Mohammed Ahmed scite author profile

Raman spectroscopy in combination with multivariate curve resolution (Raman-MCR) is used to explore the interaction between water and various kosmotropic and chaotropic anions. Raman-MCR of aqueous Na-salt (NaI, NaBr, NaNO3, Na2SO4, and Na3PO4) solutions provides solute-correlated Raman spectra (SC-spectra) of water. The SC-spectra predominantly bear the vibrational characteristics of water in the hydration shell of anions, because Na(+)-cation has negligible effect on the OH stretch band of water. The SC-spectra for the chaotropic I(-), Br(-), and NO3(-) anions and even for the kosmotropic SO4(2-) anion resemble the Raman spectrum of isotopically diluted water (H2O/D2O = 1/19; v/v) whose OH stretch band is largely comprised by the response of vibrationally decoupled OH oscillators. On the other hand, the SC-spectrum for the kosmotropic PO4(3-) anion is quite similar to the Raman spectrum of H2O (bulk). Comparison of the peak positions of SC-spectra and the Raman spectrum of isotopically diluted water suggests that the hydrogen bond strength of water in the hydration shell of SO4(2-) is comparable to that of the isotopically diluted water, but that in the hydration shell of I(-), Br(-), and NO3(-) anions is weaker than that of the latter. Analysis of integrated area of component bands of the SC-spectra reveals ∼80% reduction of the delocalization of vibrational modes (intermolecular coupling and Fermi resonance) of water in the hydration shell of I(-), Br(-), NO3(-), and SO4(2-) anions. In the case of trivalent PO4(3-), the vibrational delocalization is presumably reduced and the corresponding decrease in spectral response at ∼3250 cm(-1) is compensated by the increased signal of strongly hydrogen bonded (but decoupled) water species in the hydration shell. The peak area-averaged wavenumber of the SC-spectrum increases as PO4(3-) < SO4(2-) < NO3(-) < Br(-) < I(-) and indeed suggests strong hydrogen bonding of water in the hydration shell of PO4(3-) anion.

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Bend Vibration of Surface Water Investigated by Heterodyne-Detected Sum Frequency Generation and Theoretical Study: Dominant Role of Quadrupole

Kundu

Tanaka

Ishiyama

et al. 2016

J. Phys. Chem. Lett.

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Heterodyne-detected vibrational sum frequency generation spectroscopy was applied to the water surface for measuring the imaginary part of second-order nonlinear susceptibility (Im χ((2))) spectrum in the bend frequency region for the first time. The observed Im χ((2)) spectrum shows an overall positive band around 1650 cm(-1), contradicting former theoretical predictions. We further found that the Im χ((2)) spectrum of NaI aqueous solution exhibits an even larger positive band, which is apparently contrary to the flip-flop orientation of surface water. These unexpected observations are elucidated by calculating quadrupole contributions beyond the conventional dipole approximation. It is indicated that the Im χ((2)) spectrum in the bend region has a large quadrupole contribution from the bulk water.

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Human α‐tocopherol transfer protein: Gene structure and mutations in familial vitamin E deficiency

Hentati

Deng

Hung

et al. 1996

Annals of Neurology

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Familial vitamin E deficiency (AVED) causes ataxia and peripheral neuropathy that resembles Friedreich's ataxia. AVED is thought to be caused by a defect in the transport of vitamin E in liver cells, which is the probable function of alpha-tocopherol transfer protein (alphaTTP). We have cloned the cDNA and several genomic phage clones covering the entire human alphaTTP gene and determined the junctions between the five exons and four introns that composed the gene for human alphaTTP. Three mutations in three unrelated North American families with AVED were identified. Two mutations, 485delT and 513insTT, cause a frame shift and a premature stop codon and the third mutation 574G-->A would substitute Arg192 to His in alphaTTP. The 2 patients with a severe form of AVED were homozygous with 485delT and 513insTT, respectively, while the patient with a mild form of the disease was compound heterozygous with 513insTT and 574G-->A. These findings have identified the underlying genetic defect in AVED and have confirmed the role of alphaTTP in AVED.

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On the intermolecular vibrational coupling, hydrogen bonding, and librational freedom of water in the hydration shell of mono- and bivalent anions

Ahmed

Namboodiri

Singh

et al. 2014

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The hydration energy of an ion largely resides within the first few layers of water molecules in its hydration shell. Hence, it is important to understand the transformation of water properties, such as hydrogen-bonding, intermolecular vibrational coupling, and librational freedom in the hydration shell of ions. We investigated these properties in the hydration shell of mono- (Cl(-) and I(-)) and bivalent (SO4(2-) and CO3(2-)) anions by using Raman multivariate curve resolution (Raman-MCR) spectroscopy in the OH stretch, HOH bend, and [bend+librational] combination bands of water. Raman-MCR of aqueous Na-salt (NaCl, NaI, Na2SO4, and Na2CO3) solutions provides ion-correlated spectra (IC-spectrum) which predominantly bear the vibrational characteristics of water in the hydration shell of respective anions. Comparison of these IC-spectra with the Raman spectrum of bulk water in different spectral regions reveals that the water is vibrationally decoupled with its neighbors in the hydration shell. Hydrogen-bond strength and librational freedom also vary with the nature of anion: hydrogen-bond strength, for example, decreases as CO3(2-) > SO4(2-) > bulk water ≈ Cl(-) > I(-); and the librational freedom increases as CO3(2-) ≈ SO4(2-) < bulk water < Cl(-) < I(-). It is believed that these structural perturbations influence the dynamics of coherent energy transfer and librational reorientation of water in the hydration shell of anions.

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How Osmolyte and Denaturant Affect Water at the Air–Water Interface and in Bulk: A Heterodyne-Detected Vibrational Sum Frequency Generation (HD-VSFG) and Hydration Shell Spectroscopic Study

et al. 2016

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Preferential orientation and expulsion/accumulation of trimethylamine N-oxide (TMAO; a protecting osmolyte) and tert-butyl alcohol (TBA; a denaturant) have been investigated at the hydrophobic air–water interface by phase-sensitive heterodyne-detected vibrational sum frequency generation (HD-VSFG) spectroscopy. The imaginary χ(2) spectrum (Imχ(2); χ(2) is the second order electric susceptibility), which is directly obtainable from the HD-VSFG measurement, provides the accurate absorption characteristics of interfacial molecules, and the sign of Imχ(2) reveals the net orientation of these molecules at the interface. For the aqueous TMAO and TBA solutions, the Imχ(2) spectra in the CH-stretch region show a negative sign, which demonstrates that both TMAO and TBA orient in the same manner at the air–water interface, by pointing their methyls away from the aqueous phase (“methyl-up” orientation). Nevertheless, they affect the interfacial water quite differently: TMAO increases the H-bond strength and preferential H-down orientation of interfacial water, while the dangling OH remains almost unperturbed. TBA, on the other hand, does not affect the H-bond strength and preferential orientation of interfacial water, but reduces the propensity of the dangling OH at the air–water interface. The preferential orientation of TMAO and TBA and their distinct effect on the interfacial water have been correlated with their hydration characteristics in bulk water by retrieving the vibrational spectrum of water in their respective hydration shells, using Raman multivariate curve resolution (Raman-MCR) spectroscopy. The MCR-retrieved hydration water spectra clearly show that the water around TBA has strong water–water interaction (hydrophobic hydration) and that around TMAO has a hydrophobic hydration around the N-methyl ((CH3)3N+−) group and a hydrophilic hydration around the N-oxide group (strong H-bonding of water with the N-oxide group). The different hydration characteristic of the N-methyl and N-oxide groups orients the TMAO molecules as “methyl-up” at the air–water interface. Moreover, the strong hydration of the N-oxide group leads to a depletion of TMAO from the hydrophobic water surface, such that the preferentially oriented TMAO molecules are located beneath the topmost water layer at the air–water interface. As a result, the topmost water molecules are largely unaware of the presence of TMAO at the interface, even at very high bulk concentration of TMAO (5.0 mol dm–3). In the case of TBA, the hydrophobic hydration leads to an accumulation of TBA at the water surface, mainly affecting the topmost water molecules.

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Mohammed Ahmed

How Ions Affect the Structure of Water: A Combined Raman Spectroscopy and Multivariate Curve Resolution Study

Bend Vibration of Surface Water Investigated by Heterodyne-Detected Sum Frequency Generation and Theoretical Study: Dominant Role of Quadrupole

Human α‐tocopherol transfer protein: Gene structure and mutations in familial vitamin E deficiency

On the intermolecular vibrational coupling, hydrogen bonding, and librational freedom of water in the hydration shell of mono- and bivalent anions

How Osmolyte and Denaturant Affect Water at the Air–Water Interface and in Bulk: A Heterodyne-Detected Vibrational Sum Frequency Generation (HD-VSFG) and Hydration Shell Spectroscopic Study

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