1,2-Ethanediol

1,2-Ethanediol, also known as ethylene glycol, is a simple organic compound with the chemical formula C2H6O2. It is a colorless, odorless, viscous liquid that is miscible with water []. Ethylene glycol is produced industrially from petroleum or natural gas [].

Ethylene glycol is a versatile compound with numerous applications in various scientific fields. One of its significant contributions is its role as a precursor in the production of polyester fibers, which are used in textiles, clothing, and industrial materials [].

Molecular Structure Analysis

The ethylene glycol molecule consists of two hydroxyl groups (OH) bonded to a central carbon chain (CH2-CH2). This structure classifies it as a vicinal diol []. The presence of hydroxyl groups makes it a polar molecule capable of forming hydrogen bonds with itself and other polar molecules, influencing its physical properties [].

Chemical Reactions Analysis

Ethylene glycol undergoes various chemical reactions relevant to scientific research. Here are two key examples:

• Synthesis: Ethylene glycol is typically synthesized through the hydration of ethylene oxide using water as a catalyst [].

C2H4O + H2O -> C2H6O2

• Esterification: Ethylene glycol reacts with carboxylic acids in the presence of an acid catalyst to form esters, which are important in polymer synthesis and other applications [].

RCOOH + HOCH2CH2OH  <=> RCOOCH2CH2OH + H2O  (R = organic group)

Physical And Chemical Properties Analysis

• Melting point: -13°C []
• Boiling point: 197°C []
• Density: 1.11 g/cm³ []
• Solubility: Miscible with water, alcohol, and many other polar solvents []
• Stability: Relatively stable under normal conditions []

Chromatography Solvent

Ethylene glycol's high boiling point, miscibility with water and various organic solvents, and ability to form hydrogen bonds make it a valuable chromatography solvent. It is particularly useful in:

• High-performance liquid chromatography (HPLC): Ethylene glycol is used as a mobile phase component in HPLC for separating various polar and non-polar compounds.
• Gas chromatography (GC): When used as a stationary phase in GC, ethylene glycol helps separate polar and thermally labile compounds.

Organic Synthesis Reagent

Ethylene glycol serves as a versatile organic synthesis reagent due to its reactivity and ability to participate in various chemical reactions. Some examples include:

• Synthesis of polyesters: Ethylene glycol is a crucial building block for producing polyesters like polyethylene terephthalate (PET), widely used in plastics and textiles.
• Preparation of acetals: Ethylene glycol reacts with aldehydes and ketones to form acetals, which find applications in organic synthesis and protecting groups for other functional groups.

Enzyme and Protein Stabilizer

Ethylene glycol's ability to form hydrogen bonds with water molecules helps stabilize enzymes and proteins by preventing them from unfolding and losing their function. This property makes it useful in:

• Protein crystallography: Ethylene glycol is used as a cryoprotectant to protect protein crystals during X-ray diffraction studies for determining protein structures.
• Enzyme storage: Ethylene glycol solutions are used to store enzymes at low temperatures, preserving their activity for extended periods.

Other Research Applications

Beyond the areas mentioned above, ethylene glycol is also involved in various other scientific research applications, such as:

• Studying antifreeze properties: Ethylene glycol's ability to lower the freezing point of water makes it a model system for understanding antifreeze mechanisms in living organisms.
• Developing biocompatible materials: Research is ongoing to explore the potential of ethylene glycol derivatives for developing biocompatible materials for drug delivery and tissue engineering applications.

Comparison and Validation of Force Fields for Deep Eutectic Solvents in Combination with Water and Alcohol Dehydrogenase

Jan Philipp Bittner, Lei Huang, Ningning Zhang, Selin Kara, Sven Jakobtorweihen
PMID: 34232662   DOI: 10.1021/acs.jctc.1c00274

Abstract

Deep eutectic solvents (DESs) have become popular as environmental-friendly solvents for biocatalysis. Molecular dynamics (MD) simulations offer an in-depth analysis of enzymes in DESs, but their performance depends on the force field chosen. Here, we present a comprehensive validation of three biomolecular force fields (CHARMM, Amber, and OPLS) for simulations of alcohol dehydrogenase (ADH) in DESs composed of choline chloride and glycerol/ethylene glycol with varying water contents. Different properties (e.g., protein structure and flexibility, solvation layer, and H-bonds) were used for validation. For two properties (viscosity and water activity) also experiments were performed. The viscosity was calculated with the periodic perturbation method, whereby its parameter dependency is disclosed. A modification of Amber was identified as the best-performing model for low water contents, whereas CHARMM outperforms the other models at larger water concentrations. An analysis of ADH's structure and interactions with the DESs revealed similar predictions for Amber and CHARMM.

Quantum chemical calculations on dissolution of dimethylformamide in ethaline

Payam Kalhor, Ommolbanin Yarivand, Kumars Seifpanahi-Shabani
PMID: 34174555   DOI: 10.1016/j.jmgm.2021.107966

Abstract

Deep-eutectic solvents (DESs) gained attention of researchers as green solvents. Making binary mixtures of DESs with appropriate cosolvents is a strategy to obtain more favorable mixtures. Here, structural features and hydrogen bonding (H-bonding) properties of binary mixtures containing ethaline (ETH) DES, (choline chloride (ChCl):2 ethylene glycol (EG)) with N,N-dimethylformamide (DMF) are reported. Such investigations are carried out by density functional theory (DFT) calculations. The results show that in ETH-DMF mixtures, DMF molecules can hardly overcome the strong Columbic interaction and doubly ionic H-bonds between the ions Ch
and Cl
or the ionic H-bonds between Ch
and EG. Upon EG addition to ChCl to obtain ETH or DMF addition to ETH, the Cl
Ch
connectivity decreases, implying charge delocalization from Cl
to other components rather than Ch
. This is supported by the blue shift of Ch
hydroxyl observed in the calculated infrared spectra.

Vesicle Formation by the Self-Assembly of Gold Nanoparticles Covered with Fluorinated Oligo(ethylene glycol)-Terminated Ligands and Its Stability in Aqueous Solution

Jinjian Wei, Xiaoying Huang, Liang Zhang, Yuqin Chen, Kenichi Niikura, Hideyuki Mitomo, Kuniharu Ijiro, Zhide Zhang
PMID: 34369779   DOI: 10.1021/acs.langmuir.1c00996

Abstract

Water-stable gold nanoparticle vesicles (GNVs) with hollow interiors have attracted attention due to their great potential for biological applications; however, their preparation through the self-assembly approaches has been restricted due to the limited understanding of their critical mechanistic issues. In this paper, we demonstrate that a fluorinated tetra (ethylene glycol) (FTEG)-terminated tetra (ethylene glycol) (EG4), namely, FTEG-EG4, ligand can self-assemble with gold nanoparticles (5 and 10 nm) into GNVs with a hollow structure in THF due to the solvophobic feature of the ligand. Time-dependent studies showed that the GNVs with a closely packed surface derived from the incomplete and irregular GNVs, but not through the fusion of the GNV precursors. After dialysis in water, the assemblies retained vesicular structures in water, even though GNVs aggregated together, which was initiated by the hydrophobic interactions between the FTEG heads of the surface ligands on GNVs. This study provides a new insight into the design of novel small surface ligands to produce water-stable GNVs for biological applications.

Exergetic performance evaluation of a diesel engine powered by diesel/biodiesel mixtures containing oxygenated additive ethylene glycol diacetate

Sama Amid, Mortaza Aghbashlo, Wanxi Peng, Ali Hajiahmad, Bahman Najafi, Hassan S Ghaziaskar, Hajar Rastegari, Pouya Mohammadi, Homa Hosseinzadeh-Bandbafha, Su Shiung Lam, Meisam Tabatabaei
PMID: 34147796   DOI: 10.1016/j.scitotenv.2021.148435

Abstract

A diesel engine running on diesel/biodiesel mixtures containing ethylene glycol diacetate (EGDA) was investigated from the exergoeconomic and exergoenvironmental viewpoints. Biodiesel was mixed with petrodiesel at 5% and 20% volume ratios, and the resultant mixtures were then doped with EGDA at 1-3% volume ratios. The exergetic sustainability indicators of the engine operating on the prepared fuel formulations were determined at varying engine loads. The indicators were selected to support decision-making on fuel composition and engine load following thermodynamic, economic, and environmental considerations. The engine load markedly affected all the studied exergetic parameters. The highest engine exergetic efficiency (39.5%) was obtained for petrodiesel doped with 1 v/v% EGDA at the engine load of 50%. The minimum value of the unit cost of brake power exergy (49.6 US$/GJ) was found for straight petrodiesel at full-load conditions, while the minimum value of the unit environmental impact of brake power exergy (29.9 mPts/GJ) was observed for petrodiesel mixed with 5 v/v% biodiesel at the engine load of 75%. Overall, adding EGDA to fuel mixtures did not favorably influence the outcomes of both exergetic methods due to its energy-intensive and cost-prohibitive production process. In conclusion, although petrodiesel fuel improvers such EGDA used in the present study could properly mitigate pollutant emissions, the adverse effects of such additives on thermodynamic parameters of diesel engines, particularly on exergoeconomic and exergoenvironmental indices, need to be taken into account, and necessary optimizations should be made before their real-world application.

Vitrification of immature bovine oocytes in protein-free media: The impact of the cryoprotectant treatment protocol, base medium, and ovary storage

Tamás Somfai, Yuji Hirao
PMID: 34098168   DOI: 10.1016/j.theriogenology.2021.05.029

Abstract

Protein-free media are essential for the sanitary cryopreservation of bovine genetic resources. Our aim was to set up an optimized protocol for the vitrification of immature bovine oocytes using protein free media which can provide the highest embryo development rates and embryo quality after subsequent in vitro maturation and fertilization. First, using a protein free NCSU-37 as base medium we compared the efficacy of vitrification on Cryotop device with two different CPA protocols. "Protocol A″ employed a combination of ethylene glycol and propylene glycol as permeating cryoprotectants (pCPA) and equilibration in 4% total pCPA (2% ethylene glycol + 2% propylene glycol). "Protocol B″ employed a combination of ethylene glycol and DMSO and equilibration in 15% total pCPA (7.5% ethylene glycol + 7.5% DMSO). The 2 protocols were equally effective in terms of oocyte survival and subsequent development to the blastocyst stage. However, blastocyst cell numbers were significantly higher with "Protocol A". TCM-199 and NCSU-37 were equally effective as base media for vitrification. Vitrification with "Protocol A″ reduced the percentage of live oocytes and subsequent development to blastocyst stage but did not affect the hatching and cell numbers of blastocysts when compared to the non-treated group. CPA treatment of "Protocol A″ without cooling did not affect embryo development. Storage of ovaries in PBS at 15 °C for overnight reduced the percentage of surviving oocytes after vitrification but not their subsequent development to the blastocyst stage. In conclusion we established a vitrification protocol for the cryopreservation of immature bovine oocytes employing protein-free media which provided high blastocyst quality without noticeable toxic effects.

Effective Na

Shinya Seto, Takashi Takeda, Norihisa Hoshino, Tomoyuki Akutagawa
PMID: 34086464   DOI: 10.1021/acs.jpcb.1c03188

Abstract

A new amphiphilic penta(ethylene glycol) derivative (
) bearing two hydrogen-bonding -CONHC
H
chains was prepared. Compound
exhibited ion-recognition abilities for Na
and K
, and its properties were compared with those of the macrocyclic [18]crown-6. Although both compound
and [18]crown-6 have six ether oxygen atoms (-OC
H
-), the Na
-binding ability of the former was much higher than that of the latter. K
-binding ability of cyclic [18]crown-6 was much higher than its Na
-binding ability, while the reverse was true for acyclic compound
. Single-crystal X-ray structural analysis of Na
·
·B(Ph)
·(hexane)
at 100 K revealed the existence of a wrapped Na
-coordination by six ether and one carbonyl oxygen atoms of
, which was further stabilized by intramolecular N-H···O═ hydrogen-bonding interactions. The complex phase transition during glass (G) formation and recrystallization was confirmed in the thermal cycle of Na
·
·B(Ph)
, whose molten state showed two kinds of liquid phases, Na
-complexed (Na
·
) + B(Ph)
and completely dissociated Na
+
+ B(Ph)
. The Na
conductivity of the molten state was 2 orders of magnitude higher than that of the G phase.

Search for H-Bonded Motifs in Liquid Ethylene Glycol Using a Machine Learning Strategy

Aman Jindal, Vaishali Arunachalam, Sukumaran Vasudevan
PMID: 34060849   DOI: 10.1021/acs.jpcb.1c01308

Abstract

Trajectories of atomic positions derived from
molecular dynamics (AIMD) simulations of H-bonded liquids contain a wealth of information on dominant structural motifs and recurrent patterns of association. Extracting this information from a detailed search of the trajectories over multiple time frames is, however, a daunting exercise. Here, we use a machine learning strategy based on the neural inspired approach of the self-organizing maps (SOM), a type of artificial neural network that uses unsupervised competitive learning, to analyze the AIMD trajectories of liquid ethylene glycol (EG). The objective was to find whether there are H-bonded fragments, of two or more H-bonded EG molecules, that are recurrent in the liquid and to identify them. The SOM represents a set of high-dimensional data mapped onto a two-dimensional, grid of neurons or nodes, while preserving the topological properties of the input space. We show here that clustering of the fragments by SOM in terms of the molecular conformation of the individual EG molecules of the fragment and their H-bond connectivity pattern facilitates the search for H-bonded motifs. Using this approach, we are able to identify a H-bonded cyclic dimer and a bifurcated H-bonded structure as recurring motifs that appear in the longer H-bonded fragments present in liquid EG.

Toxic Alcohols

Jennifer A Ross, Heather A Borek, Christopher P Holstege
PMID: 34053711   DOI: 10.1016/j.ccc.2021.03.009

Abstract

This article reviews the background, metabolism, clinical effects, and treatment of toxic alcohols, specifically ethylene glycol, methanol, diethylene glycol, propylene glycol, and isopropyl alcohol. This article also reviews the importance of an anion gap metabolic acidosis in relation to toxic alcohols and explores both the utility and the limitations of the osmole gap in patient management.

Site selective C-H functionalization of Mitragyna alkaloids reveals a molecular switch for tuning opioid receptor signaling efficacy

Srijita Bhowmik, Juraj Galeta, Václav Havel, Melissa Nelson, Abdelfattah Faouzi, Benjamin Bechand, Mike Ansonoff, Tomas Fiala, Amanda Hunkele, Andrew C Kruegel, John E Pintar, Susruta Majumdar, Jonathan A Javitch, Dalibor Sames
PMID: 34158473   DOI: 10.1038/s41467-021-23736-2

Abstract

Mitragynine (MG) is the most abundant alkaloid component of the psychoactive plant material "kratom", which according to numerous anecdotal reports shows efficacy in self-medication for pain syndromes, depression, anxiety, and substance use disorders. We have developed a synthetic method for selective functionalization of the unexplored C11 position of the MG scaffold (C6 position in indole numbering) via the use of an indole-ethylene glycol adduct and subsequent iridium-catalyzed borylation. Through this work we discover that C11 represents a key locant for fine-tuning opioid receptor signaling efficacy. 7-Hydroxymitragynine (7OH), the parent compound with low efficacy on par with buprenorphine, is transformed to an even lower efficacy agonist by introducing a fluorine substituent in this position (11-F-7OH), as demonstrated in vitro at both mouse and human mu opioid receptors (mMOR/hMOR) and in vivo in mouse analgesia tests. Low efficacy opioid agonists are of high interest as candidates for generating safer opioid medications with mitigated adverse effects.