insulated retrieval cartridge helps protect handler from exposure to liquid nitrogen and samples to TWE
- Uninterrupted power supply
- Liquid nitrogen volume control alert system
- Series of audible alarms and screen alerts notify users of situations that need to be attended to.
1.Rubenstein P. Cord blood banking for clinical transplantation. Bone Marrow Transplantation 2009;44:635-642.
* When used in conjunction with the AutoXpress® AXP® System.
The BioArchive® System uses an advanced robotic method for freezing, storing and retrieving cell samples.
Liquid Nitrogen Dewar
The liquid nitrogen dewar is a double-walled stainless steel reservoir that holds liquid nitrogen for freezing samples. A vacuum is maintained between the walls, which effectively insulates the storage dewar. Liquid nitrogen level sensors are located within the dewar to allow monitoring of the liquid nitrogen level.
The dewar’s storage racks have approximately 3,600 individual storage positions “addresses” for 25 mL samples. The addresses are arranged concentrically so that every storage location can be accessed by the periscope assembly.
Two small ports on the dewar lid provides access to the inside of the dewar. These ports are used for insertion of the Control Rate Freezers and Retrieval Cartridges and are covered when not in use. Minimizing the size of the opening reduces LN2 evaporation, provides an added safety measure for the user and ice formation.
Liquid Nitrogen Control System
The control system operates a liquid nitrogen supply valve and an alarm system. This system allows the BioArchive to be set in an auto fill mode so when the liquid nitrogen level sensors detects the liquid nitrogen level below a preset level it signals the control system to open the liquid nitrogen supply valve. The control system also contains audible alarms and will alert the usert if the dewar LN2 volume is at high, low, extra low levels.
A controlled-rate freezer module (CRF) is used to hold the sample during the freeze cycle. It also monitors the freeze cycle and facilitates the execution of a freeze profile. The CRF is inserted into a port on the BioArchive System allowing the canister to be suspended in the liquid nitrogen vapor once in the port. A small electric fan, mounted at the rear of the CRF doors, is activated forcing nitrogen vapor through the interior of the chamber, and controls the flow of LN2 vapor over the sample. Two sensor probes, also found on one of the CRF doors, monitor the temperature of the sample and sends a signal to the fan to adjust it’s speed. This precise monitoring allows for superior accuracy in the control rate freezing process which is vital to maintain cell viability.
The freezing procedure follows a predefined freeze profile. A freeze profile consists of three regions:
1. Pre-freeze region
This is the region where the temperature of the sample begins above the freezing point of the cryoprotected sample solution and is brought down to a temperature just before ice forms in the extracellular sample.
2. Freeze region
In this region water, removed from the cells turns to ice and the unfrozen fraction becomes increasingly concentrated as the freezing progresses. There is typically an increase in temperatrue immediately after the sample changes from liquid to cryptolline nucleation. This localized rise in temperature is known as the latent heat of fusion controlling nucleation and the temperature compensation provided by the CRF fans during the control rate preservation results in improved post-freeze cell viability1.
3. Post-freeze region
This region is where the temperature of the sample is below the freezing point and is brought down to a defined temperature at a constant rate. After the temperature of the sample reaches the user-defined target the robotic arm transfers the frozen sample to its permanent storage address in liquid nitrogen. The frozen sample remains at this address until it is retrieved.
The retrieval cartridge is used for retrieving frozen samples. It holds a foam canister sleeve designed to slow the warming of a removed canister.
The periscope assembly is an electromechanical system that transports a canister containing a sample from the controlled rate freezer (CRF) module to a specific storage address in the dewar. It also retrieves the frozen sample from its storage address when it is needed.
A camera and mirror mounted in the periscope allows for the reading of the barcode label of the canister when the canister is on or near the periscope hook.
Preparing a Sample for cryopreservation and storage
- Place a labeled overwrapped freezing bag sample into a labelled canister.
- The canister is placed into a controlled-rate freezer (CRF).
- CRF is placed into a port on the BioArchive and thre freeze cycle begins.
Robotic Controlled Sample Storage
Published Journal Articles
- Ivanovic, Z., et. al. A Novel Procedure to Improve functional Preservation of Hematopoietic Stem and Progenitor Cells in Cord Blood Stored at +4oC Before Cryopreservation. Stem Cells and Development, Vol. 23, Number 15, 2014.
- K. de Lima Prata et. al., Cryopreservation of umbilical cord mesenchymal cells in xenofree conditions, Cytotherapy, 2012.
- I. P. Arrojo, et. al., Trends in cord blood banking, Blood Transuf, 10: 95-100, 2012.
- Rubinstein, et. al. Transient Warming Events and Cell Viability of Placental/Umbilical Cord Blood (PCB). ISHAGE, 2001.
- O. E. Giet, et. al., Management of a disaster management: particular issue of the Bioarchive cryogenic tank. ISCT, 2013.
- J. Li, et. al. A study of MXP cell process and BioArchive Cryopreservation with Human Bone marrow. ISCT, 2009.