Robert N. Ben scite author profile

The ability to replace organs and tissues on demand could save or improve millions of lives each year globally and create public health benefits on par with curing cancer. Unmet needs for organ and tissue preservation place enormous logistical limitations on transplantation, regenerative medicine, drug discovery, and a variety of rapidly advancing areas spanning biomedicine. A growing coalition of researchers, clinicians, advocacy organizations, academic institutions, and other stakeholders has assembled to address the unmet need for preservation advances, outlining remaining challenges and identifying areas of underinvestment and untapped opportunities. Meanwhile, recent discoveries provide proofs of principle for breakthroughs in a family of research areas surrounding biopreservation. These developments indicate that a new paradigm, integrating multiple existing preservation approaches and new technologies that have flourished in the past 10 years, could transform preservation research. Capitalizing on these opportunities will require engagement across many research areas and stakeholder groups. A coordinated effort is needed to expedite preservation advances that can transform several areas of medicine and medical science.

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Potent inhibition of ice recrystallization by low molecular weight carbohydrate-based surfactants and hydrogelators

Capicciotti

et al. 2012

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Ice recrystallization inhibition (IRI) activity is a very desirable property for an effective cryoprotectant. This property was first observed in biological antifreezes (BAs), which cannot be utilized in cryopreservation due to their ability to bind to ice. To date, potent IRI active compounds have been limited to BAs or synthetic C-linked AFGP analogues (1 and 2), all of which are large peptide-based molecules. This paper describes the first example of low molecular weight carbohydrate-based derivatives that exhibit potent IRI activity. Non-ionic surfactant n-octyl-b-D-galactopyranoside (4) exhibited potent IRI activity at a concentration of 22 mM, whereas hydrogelator N-octyl-Dgluconamide (5) exhibited potent IRI activity at a low concentration of 0.5 mM. Thermal hysteresis measurements and solid-state NMR experiments indicated that these derivatives are not exhibiting IRI activity by binding to ice. For non-ionic surfactant derivatives (3 and 4), we demonstrated that carbohydrate hydration is important for IRI activity and that the formation of micelles in solution is not a prerequisite for IRI activity. Furthermore, using solid-state NMR and rheology we demonstrated that the ability of hydrogelators 5 and 6 to form a hydrogel is not relevant to IRI activity. Structurefunction studies indicated that the amide bond in 5 is an essential structural feature required for potent IRI activity.

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The Importance of Hydration for Inhibiting Ice Recrystallization with C-Linked Antifreeze Glycoproteins

et al. 2008

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Hydration IndexA Better Parameter for Explaining Small Molecule Hydration in Inhibition of Ice Recrystallization

Tam¹,

Ferreira²,

Czechura³

et al. 2008

J. Am. Chem. Soc.

131

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Several simple mono- and disaccharides have been assessed for their ability to inhibit ice recrystallization. Two carbohydrates were found to be effective recrystallization inhibitors. D-galactose (1) was the best monosaccharide and D-melibiose (5) was the most active disaccharide. The ability of each carbohydrate to inhibit ice growth was correlated to its respective hydration number reported in the literature. A hydration number reflects the number of tightly bound water molecules to the carbohydrate and is a function of carbohydrate stereochemistry. It was discovered that using the absolute hydration number of a carbohydrate does not allow one to accurately predict its ability to inhibit ice recrystallization. Consequently, we have defined a hydration index in which the hydration number is divided by the molar volume of the carbohydrate. This new parameter not only takes into account the number of water molecules tightly bound to a carbohydrate but also the size or volume of a particular solute and ultimately the concentration of hydrated water molecules. The hydration index of both mono- and disaccharides correlates well with experimentally measured RI activity. C-Linked derivatives of the monosaccharides appear to have RI activity comparable to that of their O-linked saccharides but a more thorough investigation is required. The relationship between carbohydrate concentration and RI activity was shown to be noncolligative and a 0.022 M solution of D-galactose (1) and C-linked galactose derivative (10) inhibited recrystallization as well as a 3% DMSO solution. The carbohydrates examined in this study did not possess any thermal hysteresis activity (selective depression of freezing point relative to melting point) or dynamic ice shaping. As such, we propose that they are inhibiting recrystallization at the interface between bulk water and the quasi liquid layer (a semiordered interface between ice and bulk water) by disrupting the preordering of water.

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Small Molecule Ice Recrystallization Inhibitors Enable Freezing of Human Red Blood Cells with Reduced Glycerol Concentrations

Capicciotti

Kurach

Turner

et al. 2015

Sci Rep

109

128

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In North America, red blood cells (RBCs) are cryopreserved in a clinical setting using high glycerol concentrations (40% w/v) with slow cooling rates (~1°C/min) prior to storage at −80°C, while European protocols use reduced glycerol concentrations with rapid freezing rates. After thawing and prior to transfusion, glycerol must be removed to avoid intravascular hemolysis. This is a time consuming process requiring specialized equipment. Small molecule ice recrystallization inhibitors (IRIs) such as β-PMP-Glc and β-pBrPh-Glc have the ability to prevent ice recrystallization, a process that contributes to cellular injury and decreased cell viability after cryopreservation. Herein, we report that addition of 110 mM β-PMP-Glc or 30 mM β-pBrPh-Glc to a 15% glycerol solution increases post-thaw RBC integrity by 30-50% using slow cooling rates and emphasize the potential of small molecule IRIs for the preservation of cells.

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Robert N. Ben

The promise of organ and tissue preservation to transform medicine

Potent inhibition of ice recrystallization by low molecular weight carbohydrate-based surfactants and hydrogelators

The Importance of Hydration for Inhibiting Ice Recrystallization with C-Linked Antifreeze Glycoproteins

Hydration IndexA Better Parameter for Explaining Small Molecule Hydration in Inhibition of Ice Recrystallization

Small Molecule Ice Recrystallization Inhibitors Enable Freezing of Human Red Blood Cells with Reduced Glycerol Concentrations

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