Cryostability of large unilamellar vesicles in relation to the effect of cryoprotective agents on ice matrix

Siow, Lee Fong, n/a

January 2008

Freeze-injury at the plasma membrane level has been identified as being crucial for the survival of living matter. Since plasma membranes consist of several micro domains that make the structure rather complex, this study attempted to use simple model membranes to investigate the changes of phospholipid bilayers at sub-zero temperatures. Egg yolk L-α-phosphatidylcholine (EPC) and 1, 2-dipalmitoyl-rac-glycero-3-phosphocholine (DPPC) that mimic plasma membranes in their unique ways were used to prepare large unilamellar vesicles (LUV), which were the model membranes of this study. At cooling rates of 0.5 and 10�C/min, LUV were freeze-concentrated in the unfrozen matrix as a result of the advancing extraliposomal ice front and the decreasing phase volume of the unfrozen matrix, both of which led to membrane lesion. At the slow cooling rate of 0.5�C/min, an additional freezing stress imposed by the osmotic gradient across the bilayers, due to the increase of solute concentration in the unfrozen matrix, promoted leakage of LUV. The gel-liquid crystal phase transition temperature of phospholipids played an important role in determining if the LUV could withstand freezing stress when the LUV were held at a defined sub-zero temperature for a given period of holding time. EPC LUV were more leaky than DPPC LUV when they were held at the high sub-zero temperatures and their leakage increased with increasing holding time. The leakiness of EPC LUV could be related to the fluid and deformable nature of the EPC above its phase transition temperature. In contrast, DPPC LUV with a higher gel-liquid crystal phase transition temperature compared to EPC may become increasingly fragile at lower sub-zero temperatures, which led to the increase of leakage when the DPPC LUV were held at the lower sub-zero temperatures. These results indicated that the determination of the fatty acid profile of the plasma membranes was essential to aid in developing the most suitable holding temperature and time during the cryopreservation of biological specimens. Adding to the integrity of LUV that depended on the gel-liquid crystal phase transition temperature of phospholipids, intraliposomal ice formation also depended on the phase transition temperature of phospholipids. Intraliposomal ice formation was only observed for DPPC LUV but not for EPC LUV. In addition to the extraliposomal ice formation, other physical changes such as the eutectic crystallization of sodium chloride (NaCl) and ice mixture on the stability of LUV were also investigated. The eutectic crystallization of NaCl/ice mixture was governed by the intra- and extraliposomal distribution of NaCl and was more likely to occur at the physiological NaCl concentrations compared to lower NaCl concentrations. The eutectic crystallization of NaCl/ice mixture further increased the leakage of LUV. The understanding of the freezing behaviour and the mechanisms of freeze-injury of LUV allowed the use of the current model membranes for further investigations of the cryoprotective actions of cryoprotective agents (CPA). Partial phase diagrams of sugar-salt-water, dimethyl sulfoxide (DMSO)-salt-water and ethylene glycol (EG)-salt-water systems that resembled extraliposomal solute compositions were constructed and the phase volume of ice and unfrozen matrix was estimated from the freezing curves. Ice reduction was the major mechanism by which the non-permeable and permeable CPA protected the LUV from freeze-injury. Other cryoprotective mechanisms of the non-permeable and permeable CPA through the dilution and spacing out of the LUV in the unfrozen matrix as well as the suppression of the eutectic crystallization of NaCl/ice mixture were not ruled out. Non-permeable CPA were more effective in preventing leakage of DPPC than EPC LUV. Unlike the non-permeable CPA, permeable CPA were more effective for EPC than DPPC LUV that had been subjected to freezing and thawing processes. At room temperature, however, DMSO and EG were detrimental to the stability of DPPC LUV. The choice of CPA is strictly dependent on the type of phospholipids that varied in their acyl chain length and phase transition temperature. In summary, this study provides insights of the freeze-injury of LUV and the cryoprotective mechanisms of the non-permeable and permeable CPA which are beneficial to the field of cryopreservation that often depends on empirical trial and error methods. By integrating a comprehensive molecular-based understanding, an optimal cryopreservation procedure could be designed.

ice

microbiology

ice crystals

cryobiology

The molecular identification and evaluation of the effects of cold temperatures on Antarctic Pseudomonas spp.

Burke, Genola.

January 2009

Thesis (M.S.)--University of Alabama at Birmingham, 2009. / Description based on contents viewed June 2, 2009; title from PDF t.p. Includes bibliographical references (p. 37-41).

Membrane and Mitochondrial Responses to Cryobiological Conditions

Reardon, Anthony J

Unknown Date

No description available.

Cryobiology

Mitochondria

Plasma Membrane

Flow Cytometry

Cellular osmotic properties and cellular responses to cooling

Ross-Rodriguez, Lisa Ula.

January 2009

Thesis (Ph.D.)--University of Alberta, 2009. / A thesis submitted to the Faculty of Graduate Studies and Research in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Medical Sciences-Laboratory Medicine and Pathology, Department of Laboratory Medicine and Pathology. Title from pdf file main screen (viewed on October 23, 2009). Includes bibliographical references.

Synthesis of Novel Charged Ice Recrystallization Inhibitors

Charlton, Thomas Aurelio

28 June 2021

With emerging trends of new cellular therapies, the need for quick access to cellular components is necessary. For most applications genetically compatible biological components are essential to prevent adverse immune responses and graft-versus host disease (GVHD). Since these biological components have a limited window to be used, techniques for long-term storage are needed. Cryopreservation is essential for this in the field of biobanking and regenerative medicine to allow for long-term storage of cell products. During this process, ice recrystallization is the major contributor to cell death and decreased cell viability post-thaw. Due to this, controlling ice growth and recrystallization is imperative to increasing cell survival and function. The Ben lab is focused on the synthesis of small molecule, carbohydrate-based cryoprotectants that function as ice recrystallization inhibitors (IRIs). Previously, many IRIs have been synthesized showing varying degrees of ice recrystallization inhibition (IRI). Through the structure-function work, a delicate balance between hydrophobic and hydrophilic portions on the same molecule must be met. These compounds are believed to disrupt hydrogen bonding networks present in the formation of ice, and control ice growth. While numerous types of functional groups on carbohydrate derivatives have been explored, many highly solvated functional groups (amines, sulfates, phosphates, etc.) have not been thoroughly investigated. Highly solvated functional groups should disrupt hydrogen bond networks due to their solvation and in theory, should illicit an IRI response. Sulfate groups have not previously been studied, but are present in several different biological processes, such as immune response and blood coagulation. This suggests that sulfated carbohydrates should be well tolerated biologically. Sulfate groups can also be easily installed on existing IRI active molecules through orthogonal protecting group chemistry. The first part of this thesis is focused on the synthesis and IRI activity of sulfated carbohydrates based upon previously synthesized, IRI active pyranose derivatives. When compared to their parent compounds, most of the sulfated derivatives were less active, but all compounds were incredibly soluble in aqueous media. These derivatives did not show much promise as new IRIs due to the length of their synthesis and reduced IRI activity compared to their parent compounds. The Ben lab has also developed a new class of IRI active carbohydrates: aldonamide derivatives. These compounds are open-chain carbohydrates with an amide bond, arising from the ring opening of a carbohydrate lactone with a substituted amine. While many of these compounds displayed high degrees of IRI activity, many were incredibly insoluble in aqueous systems (many with solubility limits under 50 mM). Since sulfate groups were able to greatly increase solubility with some derivatives retaining IRI activity, installing sulfate groups on existing aldonamide-based IRIs should increase their solubility. Additionally, since many of these derivatives display high degrees of IRI activity, a reduction in IRI activity can be tolerated. Similarly, to the sulfated pyranose derivatives, the presence of a sulfate group reduced the IRI activity compared to the parent compounds in most derivatives. Though some sulfated derivatives possessed a higher degree of IRI activity, all the derivatives experienced a drastic increase in solubility (over 200 mM in PBS). Some of the sulfated aldonamide derivatives were assessed for their ability to protect red blood cells (RBCs) during freezing with reduced glycerol concentrations (15% glycerol), although none of thew tested derivatives showed an improvement over existing IRIs explored by the Ben lab. Since the introduction of sulfate groups to existing IRIs drastically increased solubility in aqueous systems, but resulted in reduced IRI activity in most compounds, focus was switched to the addition of different hydrophilic functional groups. Amino functional groups were briefly explored with galactose-based pyranose IRIs, aldonamide derivatives had not been explored. Amino groups are present on many biological carbohydrates and should be well tolerated biologically. The addition of amino groups to aldonamide derivatives should increase solubility, with the amino derivatives ideally retaining some IRI activity. The amino aldonamide derivatives synthesized had high solubilities (>500 mM in PBS), but did possess lower degrees of IRI activity. Due to the high solubility these derivatives were initially assessed in the cryopreservation of RBCs with reduced glycerol concentrations. Initial experiments showed improvements over current IRIs, and the compounds were assessed in a number of other biological cryopreservation scenarios including articular cartilage, platelets, and hematopoietic stem/progenitor cells (HSPCs). While the compounds showed toxicity in these cell types, more studies need to be conducted for the cryopreservation of RBCs.

Carbohydrate Synthesis

Cryobiology

Cryopreservation

Ice Recrystallization Inhibitors

Application of insect freeze tolerant strategies to the freezing of bovine embryos

Whitman, Sarah S.

January 1984

Hemolymph of Tipula trivittata larvae permits freeze tolerance of this insect due to its content of cryoprotectants and ice nucleating proteins. Spontaneous ice nucleation of the dialyzed hemolymph occurs between -5 C and -11 C up to dilutions of 1:1000. The objectives of this study were to evaluate the effects of seeding temperature (-5 C vs -7 C), and the presence of hemolymph at a low (.1% v/v) and a high (10% v/v) level on the survival of frozen-thawed bovine embryos. In Exp. l, survival rates of 6 and 7 day bovine embryos frozen in medium containing .1% hemolymph and seeded at -5 C or -7 C, were compared to evaluate the effect of seeding temperature. The effect of hemolymph was evaluated by including a control without hemolymph seeded at -7 C. In Exp. 2, survival rates of embryos frozen with and without 10% hemolymph were compared. In Exp. 3 the evaluation of the effect of 10% hemolymph was continued. Also included was a control handled identically to embryos frozen in medium with 10% hemolymph regarding pre and post freeze manipulations but which was not frozen. This allowed evaluation of freezing damage per se. For Exps. l, 2, and 3, survival based on mean final development score and time to advance a developmental stage in vitro did not differ for embryos frozen. However, in Exp.· 3, the control which was not frozen had 30% greater survival than embryos undergoing the same manipulations but which were frozen. Thus, neither seeding temperature nor inclusion of .1% or 10% hemolymph in freezing medium had a significant effect on survival of frozen-thawed bovine embryos. / Master of Science

LD5655.V855 1984.W488

Embryo transplantation

Cryobiology

Effects of freezing and frozen storage on histologic characteristics of canine tissues

Baraibar, Martha A.

January 1984

Call number: LD2668 .T4 1984 B37 / Master of Science

Veterinary histology.

Dogs--Physiology.

Veterinary pathology.

Cryobiology.

Masters theses

Kinetic Study of Intracellular Ice Formation in Micropatterned Endothelial Cell Cultures Using High Speed Video Cryomicroscopy

Stott, Shannon Leigh

10 July 2006

Intracellular ice formation (IIF), a major cause of cryoinjury in biological cells, is significantly more pronounced during freezing of tissue than during freezing of suspended cells. While extensive studies of IIF have been conducted for single cells in suspension, few have investigated IIF in tissue. Due to the increased complexity that arises from both cell-substrate and cell-cell interactions in tissue, knowledge of cryobiology of isolated cells cannot simply be extrapolated to tissue. Different theories have been hypothesized for the mechanisms of IIF in tissue, but none have been conclusively proven. Towards the goal of developing mathematical models to accurately predict the probability of IIF in tissues of one or more cell types, we have developed a novel high-speed video cryomicroscopy system capable of image acquisition at sampling rates up to 32,000 Hz. Specifically, the effects of cell adhesion to the substrate and cell-cell interactions were investigated with experimental (micropatterned endothelial cell constructs) and mathematical models (Monte Carlo simulations). We have reported the first direct observations of the IIF process recorded at unprecedented sub-millisecond and sub-micron resolution. For the majority of our experiments, IIF nucleation was determined to occur preferentially at the cell perimeter. This observation was not consistent with the commonly accepted hypotheses of ice nucleation in suspended cells and suggests that an alternative mechanism of IIF initiation is dominant in adherent cells. In addition, the kinetics of ice nucleation were shown to be influenced by time in culture, attached cell perimeter, fibronectin coating density, and degree of cell-cell contact. Moreover, an additional phenomenon, paracellular ice penetration was identified, and the frequency of formation was correlated with focal adhesion formation. The data and mathematical models presented in this thesis bring closer the goal of elucidating the primary mechanisms contributing to IIF in tissue; providing important contributions to both the fields of cryopreservation (minimizing IIF) and cryosurgery (maximizing IIF).

Cryopreservation

IIF

Modeling

Cryosurgery

Cryobiology

Cryomicroscopy

The application of the multisolute osmotic virial equation to cryobiology

Prickett, Richelle Catherine.

January 2010

Thesis (Ph. D.)--University of Alberta, 2010. / Title from pdf file main screen (viewed on Jan. 15, 2010). A thesis submitted to the Faculty of Graduate Studies and Research in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Chemical Engineering and Medical Sciences, Departments of Chemical and Materials Engineering and Medical Sciences - Laboratory Medicine and Pathology, University of Alberta. Includes bibliographical references.

Cryobiological characteristics of red blood cells from human umbilical cord blood

Zhurova, Mariia

Unknown Date

No description available.

red blood cell

umbilical cord blood

cryobiology

osmotic parameters