A new method of cryopreserving colorectal carcinoma cells for patient derived xenograft model generation

Patient derived xenograft (PDX) models provide an efficient way to study anti-tumor drug efficacy. In this respect, it is essential to study the optimal method needed to cryopreserve the starting cells obtained from tumor samples for PDX model generation. Cryopreservation of cells prior to xenografting is necessary for cross-verification of results obtained by xenografting and also for practical planning of experiments. In the present work, we studied the cryopreservation of colorectal carcinoma (CRC) cells isolated from patient tumor samples for generating their patient derived xenograft models. CRC therapeutics study is essential for early stage intervention and treatment of the disease. CRC cell lines do not ideally depict the molecular characteristics of patient CRC tumor samples. This necessitates the generation of CRC PDX models for drug discovery. We show that CRC cells isolated from patient tumor samples have comparable recovery, viability and growth with both conventional cryopreservation methods as well as Fibulas BioFlash Drive™. However, xenograft tumor formation was much more effective with Fibulas BioFlash Drive™ cryopreserved cells than with cells cryopreserved with conventional methods. Therefore, we put forward an effective way to cryopreserve primary cells obtained from patient tumor samples for PDX model generation in this study.     

Theoretic considerations regarding slow cooling and vitrification during cryopreservation

This review presents the methodology of using theoretic models for development of cryopreservation protocols by designing specific cooling profiles and selecting appropriate external conditions to optimize cryopreservation survival. Biophysical events during the processes of cryopreservation were examined and corresponding theoretic equations were used to simulate cryopreservation procedures under various slow cooling conditions for rat zygotes in the presence of DMSO, using a 0.25-mL plastic straw as the container. Simulation revealed three regions with their own characteristics and cryopreservation relevance. In addition, this review discusses vitrification cryopreservation using two-step additions. The effects of exposure durations and exposure temperatures on cell survival and subsequent development rates were examined in a series of cryopreservation experiments. Values of accumulative osmotic damage were used to quantitatively examine the magnitude of the associated osmotic damage during cryoprotective agent (CPA) additions and dilutions. In these investigations, oocyte blastocyst rates were highly correlated with the values of accumulative osmotic damage in the processes of CPA additions/dilutions. This review emphasizes the most essential step of the selection of the cell container in the process of cryopreservation, and provides practical suggestions and guidelines for optimizing slow cooling protocols. The review stresses that conducting CPA addition steps at 25 °C would be preferable for vitrification. It also suggests that the final dilution process needs more systematic research to optimize vitrification procedures.     

134 Cryopreservation of Chlamydomonas Reinhardtii (Chlorophyceae): A Cause of Low Viability at High Cell Density

Cryopreservation provides a convenient method for long term storage of living organisms. Current protocols allow the successful cryopreservation of a wide range of algae, although many strains remain recalcitrant to cryopreservation. Chlamydomonas reinhardtii , a species utilized in many molecular and biochemical studies, survives cryopreservation best at low cell density. We show that reduced viability at higher cell densities is caused by the accumulation of a substance released from C. reinhardtii into the culture medium during cryopreservation. A mutant strain of C. reinhardtii (cw10) with a greatly reduced cell wall did not release a substance inhibitory to wild type or cw10 C. reinhardtii during cryopreservation, and could be cryopreserved with the same viability regardless of cell density. The inhibitory substance is small (mw<1300), polar, heat-stable and organic. Chlamydomonas moewusii Gerloff and Chlamydomonas zebra Korschikov ex Pascher both produce substances that reduce the viability of cryopreserved C. reinhardtii . However, neither is affected by the inhibitory substance produced by themselves or C. rienhardtii. Pandorina morum (Müller) Bory and Volvox carteri f. nagariensis Iyengar are colonial Volvocalean algae related to C. reinhardtii that cannot be successfully cryopreserved. They both generate substances that inhibit C. reinhardtii during cryopreservation. The identification of the substance inhibitory to C. reinhardtii during cryopreservation should explain why this alga cryopreserves best at a low cell density, and may lead to protocols that facilitate the more successful cryopreservation of C. reinhardtii and related algae.     

海藻酸微囊在细胞冷冻保存中的研究现状及应用

细胞的冷冻保存是细胞生物学实验中重要的实验技术.长期以来,人们使用冷冻保存液重悬细胞后进行冷冻储存,但是近年来,众多研究者发现传统冷冻方案往往会导致细胞活率大幅下降和细胞功能方面受损,从而很难满足生物医学、组织再生工程、细胞移植技术等高新技术的要求.所以研究者提出利用三维海藻酸微囊包埋细胞后再进行冷冻保存,从而在保证较高细胞活率的同时维持细胞的原有功能,有效的提高细胞的冷冻保存效率.本文概述了海藻酸微囊在细胞冷冻保存过程中的研究现状,同时对其应用进行了展望,以期为后续研究工作提供参考.     

Sensitivity of a PER.C6® cell line to bis(2,4-di-tert-butylphenyl)phosphate and evaluation of a new,biocompatible single-use film

Single-use technologies have brought numerous advantages to the biopharmaceutical industry. In particular, single-use bags made from multi-layered polymeric films have been adopted for cell culture and liquid handling operations in place of traditional stainless-steel systems. Despite the advantages, leachable compounds originating from the film's materials of construction present a new challenge. In 2013, bis(2,4-di-tert-butylphenyl)phosphate (bDtBPP) was identified as a common leachable from several single-use bags that is detrimental to the growth and viability of many Chinese hamster ovary (CHO) cell lines. While much work has been completed to characterize CHO cell sensitivity to bDtBPP, little has been done to characterize its impact on other important production cell lines, particularly PER.C6®. This publication investigates inconsistent cell growth observed in a PER.C6® cell line during bioprocess development. The growth inhibition was linked to leachable migration from Bioclear™ 10, a single-use film from Cytiva (formerly GE Healthcare) that was used for cell expansion. It was shown that the PER.C6® cells displayed a sensitivity to bDtBPP, comparable to that observed in sensitive CHO cell lines. Finally, biocompatibility of PER.C6® with Cytiva's new Fortem film was evaluated, demonstrating that Fortem™ film is a suitable single-use technology for culturing PER.C6® cells.     

Efficient establishment of human embryonic stem cell lines and long-term maintenance with stable karyotype by enzymatic bulk passage

Human ES (hES) cell lines are considered to be a valuable resource for medical research and for applications in cell therapy and drug discovery. For such utilization of hES cells to be realized, however, protocols involved in the use of hES cells, such as those for establishment, propagation, and cryopreservation, have still to be improved. Here, we report on an efficient method for the establishment of hES cell lines and its detailed characterization. Additionally, we developed a new bulk-passaging technique that preserves the karyotypic integrity of hES cell lines when maintained in culture for up to 2 years. Finally, we show that a simplified vitrification cryopreservation technique is vastly superior to standard slow-cooling methods with respect to cell viability. These results provide valuable information that will assist in achieving the goal of the large-scale hES cell culture required for the application of hES cells to disease therapy.     

Development of a cryopreservation protocol for testicular interstitial cells with the account of temperature intervals for controlled cooling below -60°С

A long course of anticancer therapy may lead to testicular steroidogenesis destruction. Cryopreservation of testicular interstitial cells (TIC) would be a strategy to protect hormonal and fertile potential of pre-pubertal boys treated with chemo – or radiotherapy. The aim of this research was to optimize protocols for freezing of TIC. Essential physical processes associated with the presence of dimethyl sulphoxide (Me₂SO) in the cryoprotectant solution take place at the temperatures below −60 °С. These processes are the eutectic crystallization at the stage of freezing and the recrystallization before the melting of the eutectic mixture at the stage of heating. Both of the processes affect the viability of the cells subjected to cryopreservation. Temperature intervals when these processes take place were determined by the method of thermoplastic deformation for 10% Me₂SO selected for cryopreservation of TIC. Rat TIC were cryopreserved using five different protocols which varied in cooling rates within the chosen temperature intervals. Post-thaw cell viability and metabolic activity were evaluated by Trypan Blue and 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) staining assays. Leydig cell recovery after cryopreservation was measured by 3-beta-hydroxysteroid dehydrogenase reaction. Based on the obtained results, the authors developed a cryopreservation protocol for TIC which makes it possible to achieve great cell viability due to using controlled cooling rates within the temperature intervals below −60 °С.     

Strategies for the cryopreservation of microencapsulated cells

The major challenge in developing cryopreservation protocols for microencapsulated cells is that the relatively large size (300-400 microm) and the fragile semipermeable membrane of microcapsules makes them particularly prone to cryodamage. Rapid-cooling cryopreservation protocols with high DMSO concentrations (3.5M, 25% v/v) resulted in low post-thaw cell viability (<10%), which did not improve with higher concentrations (4.5M, 32% v/v) and longer exposure to DMSO, even though the majority of microcapsules (60-80%) remained intact. Subsequent investigations of slow cooling with a range of DMSO and EG concentrations resulted in a much higher post-thaw cell viability (80-85%), with the majority of the microcapsules remaining intact ( approximately 60%) when DMSO was used at a concentration of 2.8M (20% v/v) and EG at a concentration of 2.7M (15% v/v). The presence of 0.25M sucrose significantly improved post-thaw cell viability upon slow cooling with 2.8M (20% v/v) DMSO, although it had no effect on microcapsule integrity. Multistep exposure and removal of sucrose did not significantly improve either post-thaw cell viability or microcapsule integrity, compared to a single-step protocol. Ficoll 20% (w/v) also did not significantly improve post-thaw cell viability and microcapsule integrity. Hence, the optimal condition for microcapsule cryopreservation developed in this study is slow cooling with 2.8M (20% v/v) DMSO and 0.25M sucrose.     

Comparison of vitrification and slow cooling for umbilical tissues

The tissue cryopreservation maintains the cellular metabolism in a quiescence state and makes the conservation possible for an indefinite period of time. The choice of an appropriate cryopreservation protocol is essential for maintenance of cryopreserved tissue banks. This study evaluated 10 samples of umbilical cord, from which small fragments of tissue (Wharton’s jelly and cord lining membrane) were subjected to two protocols of cryopreservation: slow cooling and vitrification. The samples were frozen for a period of time ranging from 5 to 78 days. The efficiency of cryopreservation was evaluated by testing cell viability, histological analysis, cell culture, cytogenetic analysis and comparison with the results of the fresh samples. The results showed that the slow cooling protocol was more efficient than the vitrification for cryopreservation of umbilical cord tissue, because it has caused fewer changes in the structure of tissue (edema and degeneration of the epithelium) and, despite the significant decrease cell viability compared to fresh samples, the ability of cell proliferation in vitro was preserved in most samples. In conclusion, this study showed that it is possible to cryopreserve small fragments of tissue from the umbilical cord and, to obtain viable cells capable of proliferation in vitro after thawing, contributing to the creation of a frozen tissue bank.     

Best practices for cryopreserving,thawing, recovering,and assessing cells

Long-term storage of cell stocks insures that cells are available for use whenever needed. Cryopreservation of cells is the method of choice for preservation of important or rare cell stocks. There are several factors to consider when establishing a protocol for freezing, thawing, and recovery of cells after storage. These parameters may include cell concentration, cryoprotectant choice and concentration, and thawing rate among others. Further, the assessment of cell viability and/or function prior to and following cryopreservation is imperative in order to accurately determine downstream utility as well for optimizing the cryopreservation process. This chapter is designed to provide guidance and insight into developing robust and successful protocols for preserving cells that will preserve cell stocks and provide optimal cell yield and viability.     

Characterization of cryobiological responses in TF-1 cells using interrupted freezing procedures

Cryopreservation currently is the only method for long-term preservation of cellular viability and function for uses in cellular therapies. Characterizing the cryobiological response of a cell type is essential in the approach to designing and optimizing cryopreservation protocols. For cells used in therapies, there is significant interest in designing cryopreservation protocols that do not rely on dimethyl sulfoxide (Me₂SO) as a cryoprotectant, since this cryoprotectant has been shown to have adverse effects on hematopoietic stem cell (HSC) transplant patients. This study characterized the cryobiological responses of the human erythroleukemic stem cell line TF-1, as a model for HSC. We measured the osmotic parameters of TF-1 cells, including the osmotically-inactive fraction, temperature-dependent membrane hydraulic conductivity and the membrane permeability to 1 M Me₂SO. A two-step freezing procedure (interrupted rapid cooling with hold time) and a graded freezing procedure (interrupted slow cooling without hold time) were used to characterize TF-1 cell recovery during various phases of the cooling process. One outcome of these experiments was high recovery of TF-1 cells cryopreserved in the absence of traditional cryoprotectants. The results of this study of the cryobiology of TF-1 cells will be critical for future understanding of the cryobiology of HSC, and to the design of cryopreservation protocols with specific design criteria for applications in cellular therapies.     

Viability of zebrafish (Danio rerio) ovarian follicles after vitrification in a metal container

Cryopreservation of ovarian tissue has been studied for female germline preservation of farm animals and endangered mammalian species. However, there are relatively few reports on cryopreservation of fish ovarian tissue and especially using vitrification approach. Previous studies of our group has shown that the use of a metal container for the cryopreservation of bovine ovarian fragments results in good primordial and primary follicle morphological integrity after vitrification. The aim of this study was to assess the viability and in vitro development of zebrafish follicles after vitrification of fragmented or whole ovaries using the same metal container. In Experiment 1, we tested the follicular viability of five developmental stages following vitrification in four vitrification solutions using fluorescein diacetate and propidium iodide fluorescent probes. These results showed that the highest viability rates were obtained with immature follicles (Stage I) and VS1 (1.5 M methanol + 4.5 M propylene glycol). In Experiment 2, we used VS1 to vitrify different types of ovarian tissue (fragments or whole ovaries) in two different carriers (plastic cryotube or metal container). In this experiment, Stage I follicle survival was assessed following vitrification by vital staining after 24 h in vitro culture. Follicular morphology was analyzed by light microscopy after vitrification. Data showed that the immature follicles morphology was well preserved after cryopreservation. Follicular survival rate was higher (P < 0.05) in vitrified fragments, when compared to whole ovaries. There were no significant differences in follicular survival and growth when the two vitrification devices were compared.     

Surface-based cryopreservation strategies for human embryonic stem cells: A comparative study

Human embryonic stem cells (hESC) hold tremendous potential in the emerging fields of gene and cell therapy as well as in basic scientific research. One of the major challenges regarding their application is the development of efficient cryopreservation protocols for hESC since current methods present poor recovery rates and/or technical difficulties which impair the development of effective processes that can handle bulk quantities of pluripotent cells. The main focus of this work was to compare different strategies for the cryopreservation of adherent hESC colonies. Slow‐rate freezing protocols using intact hESC colonies was evaluated and compared with a surface‐based vitrification approach. Entrapment within ultra‐high viscous alginate was investigated as the main strategy to avoid the commonly observed loss of viability and colony fragmentation during slow‐rate freezing. Our results indicate that entrapment beneath a layer of ultra‐high viscous alginate does not provide further protection to hESC cryopreserved through slow‐rate freezing, irrespectively of the cryomedium used. Vitrification of adherent hESC colonies on culture dishes yielded significantly higher recovery rates when compared to the slow‐rate freezing approaches investigated. The pluripotency of hESC was not changed after a vitrification/thawing cycle and during further propagation in culture. In conclusion, from the cryopreservation methods investigated in this study, surface‐based vitrification of hESC has proven to be the most efficient for the cryopreservation of intact hESC colonies, reducing the time required to amplify frozen stocks thus supporting the widespread use of these cells in research and clinical applications. © 2012 American Institute of Chemical Engineers Biotechnol. Prog., 28: 1079–1087, 2012     

Exposure to dimethyl sulfoxide at 37 degrees C prior to freezing significantly improves the recovery of cryopreserved hybridoma cells

Standard cryopreservation protocols recommend the use of dimethyl sulfoxide (Me2SO) at moderate temperatures only (room temperature, 4 degrees C) due to its toxicity which appears to be potentiated by warm temperatures. In the present study, we asked whether a transient increase in temperature during membrane sealing of cryovials affects the cell viability. We show here that the cell viability of hybridoma cells and Schwann cells was not reduced following membrane sealing of cryotubes. On the contrary, incubation of cells at 37 degrees C in Me2SO-containing medium prior to freezing significantly stimulated the viability of cryopreserved hybridoma cells, whereas the viability of Schwann cells remained unaltered. We conclude that the exposure of cells to Me2SO at elevated temperatures does not necessarily reduce cell viability and that contrary to this, cell type-specific, beneficial effects of Me2SO could be observed.     

High-throughput single cell arrays as a novel tool in biopreservation

Microwell array cytometry is a novel high-throughput experimental technique that makes it possible to correlate pre-stress cell phenotypes and post-stress outcomes with single cell resolution. Because the cells are seeded in a high density grid of cell-sized microwells, thousands of individual cells can be tracked and imaged through manipulations as extreme as freezing or drying. Unlike flow cytometry, measurements can be made at multiple time points for the same set of cells. Unlike conventional image cytometry, image analysis is greatly simplified by arranging the cells in a spatially defined pattern and physically separating them from one another. To demonstrate the utility of microwell array cytometry in the field of biopreservation, we have used it to investigate the role of mitochondrial membrane potential in the cryopreservation of primary hepatocytes.Even with optimized cryopreservation protocols, the stress of freezing almost always leads to dysfunction or death in part of the cell population. To a large extent, cell fate is dominated by the stochastic nature of ice crystal nucleation, membrane rupture, and other biophysical processes, but natural variation in the initial cell population almost certainly plays an important and under-studied role. Understanding why some cells in a population are more likely to survive preservation will be invaluable for the development of new approaches to improve preservation yields.For this paper, primary hepatocytes were seeded in microwell array devices, imaged using the mitochondrial dyes Rh123 or JC-1, cryopreserved for up to a week, rapidly thawed, and checked for viability after a short recovery period. Cells with a high mitochondrial membrane potential before freezing were significantly less likely to survive the freezing process, though the difference in short term viability was fairly small. The results demonstrate that intrinsic cell factors do play an important role in cryopreservation survival, even in the short term where extrinsic biophysical factors would be expected to dominate. We believe that microwell array cytometry will be an important tool for a wide range of studies in biopreservation and stress biology.     

Cryopreservation of cell suspension cultures of <Emphasis Type="Italic">Taxus</Emphasis> × <Emphasis Type="Italic">media</Emphasis> and <Emphasis Type="Italic">Taxus floridana</Emphasis>

Different lines of cell suspension cultures of Taxus × media Rehd. and Taxus floridana Nutt. were cryopreserved with a two-step freezing method using a simple and inexpensive freezing container instead of a programmable freezer. Four to seven days old suspension cell cultures were precultured in growth medium supplemented with 0.5 M mannitol for 2 d. The medium was then replaced with cryoprotectant solution (1 M sucrose, 0.5 M glycerol and 0.5 M dimethylsulfoxide) and the cells incubated on ice for 1 h. Before being plunged into liquid nitrogen, cells were frozen with a cooling rate of approximately −1 °C per min to −80 °C. The highest post-thaw cell viability was 90 %. The recovery was line dependent. The cryopreservation procedure did not alter the nuclear DNA content of the cell lines. The results indicate that cryopreservation of Taxus cell suspension cultures using inexpensive freezing container is possible.     

Quantitative Measurement of Cell Membrane Transport: Technology and Applications

The transport of water and cryoprotective chemicals across cell membranes plays an absolutely fundamental role in the outcome of cryopreservation processing. The diversity of cell types as well as the remarkable range of perturbations that cells are subjected to as part of cryopreservation practices generate many interesting research questions. Simply stated, the extreme conditions typical of cryopreservation protocols extend the limits of membrane transport inquiry well beyond that considered in “normal” cell physiology. This paper provides a brief review of methods which have been used for measuring membrane transport properties, especially those methods developed during the past decade which allow us to measure coupled and uncoupled membrane transport properties of water and cryoprotective agents for individual cells in terms of classical Kedem–Katchalsky membrane transport theory. Representative results obtained from these new technologies will be offered to illustrate their utility and relevance to membrane transport issues arising in cryopreservation practice. Engineers have made significant contributions to this area of research primarily in terms of device development and the application of inverse methods to estimate membrane transport properties.     

Rabbit sperm cryopreservation: a review

Sperm cryopreservation is a great challenge, since many sperm are irreversibly damaged or present altered functionality after the whole process. Although components of extenders for sperm cryopreservation are quite similar between species, sperm from each of the species present peculiarities that force researchers to optimize the extenders and protocols for each particular species. In this review, information related to rabbit sperm cryopreservation is compiled. The topics discussed include the extenders and protocols developed for rabbit sperm cryopreservation, as well as fertility data obtained after artificial insemination with cryopreserved sperm and factors that may have an impact on the results obtained. In addition, suggestions for improving the results after cryopreservation of rabbit sperm are also proposed.     

Preservation of cell-based immunotherapies for clinical trials

In the unique supply chain of cellular therapies, preservation is important to keep the cell product viable. Many factors in cryopreservation affect the outcome of a cell therapy: (i) formulation and introduction of a freezing medium, (ii) cooling rate, (iii) storage conditions, (iv) thawing conditions and (v) post-thaw processing. This article surveys clinical trials of cellular immunotherapy that used cryopreserved regulatory, chimeric antigen receptor or gamma delta T cells, dendritic cells or natural killer (NK) cells. Several observations are summarized from the given information. The aforementioned cell types have been similarly frozen in media containing 5–10% dimethyl sulfoxide (DMSO) with plasma, serum or human serum albumin. Two common freezing methods are an insulated freezing container such as Nalgene Mr. Frosty and a controlled-rate freezer at a cooling rate of -1°C/min. Water baths at approximately 37°C have been commonly used for thawing. Post-thaw processing of cryopreserved cells varied greatly: some studies infused the cells immediately upon thawing; some diluted the cells in a carrier solution of varying formulation before infusion; some washed cells to remove cryoprotective agents; and others re-cultured cells to recover cell viability or functionality lost due to cryopreservation. Emerging approaches to preserving cellular immunotherapies are also described. DMSO-free formulations of the freezing media have demonstrated improved preservation of cell viability in T lymphocytes and of cytotoxic function in natural killer cells. Saccharides are a common type of molecule used as an alternative cryoprotective agent to DMSO. Improving methods of preservation will be critical to growth in the clinical use of cellular immunotherapies.     

Freezing mammalian cells for production of biopharmaceuticals

Cryopreservation techniques utilize very low temperatures to preserve the structure and function of living cells. Various strategies have been developed for freezing mammalian cells of biological and medical significance. This paper highlights the importance and application of cryopreservation for recombinant mammalian cells used in the biopharmaceutical industry to produce high-value protein therapeutics. It is a primer that aims to give insight into the basic principles of cell freezing for the benefit of biopharmaceutical researchers with limited or no prior experience in cryobiology. For the more familiar researchers, key cell banking parameters such as the cell density and hold conditions have been reviewed to possibly help optimize their specific cell freezing protocols. It is important to understand the mechanisms underlying the freezing of complex and sensitive cellular entities as we implement best practices around the techniques and strategies used for cryopreservation.