Anion Bridges Drive Salting Out of a Simple Amphiphile from Aqueous Solution

Bowron, Daniel T.; Finney, Jl

doi:10.1103/physrevlett.89.215508

Cited by 27 publications

(20 citation statements)

References 22 publications

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“…Neutron diffraction with isotopic substitution is an excellent technique to study the structure of hydrogen-containing fluids, mixtures of fluids, and solutions (12,13,15,16,19,(21)(22)(23)(24)(25)(26)(27)(28)(29)(30)(31). This is due to the difference in scattering intensity by hydrogen and deuterium, which have scattering intensities of b H ¼ ÿ3.73 fm and b D ¼ 6.671 fm, respectively.…”

Section: Theoretical Overviewmentioning

confidence: 99%

The Hydration of the Neurotransmitter Acetylcholine in Aqueous Solution

Hulme

Soper

McLain

et al. 2006

Biophysical Journal

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Neutron diffraction augmented with hydrogen isotope substitution has been used to examine the water structure around the acetylcholine molecular ion in aqueous solution. It is shown that the nearest-neighbor water molecules in the region around the trimethylammonium headgroup are located either in a ring around the central nitrogen atom or between the carbon atoms, forming a sheath around the onium group. Moreover the water molecules in this cavity do not bond to the onium group but rather form hydrogen bonds with water molecules in the surrounding aqueous environment. Given that in the bound state the onium headgroup must be completely desolvated, the absence of bonding between the onium headgroup and the surrounding water solvent may be selectively favorable to acetylcholine-binding in the receptor site. Away from the headgroup, pronounced hydrogen-bonding of water to the carbonyl oxygen is observed, but not to the ether oxygen in the acetylcholine chain.

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Section: Theoretical Overviewmentioning

confidence: 99%

The Hydration of the Neurotransmitter Acetylcholine in Aqueous Solution

Hulme

Soper

McLain

et al. 2006

Biophysical Journal

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“…On the basis of neutron scattering measurements on NaCl in t-butanol, Bowron and Finney proposed that the salting-out effect is driven by a salt bridge consisting of a halide ion linking two alcohol molecules through two IHBs. 10 However, Paschek et al have rejected this suggestion and have instead presented both experimental and theoretical evidence for an alternative mechanism in which a halide ion attaches to the methyl groups in t-butanol and thereby enhances the attractive interactions between the hydrophobic methyl groups in different t-butanol molecules. 11 These two explanations of the salting-out effect are clearly very different.…”

Section: ■ Introductionmentioning

confidence: 99%

“…The ν 3 mode is the symmetric CH stretch of the CH 3 group, while ν 9 and ν 2 are both antisymmetric CH stretches. These mode descriptions are approximate because multiple anharmonic couplings with overtone and combination states, such as 2ν 10 and ν 4 + ν 10 , are well-known in this region. 21 Indeed, a broad feature to the immediate red of the ν 9 band, which is most apparent in Figure 2b,c, probably reflects this additional vibrational complexity.…”

Section: The Journal Of Physical Chemistry a Articlementioning

confidence: 99%

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Infrared Spectroscopy of NaCl(CH₃OH)_n Complexes in Helium Nanodroplets

et al. 2016

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Infrared (IR) spectra of complexes between NaCl and methanol have been recorded for the first time. These complexes were formed in liquid helium nanodroplets by consecutive pick-up of NaCl and CH 3 OH molecules. For the smallest NaCl(CH 3 OH) n , complexes where n = 1−3, the IR data suggest that the lowest-energy isomer is the primary product in each case. The predominant contribution to the binding comes from ionic hydrogen bonds between the OH in each methanol molecule and the chloride ion in the NaCl, as established by the large red shift of the OH stretching bands compared with the isolated CH 3 OH molecule. For n ≥ 4, there is a dramatic shift from discrete vibrational bands to very broad absorption envelopes, suggesting a profound change in the structural landscape and, in particular, access to multiple low-energy isomers. ■ INTRODUCTIONAlkali halides (MX) are archetypal univalent salts. The crystalline structure of the solid is disrupted by water, and these salts readily dissolve to form separated ions in dilute aqueous solutions. If the solid represents one extreme, then the counterpart is an isolated MX molecule. How might this smallest entity of salt, a single MX molecule, behave in the presence of a small water cluster, (H 2 O) n ? This problem can be addressed in experiments by forming isolated MX(H 2 O) n complexes and then using techniques, such as spectroscopy, to determine their properties. Such studies offer insight into the interaction between the constituent ionic particles and the solvent and can be reinforced through quantum chemical calculations. Understanding these interactions and the balance between them is critical in being able to carry out accurate simulations of bulk solutions. An early infrared (IR) spectroscopic study of a NaCl/H 2 O mixture in an argon matrix provided a tentative assignment of vibrational bands of the NaCl(H 2 O) complex.2 The first detailed spectroscopic study of several different NaCl(H 2 O) n complexes (n = 1−3) was obtained by microwave spectroscopy, and this revealed important structural information. 3,4 We have recently shown that complexes between NaCl and water molecules can be formed inside liquid helium nanodroplets, and this made it possible to record the first IR spectra of several small NaCl(H 2 O) n complexes. 5 The spectra for n = 1−3 are consistent with structures in which an ionic hydrogen bond (IHB) is formed between a single OH group in each water molecule and the Cl − in the salt. Evidence for interwater hydrogen bonding only begins to appear for n ≥ 4.An alternative solvent to water is methanol. Most solid alkali halides will dissolve in methanol, but their solubility is far lower than that in water. 6,7 The reduced solubility of salts in methanol when compared with that in water is a consequence of the hydrophobic (CH 3 ) group in the former. It would therefore be interesting to investigate how this amphiphilic character affects the interactions between a single salt molecule and one or more methanol molecules. It is well-known that...

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“…Structural changes that occur along addition of a simple salting-out agent to a dilute aqueous alcohol solution have been studied using neutron diffraction with isotope substitution [22]. It seems that a relatively simple process occurs, in which interamphiphile anionic salt bridges are formed between the polar groups of the alcohol molecules.…”

Section: Discussionmentioning

confidence: 99%