Solubility of nickel oxide particles in various solutions and rat alveolar macrophages

The solubility of five types of commercial nickel oxide particles was determined in different types of solutions, including distilled water, physiological saline, buffered saline, and tissue-culture medium, in order to estimate their solubility in the human respiratory tract. In addition, we examined the solubility of the two types of particles that were the most and least soluble particles of the above five types of nickel oxide, in rat alveolar macrophages cultured in vitro. The solubility of the nickel oxide particles in these solutions varied remarkably with their types, suggesting that, even though they are called as “nickel oxide,” their solubilities are different among the manufacturer and the product lot. Their solubilities were also influenced by the types of solution and the existence of carbon dioxide in the atmosphere. The solubility of nickel oxide particles in the alveolar macrophages was significantly larger than that observed in the culture medium without macrophages, but smaller than that observed in the distilled water. These results suggest that the actual solubility of nickel oxide particles in the respiratory tract may be difficult to estimate by the conventional solubility analysis method using distilled water, and that the enhancement of particle dissolution by the alveolar macrophages and the depression of particle solubility by the coexisting salt and carbon dioxide should be taken into consideration for the accurate estimation.     

Direct concentration measurements of the unfrozen portion of solutions under freezing

Phase diagrams of solutions consisting of cryoprotective agents (CPA) are very useful in cryobiology research. Those diagrams depict the points of solution concentrations at corresponding temperatures: one of essential inputs that can be utilized to compute the volume response of cell under freezing process. However, generating such plots is costly and time-consuming. A direct method is proposed in this study to determine the solution concentration of unfrozen parts at multiple sub-zero temperatures. Measurements of binary solutions, composed of water and sodium chloride, were performed and compared with published data. Ternary solutions, consisting of water, sodium chloride and dimethyl sulfoxide, were also measured. The uniqueness and advantage achieved through the usage of this method are demonstrated when phase diagrams of complex cryopreservation solutions (CryoStor solutions including CryoStor Base and CryoStor 10) are generated. The temperature range where the method is utilized is either limited by the osmometry (0-3200 mmol/kg) or by the availability of liquid samples at sub-freezing temperatures. Modified methods will be required to address the limitation of osmolality measurements and the availability of sub-freezing liquid samples at lower temperatures.     

Faster gastric emptying for glucose-polymer and fructose solutions than for glucose in humans

This study examined the rates of gastric emptying for water and 13 different carbohydrate-containing solutions in seven subjects, using conventional gastric intubation techniques. The rates of gastric emptying for water and a 10% glucose-polymer solution were also measured during 90 min of treadmill running at 75% of each subject's maximum oxygen consumption (VO2max). At rest, 15% glucose-polymer (P) and fructose (F) solutions emptied more rapidly from the stomach and provided a faster rate of carbohydrate delivery than did a 15% glucose (G) solution (p less than 0.05). The G solutions showed a constant energy delivery rate of 3.3 kcal.min-1; energy delivery from P and F solutions rose with increasing solution concentrations. The osmolality of the gastric aspirate predicted the rate of gastric emptying for all solutions (p less than 0.05) but overestimated rates of emptying for 10% and 15% P solutions and underestimated emptying rates for 10% and 15% F solutions. Exercise at 75% VO2max decreased the rate of gastric emptying of water but not of 10% P solutions. Thus the different rates of gastric emptying for different carbohydrate-containing solutions were not entirely explained by differences in osmolality. Furthermore, exercise may have different effects on the gastric emptying rates of water and carbohydrate solutions.     

Calcium-induced lipid phase separations and interactions of phosphatidylcholine/anionic phospholipid vesicles. Fluorescence studies using carbazole-labeled and brominated phospholipids

A novel method that uses a carbazole-labeled fluorescent phosphatidylcholine, which partitions preferentially into liquid-crystalline lipid domains, to monitor the kinetics and the extents of thermotropic and ionotropic lateral phase separations in vesicles combining brominated and nonbrominated phosphatidylcholines (PCs), phosphatidic acids (PAs), and phosphatidylserines (PSs) is described. The calcium-induced segregation of several nonbrominated PA species in liquid-crystalline brominated PC bilayers behaves as a well-defined lateral phase separation; the residual solubility of the PA component in the PC-rich phase in the presence of calcium can vary severalfold depending on the PA acyl chain composition. PC/PS mixtures show a pronounced tendency to form metastable solutions in the presence of calcium, particularly when they contain less than equimolar proportions of PS. This metastability is not readily relaxed by repeated freeze-thawing of vesicles in the presence of calcium, by avidin-mediated contacts between PC/PS vesicles containing biotinylated lipids, or by calcium-induced lateral segregation of PA in the same vesicles. Different PS species exhibit different apparent residual solubilities in liquid-crystalline PC bilayers, ranging from less than 10 mol % for dimyristoyl-PS to ca. 45 mol% for dioleoyl-PS, after prolonged incubations of PC/PS multilamellar vesicles with excess calcium. Results are presented, obtained by using the above lipid-segregation assay and parallel assays of intervesicle lipid mixing, that raise questions concerning the relevance of the equilibrium behavior of calcium-treated PS/PC mixtures to the relatively rapid interactions (fusion and lipid mixing) of PC/PS vesicles that follow initial exposure to calcium.     

A field lab method to determine urine concentration in small mammals

1. The concentrations of 136 urine samples from four species of small mammals were compared using osmometry, refractometry and a colorimetric test for urea concentration. 2. To obtain a wide range of concentrations (430-3950 mOsm/kg), urine samples were collected under normal and dehydration conditions. 3. Regression analyses of paired values indicate that measurements of total solids concentration (refractometric method) permit evaluations of urine osmolality and estimations of the concentration of urea with a high degree of confidence.     

Unexpected differences between D- and L- tyrosine lead to chiral enhancement in racemic mixtures.

We report here an unexpected difference in the solubilities of D- and L-tyrosine in water, which could be discerned by their rate of crystallization and the resulting concentrations of their saturated solutions. A supersaturated solution of 10 mM L-tyrosine at 20 degrees C crystallized much more slowly than that of D-tyrosine under the same conditions, and the saturated solution of L-tyrosine was more concentrated than that of D-tyrosine. Supersaturated solutions of 10 mM DL-tyrosine in water formed precipitates of predominantly D-tyrosine and DL-tyrosine, resulting in an excess of L-tyrosine in the saturated solution. The experimental setups were monitored independently by UV-absorption, radioactivity tracing, optical rotation and X-ray diffraction. The process of nucleation and crystallization of D- and L-tyrosine is characterized by an exceptionally high cooperativity. It is possible that minute energy differences between D- and L-tyrosine, originating from parity violation or other non-conservative chiral discriminatory rules, could account for the observations. The physical process that initiated chiral selection in biological systems remains a challenging problem in understanding the origin of life, and it is possible that chiral compounds were concentrated from supersaturated racemic mixtures by preferential crystallization.     

Unexpected Differences between D- and L- Tyrosine Lead to Chiral Enhancement in Racemic Mixtures Dedicated to the memory of Prof. Shneior Lifson – A great liberal thinker.

We report here an unexpected difference in the solubilities of D- and L-tyrosine in water, which could be discerned by their rate of crystallization and the resulting concentrations of their saturated solutions. A supersaturated solution of 10 mM L-tyrosine at 20 °C crystallized much more slowly than that of D-tyrosine under the same conditions, and the saturated solution of L-tyrosine was more concentrated than that of D-tyrosine. Supersaturated solutions of 10 mM DL-tyrosine in water formed precipitates of predominantly D-tyrosine and DL-tyrosine, resulting in an excess of L-tyrosine in the saturated solution. The experimental setups were monitored independently by UV-absorption, radioactivity tracing, optical rotation and X-ray diffraction. The process of nucleation and crystallization of D- and L-tyrosine is characterized by an exceptionally high cooperativity. It is possible that minute energy differences between D- and L-tyrosine, originating from parity violation or other non-conservative chiral discriminatory rules, could account for the observations. The physical process that initiated chiral selection in biological systems remains a challenging problem in understanding the origin of life, and it is possible that chiral compounds were concentrated from supersaturated racemic mixtures by preferential crystallization.     

Lymph osmolality and rehydration from NaCl solutions by toads, Bufo marinus

Toads, Bufo marinus, allowed to maintain an ad libitum state of hydration were dehydrated by 10 15% of their standard weight and allowed to rehydrate from either deionized water or from 10 or 50 mmol l(-1) NaCl solutions. Toads rehydrating from the dilute salt solutions recovered a larger fraction of their standard weight than did toads rehydrating from deionized water despite there being a reduced osmotic gradient. Amiloride did not reduce water gain from these solutions. Water uptake from 100 mmol l(-1) sucrose and 50 mmol l(-1) Na gluconate was reduced relative to deionized water by a fraction predicted from the osmotic gradient. Thus, the presence of both Na+ and Cl- are required for the augmentation of water gain from dilute salt solutions. Toads allowed to rehydrate from 120 mmol l(-1) NaCl for 180 min recovered nearly as much water as toads rehydrating from deionized water for 120 min and the lymph osmolality was not reduced relative to the dehydrated condition. The recovery of water from the salt solution was greater than that predicted from the reduced osmotic gradient and amiloride partially inhibited the rehydration from 120 mmol l(-1) NaCl. Solute coupled water transport can therefore be demonstrated in living animals but only from a NaCl solution that is nearly isoosmotic with the lymph. The mechanism for enhanced water gain from dilute salt solutions remains unresolved.     

Application of osmometric methods to the study of lipids, lipoproteins, and apolipoproteins

Membrane and vapor pressure osmometry are two colligative methods that can be useful in lipid research. The former method can be used to study proteins or other macromolecules whose molecular weight lies between 20,000 to 1,000,000. Vapor pressure osmometry is useful with smaller molecules having a molecular weight of 10,000 or less. These techniques can be used in aqueous or nonaqueous solutions. They are rapid, precise, nondestructive, and require relatively small amounts of material. These techniques provide information about the state of aggregation and also about interactions of lipids, lipoproteins, and apolipoproteins in solution. We will show how membrane osmometry can be used to study solutions of lipoproteins and apolipoproteins. The application of vapor pressure osmometry to the study of biologically important lipids such as cholesterol, cholesteryl esters, and bile salts is shown.     

Solid–Liquid Equilibrium of Maltitol Aqueous Solutions—Implications on the Crystallization Behavior and Process

The solubility of maltitol in pure water and industrial syrup was measured in a temperature range from 10 to 90 °C. Maltitol is highly soluble in water, and this yields high viscosity values for the saturated aqueous solutions at different temperatures. In addition, solubility of maltitol in ethanol/water mixtures was followed at 30, 35, 45, and 55 °C. Results show that maltitol solubility is highly dependent on water content in the solvent mixture. Moreover, it increases monotonically with temperature. The logarithm of viscosity changes linearly against the mole fraction of maltitol in the aqueous solutions up to saturation. The saturated solutions showed a Newtonian behavior in a temperature range from 20 to 90 °C. Maltitol is also characterized in supersaturated solutions by a narrow metastable zone, which slightly increases as temperature is raised. The density of aqueous solutions of maltitol was measured as a function of molality up to saturation at 20 °C, and results show that density can be correlated with concentration according to a linear relation. The obtained results were used to explain maltitol crystallization, which exhibits a high nucleation rate and a slow growth leading to small size crystals.     

Interaction of bile salt monomer and cholesterol in the aqueous phase

The purpose of the present study was to evaluate the possible interaction of bile salt monomer and cholesterol in the intermicellar aqueous phase. Cholesterol and taurocholate monomer concentrations in the intermicellar aqueous phase were determined using 0-20 mM taurocholate solutions saturated with cholesterol. Maximal solubilities of cholesterol in aqueous solutions having various concentrations of taurocholate, especially below its intermicellar monomer concentration (critical micellar concentration), were determined and compared with the intermicellar cholesterol concentration. The intermicellar monomer concentration of taurocholate was constant (6 mM) and independent of taurocholate concentrations. The cholesterol concentration in the intermicellar aqueous phase gradually increased, depending upon taurocholate concentrations, and became constant (1,3 microM) above 10 mM taurocholate. The solubility of cholesterol increased linearly with the taurocholate concentration even below the critical micellar concentration, and was 0.3 microM at 6 mM taurocholate, which was approx. 20-times higher than the aqueous solubility of cholesterol, but a fifth of the maximal intermicellar cholesterol concentration. The results indicate that the higher cholesterol concentration in the intermicellar aqueous phase compared to its aqueous solubility can be primarily ascribed to the interaction of cholesterol with bile salt monomers possibly forming bile salt-cholesterol dimers, and partly to the sustaining forces induced by numerous micelles.     

A method to probe the cytoplasmic osmolality and osmotic water and solute fluxes across the cell membrane of cyanobacteria with chlorophyll a fluorescence: Experiments with Synechococcus sp. PCC7942

We present a method with which osmotic properties of the cytoplasm of cyanobacterial cells and the osmotic permeability of plasma membranes to water and solutes can be assessed from measurements of chlorophyll a fluorescence. When the electron transport of photosystem II is inhibited, the quantum yield of chlorophyll a fluorescence in cyanobacterial cells varied between a low yield limit that was attained after acclimation to darkness (state 2) and a high yield limit that was attained after acclimation to light (state 1). It was shown recently that the difference between chlorophyll a fluorescence of light‐acclimated and of dark‐acclimated cells relates quantitatively to the internal osmolality of cyanobacteria (G. C. Papageorgiou and A. Alygizaki‐Zorba. 1997. Biochim. Biophys. Acta 1335: 1‐4). In the present work we employed rapid mixing of Synechococcus sp. PCC7942 (strain PAMCOD) suspensions with solutions of defined osmolality in order to measure cell osmolality and turgor threshold, as well as water and solute fluxes across cell membranes. Concentration upshocks with sorbitol, glycine betaine, Na⁺ and K⁺ salts caused rapid (t_1/2 < 10 ms) depression of fluorescence that was correlated to osmotic water outflow from the cells. The fluorescence remained depressed in all cases except for NaCl. With NaCl, the depression was transient and fluorescence recovered with an apparent time constant of 200 ms. The fluorescence rise correlates to inflows of NaCl and water.     

Comparative studies on the membrane actions of depressant drugs: the role of lipophilicity in inhibition of brain sodium and potassium-stimulated ATPase.

Depressant drugs are considered to exert their pharmacological effects as a result of membrane interactions determined by their physico-chemical properties. In this study, a correlation was found between lipid solubility and potency of various local anaesthetics, antihistamines, tricyclic antidepressants and phenothiazine tranquilizers as inhibitors of the Na, K-ATPase activity of a microsomal membrane fraction from bovine brain cortex. Depressant drugs such as chlorpromazine, which have the greatest lipid solubilities, were competitive inhibitors of Na activation but noncompetitive toward K activation, whereas drugs such as tetracaine with lower lipid solubilities were competitive inhibitors of K activation but noncompetitive toward Na activation. Drugs with intermediate lipid solubilities were mixed competitive-noncompetitive inhibitors of both Na and K activation. Both chlorpromazine and tetracaine competitively inhibited cation activation by a heterotropic allosteric mechanism, probably mediated through membrane conformational changes. Whereas quaternization or a decrease in the incubation pH interfered with the ability of chlorpromazine to inhibit Na activation in a competitive fashion, these changes did not affect the ability of tetracaine to compete with K activation. In addition Mn, Ca and phosphatidyl serine were very effective non-competitive antagonists of chlorpromazine inhibition of Na, K-ATPase, whereas these agents competitively antagonized tetracaine inhibition to a lesser extent. These data suggest that the more lipid soluble phenothiazines penetrate into and react in hydrophobic areas of the membrane microenvironment, resulting in a membrane perturbation which interferes with Na activation. On the other hand the less lipid soluble local anaesthetics probably act at superficial sites near the membrane surface, resulting in a different membrane perturbation which interferes with the K activation mechanism. It is suggested that lipid solubility may be a significant factor in determining selectivity in the membrane interactions of various pharmacological agents and hence differences in pharmacological activity among different classes of depressant drugs.     

Ligand binding and the gelation of sickle cell hemoglobin.

The solubility equilibrium between monomer and polymer which has been shown to exist in deoxyhemoglobin S solutions is examined in solutions partially saturated with carbon monoxide. The total solubility is found to increase monotonically with increasing fractional saturation. At low fractional saturations the increase is nearly linear, amounting roughly to an increase of 0.01 g cm^?3 in solubility for each 10% increase in fractional saturation. Linear dichroism measurements on the spontaneously aligned polymer phase are used to examine the composition of the polymer as a function of the fractional saturation of the corresponding solution phase. The dichroism experiments show that the polymer phase contains less than 5% of CO-liganded hemes even at supernatant fractional saturations in excess of 70%. The polymer selects against totally liganded hemoglobin molecules by a minimum factor of 65 and against singly liganded molecules by a factor of at least 2.5. Consequently, polymerized hemoglobin S has a ligand affinity which is significantly lower than that of monomeric hemoglobin S in the deoxy quaternary structure.The kinetics of the polymerization reaction in the presence of CO are similar to those observed in pure deoxyhemoglobin S solutions. The polymerization is preceded by a pronounced delay, the duration of which, t_d, is proportional roughly to the 30th power of the solubility. At low fractional saturations, this amounts to a tenfold increase in t_d for each 10% increase in the fractional saturation.These results show that the polymerization reaction is nearly specific for deoxyhemoglobin. Models for the dependence of the solubility and the polymer saturation on ligand partial pressure demonstrate the importance of solution phase non-ideality in determining the solubility of mixtures. The results require selection against partially liganded species which is significantly greater than is predicted by the two-state allosteric model. The data are compatible with either sequential or allosteric models in which the major polymerized component is the unliganded hemoglobin molecule.     

Regulation of motility in sperm of the red-spotted newt

The motility of sperm was examined in vivo in the vas deferens, the spermatophore, and the spermatheca of the red-spotted newt and in in vitro preparations with variations in osmolality, hydrogen ion concentration, and concentrations of specific osmolytes. Sperm were motile within the spermatophore, but little or no evidence of motility was seen in the spermatheca or the vas deferens. Approximately 25% of sperm from the vas deferens became motile when dispersed in spermatic fluid plasma, the sperm-bearing liquid of the vas deferens, indicating crowding to be a possible motion-restraining factor. Fewer than 50% were motile in several saline media isosmotic with spermatic fluid plasma, whereas more than 90% became motile in distilled water or media at osmolalities near that of pond water. Motility in isosmotic solutions persisted beyond 12 hours, but at low osmolality ceased by 6 hours. When dispersed at higher osmolalities initial motility was low but increased to isosmotic levels by 12 hours. Responses to immersion in solutions of mannitol were similar to ones observed in saline solutions of equivalent osmolality. Dispersion in hydrogen ion concentrations between pH 4 and 9 did not affect the initial motility of sperm, but after 12 hours at pH 9, pH 4 or 5 movement was inhibited. In general, these data indicate a major role for osmolality in the enforced quiescence of sperm during storage and demonstrate that the low osmolality of pond water is primarily responsible for the activation of sperm in the spermatophore of the newt.     

Influence of short-chain fatty acids and osmolality on mucin release in the rat colon

Summary The influence of short-chain fatty acids (SCFA) and osmolality on mucin release in the rat colon was studied histochemically by determining number of stained mucin-containing cells. SCFA did not significantly influence the number of cells staining for mucin. Hypertonic solutions (360 mosm/l) did not affect mucin release in the proximal colon, but stimulated mucin release in the distal colon. Solutions of lower osmolality (300 or 250 mosm/l) caused a considerable release of mucin from goblet cells as well as vacuolated cells in both the proximal and the distal colon; the lower the osmolality, the more mucin was released. The mucosa of the distal colon was conspicuously affected by solutions of lower osmolality. The influence of osmolality on mucin release was entirely local.Supported by a grant from the Deutsche Forschungsgemeinschaft (En 65/9)The authors wish to thank Prof. H. Höller and G. Rechkemmer for critical advice and Miss G. Becker for technical assistanceA preliminary portion of this study was presented at the 3rd Meeting of the European Intestinal Transport Group, Southampton, 21.–23. April, 1980     

Cat Heart Muscle in Vitro : IX. Cell ion and water contents in anisosmolal solutions

Cell contents of water, K, Na, and Cl have been determined in cat right ventricular papillary muscles immersed in solutions with and without NaCl when the external osmolality was varied with sucrose. The plot of cell water/kilogram dry weight (corrected for sucrose content) vs. (external osmolality)^-1 suggests that not less than 82% of water present in cells at physiological external osmolality is free to move across the cell membrane in response to an imposed osmotic gradient. Cells fail to increase their water content in very hypotonic solutions. For osmolalities greater than 5 times isosmolal, at which the mannitol space and the Cl³⁶ space are both equal to 100% of muscle water, rather large amounts of univalent cation appear to remain "bound" to the tissue.     

Work of adhesion of respiratory tract mucus.

A method was devised to measure the work of adhesion (WA) to a substrate of mucus, a viscoelastic gel, from the measured contact angle of glycerol on a mucus substrate and the known physical properties of a Teflon surface. Fifteen sputum samples from cystic fibrosis (CF) patients were compared with 25 mucus samples from canine tracheal pouches (CP), studied in the hydrated and partially dehydrated states. Apparent viscosity (eta A) and recoverable shear strain (SR) were measured by fluxgate magnetometry, and water content was inferred from vapor pressure osmometry. Na+, K+, and Ca2+ concentrations were measured with specific ion electrodes and Cl- with a chloridimeter. The Cl- concentration of the CP mucus was inversely proportional to its osmolality, and the Cl- concentration of the CP mucus was 102.5 +/- 1.6 meq/l compared with 55.6 +/- 2.5 meq/l for CF sputum. When CP mucus osmolality was increased from 316.0 +/- 5.5 to 430.0 +/- 7.5 mosmol/kg, WA increased from 25.1 +/- 1.8 to 31.1 +/- 1.2 ergs/cm2 and eta A increased from 391 +/- 55 to 622 +/- 121 P, respectively. CF sputum WA was 30.2 +/- 0.6 ergs/cm2, eta A was 1,110 +/- 316 P, and osmolality was 466.0 +/- 14.0 mosmol/kg. The increased WA and eta A of mucus in CF patients may thus be dependent on the hydration of mucus, which is related to the documented Cl- transport defect.     

Solubility of retinoids in water

Spectrophotometric and radioactive techniques were used to measure the water solubility of retinaldehyde, retinol (vitamin A), and retinoic acid under physiological conditions. Hydration decreases the molar extinction coefficient of these substances and shifts their absorption peak bathochromically (10 nm for retinal and approximately 1 nm for the rest). We find their solubility to be about 0.1 microM at room temperature, pH 7.3 (with experimental values being 0.11 microM for retinaldehyde, 0.06 microM for retinol, and 0.21 microM for retinoic acid). To prevent oxidative degradation of retinol, which is the most labile retinoid, our argon-saturated buffer solutions contained physiological levels of ascorbate or alpha-tocopherol. To the best of our knowledge, water solubility of these compounds has not yet been previously reported. Although the measured solubilities are relatively low, they are significant and may account for the movement of retinoids through the aqueous phase as observed by others during exchange with binding proteins and during intervesicular transfer in the absence of binding proteins. Diffusion of uncomplexed retinoids through the aqueous phase can be a major pathway for transport over subcellular distances.     

The solubility of fibrinogen in dilute salt solutions

Highly purified human fibrinogen was dialyzed versus eleven different sodium salts at ionic strengths of 0.005–0.3 and pH values of 4.5–8.0. After equilibration and centrifugation of the protein solutions, fibrinogen solubilities were determined spectrophotometrically and were analyzed as functions of pH, ionic strength, and specific anion. Bell-shaped curves are obtained when fibrinogen solubility is plotted as a function of pH. The solubility exhibits a minimum at a given pH and rises at acid and alkaline values. As the ionic strength is increased, the solubility curves shift toward more acid pH values. At constant pH values between 6 and 7, fibrinogen solubility increases with an increase in ionic strength. At constant pH values below pH 6, a decrease in solubility occurs as the ionic strength is increased. The isoionic pH of a saturated aqueous fibrinogen solution has been determined to be 6.25, meaning that fibrinogen in pure water behaves as a weak acid with a mean net charge of ?0.9. At pH values acid to 6.25, the anions solubilize fibrinogen in the following order of increasing efficacy: thiocyanate, perchlorate, sulfate, citrate, bromide, nitrate, phosphate, chloride, acetate, fluoride, and formate. This order is reversed at pH values alkaline to 6.25. Anion binding parameters calculated from the solubility data indicate that those anions which most effectively solubilize fibrinogen at alkaline pH and precipitate it at acid pH have the highest apparent binding affinities for the protein. Anions with less pronounced solubility effects have lower binding affinities.