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Elucidating the Important Structural Features of Aryl Glycosides and Antifreeze Glycoprotein Disaccharide Analogs for Ice Recrystallization InhibitionMusca, Vanessa January 2017 (has links)
Cryopreservation of human red blood cells (RBCs) extends the storage time from 42 days (hypothermic storage limit) to a maximum of 10 years. While this reduces the possibility of RBC shortages in emergency situations, this preservation method is currently limited to individuals with rare blood phenotypes, patients who require autologous blood transfusions, and military applications. Furthermore, cryopreservation is associated with a high degree of cellular damage, which can subsequently reduce the viability of cells post-thaw. The cellular damage incurred upon cryopreservation is primarily attributed to the process of ice recrystallization. To reduce the degree of cellular damage, cryoprotective agents (CPAs) are used. Currently, 10 % dimethyl sulphoxide (DMSO) and 40 % glycerol are used for the cryopreservation of hematopoietic stem cells (HSCs) and human RBCs respectively. Unfortunately, these CPAs do not provide protection against ice recrystallization.
The biological antifreezes (BAs) consisting of antifreeze proteins (AFPs) and antifreeze glycoproteins (AFGPs) were identified as the first inhibitors of ice recrystallization. Consequently, the Ben laboratory is interested in synthesizing small molecule carbohydrate-based inhibitors of ice recrystallization that can be used as an alternative to glycerol or DMSO for the cryopreservation of various cell types. Therefore, this thesis focuses on elucidating important structural features of carbohydrate-based derivatives that are responsible for IRI activity. The first part of this study examines the importance of the anomeric oxygen atom of aryl glycosides for IRI activity. Our laboratory previously demonstrated that the O-linked aryl glycosides are effective inhibitors of ice recrystallization. However, the influence of stereoelectronic effects at the C1 position of aryl glycosides on IRI activity has not been investigated. As a result, N- and S-linked aryl glycosides were synthesized in this study and their IRI activities were compared to that of the O-linked aryl glycosides. These results suggest that a stronger exo-anomeric effect exhibited by the C1 nitrogen derivatives reduces the IRI activity of aryl glycosides.
The second part of this study focuses on the synthesis of AFGP disaccharide analogs. While the β-(1,3) glycosidic linkage found in native AFGP-8 was previously assessed for its influence on IRI activity, an extensive structure-function analysis of AFGP disaccharide analogs has not yet been performed. As a result, an AFGP disaccharide analog was designed whereby a para-methoxyphenyl (PMP) substituent was incorporated. This was done to assess whether the PMP substituent could enhance the lack of IRI activity exhibited previously with AFGP disaccharide analogs. Although the synthesis of this disaccharide target was not completed, a number of advantageous developments have been made regarding the glycosylation of N-acetyl-D-glycosamine derivatives. In addition, the PMP-GlcNAc intermediate encountered in disaccharide synthesis was assessed for its IRI activity, confirming that the acetamido (NHAc) function is not required for IRI activity.
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Investigating the Importance of Electronic and Hydrophobic Effects for Ice Recrystallization Inhibition Using 'Beta'-'O'-Aryl GlycosidesAlteen, Matthew January 2014 (has links)
The cryopreservation of cells and tissues requires the addition of a cryoprotectant in order to prevent cellular damage caused by ice. Unfortunately, common cryoprotectants such as DMSO and glycerol exhibit significant toxicity which makes their use unfeasible for many clinical procedures. Our laboratory is interested in the development of alternative, non-toxic cryoprotectants which possess ice recrystallization inhibition (IRI) activity. Potent IRI activity has recently been discovered in certain small molecules, but the structural features required for this process are unclear. Herein we report the development of a library of O-aryl glycosides in order to probe the importance of electron density and hydrophobic moieties for IRI activity. It was found that the degree of electron density at the anomeric oxygen does not correlate with IRI ability in para-substituted aryl glycosides, nor does changing the position of the aryl substituent impart a predictable effect on activity. However, the addition of hydrophobic alkyl or acyl chains was beneficial for IRI activity; generally, increasing chain length was found to correlate with increasing activity. In some instances, an optimal alkyl chain length was identified, after which continued lengthening results in a loss of potency. We conclude from this study that a certain extent of hydrophobic character is beneficial for the IRI activity of aryl glycosides, and that a balance between hydrophobicity and hydrophilicity is required for optimum IRI ability. It is hoped that these findings will aid future efforts towards the rational design of novel cryoprotectants.
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The Rational Design of Potent Ice Recrystallization Inhibitors for Use as Novel CryoprotectantsCapicciotti, Chantelle January 2014 (has links)
The development of effective methods to cryopreserve precious cell types has had tremendous impact on regenerative and transfusion medicine. Hematopoietic stem cell (HSC) transplants from cryopreserved umbilical cord blood (UCB) have been used for regenerative medicine therapies to treat conditions including hematological cancers and immodeficiencies. Red blood cell (RBC) cryopreservation in blood banks extends RBC storage time from 42 days (for
hypothermic storage) to 10 years and can overcome shortages in blood supplies from the high demand of RBC transfusions. Currently, the most commonly utilized cryoprotectants are 10%
dimethyl sulfoxide (DMSO) for UCB and 40% glycerol for RBCs. DMSO is significantly toxic
both to cells and patients upon its infusion. Glycerol must be removed to <1% post-thaw using
complicated, time consuming and expensive deglycerolization procedures prior to transfusion to prevent intravascular hemolysis. Thus, there is an urgent need for improvements in
cryopreservation processes to reduce/eliminate the use of DMSO and glycerol.
Ice recrystallization during cryopreservation is a significant contributor to cellular injury and
reduced cell viability. Compounds capable of inhibiting this process are thus highly desirable as novel cryoprotectants to mitigate this damage. The first compounds discovered that were ice recrystallization inhibitors were the biological antifreezes (BAs), consisting of antifreeze proteins and glycoproteins (AFPs and AFGPs). As such, BAs have been explored as potential cryoprotectants, however this has been met with limited success. The thermal hysteresis (TH)activity and ice binding capabilities associated with these compounds can facilitate cellular damage, especially at the temperatures associated with cryopreservation. Consequently,
compounds that possess “custom-tailored” antifreeze activity, meaning they exhibit the potent ice recrystallization inhibition (IRI) activity without the ability to bind to ice or exhibit TH activity,are highly desirable for potential use in cryopreservation.
This thesis focuses on the rational design of potent ice recrystallization inhibitors and on
elucidating important key structural motifs that are essential for potent IRI activity. While
particular emphasis in on the development of small molecule IRIs, exploration into structural
features that influence the IRI of natural and synthetic BAs and BA analogues is also described as these are some of the most potent inhibitors known to date. Furthermore, this thesis also
investigates the use of small molecule IRIs for the cryopreservation of various different cell types to ascertain their potential as novel cryoprotectants to improve upon current cryopreservation protocols, in particular those used for the long-term storage of blood and blood products.
Through structure-function studies the influence of (glyco)peptide length, glycosylation and
solution structure for the IRI activity of synthetic AFGPs and their analogues is described. This thesis also explores the relationship between IRI, TH and cryopreservation ability of natural
AFGPs, AFPs and mutants of AFPs. While these results further demonstrated that BAs are
ineffective as cryoprotectants, it revealed the potential influence of ice crystal shape and growth progression on cell survival during cryopreservation.
One of the most significant results of this thesis is the discovery of alkyl- and phenolicglycosides as the first small molecule ice recrystallization inhibitors. Prior to this discovery, all reported small molecules exhibited only a weak to moderate ability to inhibit ice recrystallization.
To understand how these novel small molecules inhibit this process, structure-function studies
were conducted on highly IRI active molecules. These results indicated that key structural
features, including the configuration of carbons bearing hydroxyl groups and the configuration of
the anomeric center bearing the aglycone, are crucial for potent activity. Furthermore, studies on the phenolic-glycosides determined that the presence of specific substituents and their position on the aryl ring could result in potent activity. Moreover, these studies underscored the sensitivity of IRI activity to structural modifications as simply altering a single atom or functional group on this substituent could be detrimental for activity.
Finally, various IRI active small molecules were explored for their cryopreservation potential
with different cell types including a human liver cell line (HepG2), HSCs obtained from human
UCB, and RBCs obtained from human peripheral blood. A number of phenolic-glycosides were
found to be effective cryo-additives for RBC freezing with significantly reduced glycerol
concentrations (less than 15%). This is highly significant as it could drastically decrease the
deglycerolization processing times that are required when RBCs are cryopreserved with 40%
glycerol. Furthermore, it demonstrates the potential for IRI active small molecules as novel
cryoprotectants that can improve upon current cryopreservation protocols that are limited in terms of the commonly used cryoprotectants, DMSO and glycerol.
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