Comparative Study of the Thermal Conductivity of Solid Biomass Fuels.

The thermal conductivity of solid biomass fuels is useful information in the investigation of biomass combustion behavior and the development of modeling especially in the context of large scale power generation. There are little published data on the thermal conductivity of certain types of biomass such as wheat straw, miscanthus, and torrefied woods. Much published data on wood is in the context of bulk materials. A method for determining the thermal conductivities of small particles of biomass fuels has been developed using a custom built test apparatus. Fourteen different samples of various solid biomass fuel were processed to form a homogenized pellet for analysis. The thermal conductivities of the pelletized materials were determined and compared against each other and to existing data.

Neutron scattering studies of the hydration structure of Li+.

New results derived from the experimental method of neutron diffraction and isotopic substitution (NDIS) are presented for the hydration structure of the lithium cation (Li(+)) in aqueous solutions of lithium chloride in heavy water (D2O) at concentrations of 6, 3, and 1 m and at 1.5 m lithium sulfate. By introducing new and more-accurate data reduction procedures than in our earlier studies (I. Howell and G. W. Neilson, J. Phys: Condens. Matter, 1996, 8, 4455-4463), we find, in the first hydration shell of Li(+), ∼4.3(2) water molecules at 6 m, 4.9(3) at 3 m, 4.8(3) at 1 m in the LiCl solutions, and 5.0(3) water molecules in the case of Li2SO4 solution. The general form of the first hydration shell is similar in all four solutions, with the correlations for Li-O and Li-D sited at 1.96 (0.02) Å and 2.58 (0.02) Å, respectively. The results resemble those presented in 1996, in terms of ion-water distances and local coordination, but the hydration number is significantly lower for the case at 1 m than the 6.5 (1.0) given at that time. Thus, experimental and theoretical results now agree that lithium is hydrated by a small number of water molecules (4-5) in the nearest coordination shell.

Molecular dynamics studies of the conformation of sorbitol.

Molecular dynamics simulations of a 3 molal aqueous solution of D-sorbitol (also called D-glucitol) have been performed at 300 K, as well as at two elevated temperatures to promote conformational transitions. In principle, sorbitol is more flexible than glucose since it does not contain a constraining ring. However, a conformational analysis revealed that the sorbitol chain remains extended in solution, in contrast to the bent conformation found experimentally in the crystalline form. While there are 243 staggered conformations of the backbone possible for this open-chain polyol, only a very limited number were found to be stable in the simulations. Although many conformers were briefly sampled, only eight were significantly populated in the simulation. The carbon backbones of all but two of these eight conformers were completely extended, unlike the bent crystal conformation. These extended conformers were stabilized by a quite persistent intramolecular hydrogen bond between the hydroxyl groups of carbon C-2 and C-4. The conformational populations were found to be in good agreement with the limited available NMR data except for the C-2-C-3 torsion (spanned by the O-2-O-4 hydrogen bond), where the NMR data support a more bent structure.

"Tetrahedrality" and the relationship between collective structure and radial distribution functions in liquid water.

Molecular dynamics simulations of pure liquid water under ambient conditions using four common empirical water models have been analyzed to determine how well the oxygen-oxygen radial distribution function, g(OO)(r), used as the sole criterion of congruence with experiment, captures variations in the actual anisotropic collective structuring for these models. The largest systematic deviations from tetrahedrality were found to be due to deformations of the angle between the two closet hydrogen bond donor neighbors, but for intrinsic geometric reasons, these were found to contribute less to g(OO)(r) than deformations of the angles between one hydrogen bond donor neighbor and one hydrogen bond acceptor neighbor. Relying exclusively on a qualitative characterization of the second peak in g(OO)(r) seems to overemphasize the differences between the structuring in some of these models.

X-ray and neutron scattering studies of the hydration structure of alkali ions in concentrated aqueous solutions.

The presence of ions in water provides a rich and varied environment in which many natural processes occur with important consequences in biology, geology and chemistry. This article will focus on the structural properties of ions in water and it will be shown how the 'difference' methods of neutron diffraction with isotopic substitution (NDIS) and anomalous X-ray diffraction (AXD) can be used to obtain direct information regarding the radial pair distribution functions of many cations and anions in solution. This information can subsequently be used to calculate coordination numbers and to determine ion-water conformation in great detail. As well as enabling comparisons to be made amongst ions in particular groups in the periodic table, such information can also be contrasted with results provided by molecular dynamics (MD) simulation techniques. To illustrate the power of these 'difference' methods, reference will be made to the alkali group of ions, all of which have been successfully investigated by the above methods, with the exception of the radioactive element francium. Additional comments will be made on how NDIS measurements are currently being combined with MD simulations to determine the structure around complex ions and molecules, many of which are common in biological systems.

Nanometer-scale ion aggregates in aqueous electrolyte solutions: guanidinium carbonate.

Neutron diffraction with isotopic substitution (NDIS) experiments and molecular dynamics (MD) simulations have been used to characterize the structure of aqueous guanidinium carbonate (Gdm2CO3) solutions. The MD simulations found very strong hetero-ion pairing in Gdm2CO3 solution and were used to determine the best structural experiment to demonstrate this ion pairing. The NDIS experiments confirm the most significant feature of the MD simulation, which is the existence of strong hetero-ion pairing between the Gdm+ and CO3(2-) ions. The neutron structural data also support the most interesting feature of the MD simulation, that the hetero-ion pairing is sufficiently strong as to lead to nanometer-scale aggregation of the ions. The presence of such clustering on the nanometer length scale was then confirmed using small-angle neutron scattering experiments. Taken together, the experiment and simulation suggest a molecular-level explanation for the contrasting denaturant properties of guanidinium salts in solution.

Neutron diffraction studies of electrolytes in null water: a direct determination of the first hydration zone of ions.

A method of neutron diffraction is described which enables the first hydration zone of small cations to be investigated at atomic resolution. It is shown that the cation structures of aqueous electrolyte solutions dissolved in a 'null' mixture of water (H(2)O) and heavy water (D(2)O), can be calculated directly from the neutron scattering patterns. The hitherto unresolved structure around Na(+) is used to illustrate the power of this method, the accuracy of which is discussed formally with reference to standard nickel chloride solutions. Possible applications to a variety of other systems and at different thermodynamic states are proposed.

Nanometer-scale ion aggregates in aqueous electrolyte solutions: guanidinium sulfate and guanidinium thiocyanate.

Neutron diffraction experiments and molecular dynamics simulations are used to study the structure of aqueous solutions of two electrolytes: guanidinium sulfate (a mild protein conformation stabilizer) and guanidinium thiocyanate (a powerful denaturant). The MD simulations find the unexpected result that in the Gdm2SO4 solution the ions aggregated into mesoscopic (nanometer-scale) clusters, while no such aggregation is found in the GdmSCN solution. The neutron diffraction studies, the most direct experimental probe of solution structure, provide corroborating evidence that the predicted very strong ion pairing does occur in solutions of 1.5 m Gdm2SO4 but not in 3 m solutions of GdmSCN. A mechanism is proposed as to how this mesoscopic solution structure affects solution denaturant properties and suggests an explanation for the Hofmeister ordering of these solutions in terms of this ion pairing and the ability of sulfate to reverse the denaturant power of guanidinium.

Structure of aqueous glucose solutions as determined by neutron diffraction with isotopic substitution experiments and molecular dynamics calculations.

Neutron diffraction with isotopic substitution (NDIS) experiments and molecular dynamics (MD) simulations have been used to examine the structuring of solvent around d-glucose in aqueous solution. As expected, no significant tendency for glucose molecules to aggregate was found in either the experiments or the simulation. To the extent that solute pairing does occur as the result of the high concentration, it was found to take place through hydroxyl-hydroxyl hydrogen bonds, in competition with water molecules for the same hydrogen-bonding sites. A detailed analysis of the hydrogen-bonding patterns occurring in the simulations found that the sugar hydroxyl groups are more efficient hydrogen bond donors than acceptors. From the comparison of the MD and NDIS data, it was found that while the modeling generally does a satisfactory job in reproducing the experimental data the force fields may produce sugar rings that are too rigid and thus may require future revisions.

The hydration structure of guanidinium and thiocyanate ions: implications for protein stability in aqueous solution.

Neutron diffraction experiments were carried out on aqueous solutions containing either guanidinium or thiocyanate ions. The first-order difference method of neutron diffraction and isotopic substitution was applied, and the hydration structures of two of nature's strongest denaturant ions were determined. Each ion is shown to interact weakly with water: Guanidinium has no recognizable hydration shell and is one of the most weakly hydrated cations yet characterized. Hydration of thiocyanate is characterized by a low coordination number involving around one hydrogen-bonded water molecule and approximately two water molecules weakly interacting through "hydration bonds." The weak hydration of these denaturant ions strongly supports suggestions that a major contribution to the denaturant effect is the preferential interaction of the denaturant with the protein surface. By contrast, solute species such as many sugars and related polyols that stabilize proteins are strongly hydrated and are thus preferentially retained in the bulk solvent and excluded from the protein surface.

[Membrane biophysical interaction of amlodipine and antioxidant properties]. / Interactions biophysiques membranaires de l'amlodipine et propriétés antioxydantes.

OBJECTIVE: To assess the potential benefits of the antioxidant activity of certain pharmacological agents that may be beneficial in the treatment of cardiovascular disease, including coronary heart disease and heart failure, by reducing irreversible cell injury due to oxyradical damage. METHODS: The antioxidant activities of representative calcium antagonists were examined and correlated with the molecular membrane interactions of the compounds, as measured by radioligand binding assays and high resolution differential scanning calorimetry. RESULTS: The results of these experiments show a direct relationship between the antioxidant activities of the calcium antagonists and their affinity for the membrane lipid bilayer, as well as their ability to modulate membrane thermodynamic properties (amlodipine > verapamil >> diltiazem). The charged 1,4-dihydropyridine calcium antagonist amlodipine had the highest affinity for the membrane bilayer (Kp10(4)) and produced the largest changes in membrane thermodynamic properties, including a reduction in the thermal phase transition temperature (-11%), enthalpy (-14%) and cooperative unit size (-59%), relative to control phosphatidylcholine liposomes. CONCLUSIONS: These findings indicate that lipophilic calcium antagonists inhibit lipid peroxidation in cellular membranes as a result of modulating physicochemical properties of the membrane lipid bilayer, independently of calcium channel inhibition. The antioxidant activity of highly lipophilic calcium antagonists, such as amlodipine, may contribute to new cytoprotective mechanisms of action in cardiovascular disease.

Antioxidant properties of calcium antagonists related to membrane biophysical interactions.

The antioxidant activities of representative calcium antagonists, including amlodipine, verapamil, and diltiazem, were measured in hepatic microsomal membranes by the Fe-catalyzed, hydroxyl radical-producing system (dihydroxyfumarate + Fe3+) and assessed by malondialdehyde (MDA) formation. Despite the absence of L-type calcium channels in this membrane preparation, the calcium antagonists showed dose-dependent antioxidant activity. The biophysical mechanism for calcium-antagonist antioxidant activity was evaluated using radioligand binding assays, high-resolution differential scanning calorimetry, and small-angle x-ray diffraction approaches. These analyses demonstrated that calcium-antagonist antioxidant potency correlated directly with the compounds' relative affinity for the membrane lipid bilayer and ability to modulate membrane thermodynamic properties (amlodipine >> verapamil > diltiazem). The charged 1,4-dihydropyridine calcium antagonist, amlodipine, had the highest affinity for the membrane lipid bilayer (Kp>10(4)) and produced the largest changes in membrane thermodynamic properties, including a reduction in thermal phase transition temperature (-11%), enthalpy (-14%), and cooperative unit size (-59%), relative to control phosphatidylcholine liposomes. Electron density profiles generated from x-ray diffraction data demonstrated that amlodipine effected a broad and dose-dependent increase in molecular volume associated with the membrane hydrocarbon core. These data indicate that lipophilic calcium antagonists inhibit lipid peroxidation in cellular membranes as a result of modulating physicochemical properties of the membrane lipid bilayer, independently of calcium channel inhibition. Amlodipine had the most potent antioxidant activity as a result of distinct biophysical interactions with the membrane lipid bilayer. The nonreceptor-mediated antioxidant activity of calcium antagonists may contribute to cytoprotective mechanisms of action in cardiovascular diseases.

Distribution and fluidizing action of soluble and aggregated amyloid beta-peptide in rat synaptic plasma membranes.

The effects of soluble and aggregated amyloid beta-peptide (Abeta) on cortical synaptic plasma membrane (SPM) structure were examined using small angle x-ray diffraction and fluorescence spectroscopy approaches. Electron density profiles generated from the x-ray diffraction data demonstrated that soluble and aggregated Abeta1-40 peptides associated with distinct regions of the SPM. The width of the SPM samples, including surface hydration, was 84 A at 10 degrees C. Following addition of soluble Abeta1-40, there was a broad increase in electron density in the SPM hydrocarbon core +/-0-15 A from the membrane center, and a reduction in hydrocarbon core width by 6 A. By contrast, aggregated Abeta1-40 contributed electron density to the phospholipid headgroup/hydrated surface of the SPM +/-24-37 A from the membrane center, concomitant with an increase in molecular volume in the hydrocarbon core. The SPM interactions observed for Abeta1-40 were reproduced in a brain lipid membrane system. In contrast to Abeta1-40, aggregated Abeta1-42 intercalated into the lipid bilayer hydrocarbon core +/-0-12 A from the membrane center. Fluorescence experiments showed that both soluble and aggregated Abeta1-40 significantly increased SPM bulk and protein annular fluidity. Physico-chemical interactions of Abeta with the neuronal membrane may contribute to mechanisms of neurotoxicity, independent of specific receptor binding.

Membrane antioxidant effects of the charged dihydropyridine calcium antagonist amlodipine.

The effect of the highly lipophilic calcium channel antagonist (CCA) amlodipine on membrane oxyradical damage was examined and compared to that of other CCA analogs and a sulfhydryl-containing ACE inhibitor in isolated membrane vesicles enriched with polyunsaturated fatty acids (PUFA). Under physiological-like conditions, the dihydropyridine CCA amlodipine significantly (P<0.001) inhibited lipid peroxide formation (>10(2) microM) at concentrations as low as 10.0 nM. Under identical conditions, inhibition of lipid peroxide formation was not observed with representative CCA analogs (felodipine, verapamil, diltiazem) or the ACE inhibitor, captopril, at concentrations as high as 1.0 microM. The potent antioxidant activity of amlodipine is attributed to distinct membrane physico-chemical interactions. High-resolution differential scanning calorimetry showed that amlodipine effected marked changes in membrane thermodynamic properties as compared to other CCA analogs, including a marked reduction in the thermal phase transition temperature (-2.6 degrees C), enthalpy (-4.8 J/g) and cooperative unit size (-59%), relative to control samples. These findings indicate that the chemical structure of amlodipine contributes to distinct membrane biophysical interactions that lead to potent lipid antioxidant effects, independent of calcium channel modulation. These findings provide insights into potential new mechanisms of action for the charged CCA amlodipine.

Inhibition of excessive neuronal apoptosis by the calcium antagonist amlodipine and antioxidants in cerebellar granule cells.

Neuronal cell death as a result of apoptosis is associated with cerebrovascular stroke and various neurodegenerative disorders. Pharmacological agents that maintain normal intracellular Ca2+ levels and inhibit cellular oxidative stress may be effective in blocking abnormal neuronal apoptosis. In this study, a spontaneous (also referred to as age-induced) model of apoptosis consisting of rat cerebellar granule cells was used to evaluate the antiapoptotic activities of voltage-sensitive Ca2+ channel blockers and various antioxidants. The results of these experiments demonstrated that the charged, dihydropyridine Ca2+ channel blocker amlodipine had very potent neuroprotective activity in this system, compared with antioxidants and neutral Ca2+ channel blockers (nifedipine and nimodipine). Within its effective pharmacological range (10-100 nM), amlodipine attenuated intracellular neuronal Ca2+ increases elicited by KCl depolarization but did not affect Ca2+ changes triggered by N-methyl-D-aspartate receptor activation. Amlodipine also inhibited free radical-induced damage to lipid constituents of the membrane in a dose-dependent manner, independent of Ca2+ channel modulation. In parallel experiments, spontaneous neuronal apoptosis was inhibited in dose- and time-dependent manners by antioxidants (U-78439G, alpha-tocopherol, and melatonin), nitric oxide synthase inhibitors (N-nitro-L-arginine and N-nitro-D-arginine), and a nitric oxide chelator (hemoglobin) in the micromolar range. These results suggest that spontaneous neuronal apoptosis is associated with excessive Ca2+ influx, leading to further intracellular Ca2+ increases and the generation of reactive oxygen species. Agents such as amlodipine that block voltage-sensitive Ca2+ channels and inhibit cellular oxidative stress may be effective in the treatment of cerebrovascular stroke and neurodegenerative diseases associated with excessive apoptosis.

A new cryptand: synthesis and complexation with paraquat.

[formula: see text] Inspired by folded, nonpseudorotaxane complexes of bis(m-phenylene)-32-crown-10 systems, we synthesized a new bicyclic crown ether containing two 1,3,5-phenylene units linked by three tetra(ethyleneoxy) units. The new cryptand forms a "pseudorotaxane-like" inclusion complex with N,N'-dimethyl-4,4'-bipyridinium bis(hexafluorophosphate) with association constant Ka = 6.1 x 10(4) M-1, 100-fold greater than that of an analogous simple crown ether.

Critique of a biologic mechanism linking calcium antagonists to increased risk for cardiovascular events in diabetes.

Calcium antagonists represent a chemically and pharmacologically diverse group of agents that function by modulating the transmembrane influx of Ca2+ into contractile cells. These compounds, widely used for the treatment of hypertension and angina, bind in a highly specific and reversible fashion to voltage-sensitive Ca2+ channels in vascular smooth muscle cells. A recent study raised concerns about the safety of certain calcium antagonists for treatment of hypertension in diabetic patients. The safety issue has not been resolved and is the subject of other articles in this supplement. However, a biologic mechanism has been proposed to rationalize the potentially deleterious effects of calcium antagonists in this group of patients. This mechanism is based on an assumption that the biochemical composition of cellular membranes in patients with diabetes is fundamentally different, leading to an abnormal increase in the membrane concentration of calcium antagonists and, hence, adverse pharmacologic effects. In support of this model, original research on the lipid composition of membranes from patients with diabetes was cited, along with our own published findings, showing that accumulation of calcium antagonists in membranes is influenced by the molar ratio of cholesterol to phospholipid (C:P). A careful review of these and other related scientific reports, however, yields no evidence for reproducible changes in the membrane C:P molar ratio of diabetic patients that would lead to adverse pharmacologic effects of calcium antagonists.

Antioxidant and cytoprotective activities of the calcium channel blocker mibefradil.

Mibefradil is a new calcium channel antagonist (CCA) that acts on both L- and T-type channels, with 10-fold selectivity for T-type channels. In this study, the structural interactions of mibefradil with cardiac membrane lipid bilayers were directly examined with small-angle x-ray diffraction approaches and correlated with lipid peroxidation and bovine aortic endothelial cell viability assays. Electron density profiles (A vs electrons/A3) calculated from the diffraction data (37 degrees C) demonstrated that mibefradil had an equilibrium location in the hydrocarbon core/headgroup region of the cardiac bilayer, 12-27 A from the center of the membrane. Mibefradil also effected a pronounced reduction in electron density 0-11 A from the center of the cardiac membrane concomitant with a 7.5% (3 A) decrease in membrane hydrocarbon core thickness; these changes in membrane structure were not observed with the phenylalkylamine verapamil, a CCA with some structural similarity to mibefradil. As a result of membrane physico-chemical interactions, mibefradil inhibited (10-500 nM) lipid peroxide formation in liposomes enriched in polyunsaturated fatty acids. In aortic endothelial cells, mibefradil also inhibited loss of cell viability (IC50 of 2 microM) following acute oxy-radical generation by dihydroxyfumarate and Fe-ADP; the order of potency was mibefradil > verapamil > diltiazem. These findings indicate that the chemical structure of mibefradil contributes to biophysical interactions with the cell membrane that underlie antioxidant and cytoprotective activities in models of oxidative stress.

Physical effects of cholesterol on arterial smooth muscle membranes: evidence of immiscible cholesterol domains and alterations in bilayer width during atherogenesis.

Small angle X-ray diffraction was used to examine arterial smooth muscle cell (SMC) plasma membranes isolated from control and cholesterol-fed (2%) atherosclerotic rabbits. A microsomal membrane enriched with plasma membrane obtained from animals fed cholesterol for up to 13 weeks showed a progressive elevation in the membrane unesterified (free) cholesterol:phospholipid (C/PL) mole ratio. Beyond 9 weeks of cholesterol feeding, X-ray diffraction patterns demonstrated a lateral immiscible cholesterol domain at 37 degrees C with a unit cell periodicity of 34 A coexisting within the liquid crystalline lipid bilayer. On warming, the immiscible cholesterol domain disappeared, and on cooling it reappeared, indicating that the immiscible cholesterol domain was fully reversible. These effects were reproduced in a model C/PL binary lipid system. In rabbits fed cholesterol for less than 9 weeks, lesser increases in membrane C/PL mole ratio were observed. X-ray diffraction analysis demonstrated an increase in membrane bilayer width that correlated with the C/PL mole ratio. This effect was also reproduced in a C/PL binary lipid system. Taken together, these findings demonstrate that in vivo, feeding of cholesterol causes cholesterol-phospholipid interactions in the membrane bilayer that alter bilayer structure and organization. This interaction results in an increase in bilayer width peaking at a saturating membrane cholesterol concentration, beyond which lateral phase separation occurs resulting in the formation of separate cholesterol bilayer domains. These alterations in structure and organization in SMC plasma membranes may have significance in phenotypic modulation or aortic SMC during early atherogenesis.