Effects of citrate on the composition and enzymic coagulation of colloidal bovine casein aggregates

Colloidal casein aggregates (CCA) prepared from soluble whole bovine caseinates in the presence of Ca²⁺ and phosphate (Pi) ions by addition of different citrate (Cit) concentrations showed different mineral and proteic composition. Citrate concentration conditions the Ca and Pi concentrations incorporated into CCA, probably due to the complexing effect of this anion on calcium. A significant change in the incorporated Ca/Pi ratio at 8 mM citrate could very likely be associated to changes in CCA net charge. The incorporation of individual caseins to the colloidal particles obtained, as well as their average size and size distribution, depended also on the Cit concentration used [Cit]_P. α_S- and β-caseins assembled in the CCA structure sharply decreased at a [Cit]_P higher than 15 mM, i.e., at a low Ca²⁺ concentration in the aggregates, showing that the presence of this cation is necessary for the incorporation of these caseins. An inverse relationship between the aggregation step rate in CCA enzymic coagulation and their average size was observed. The aggregation rate vs the average size curve obtained at [Cit]_P 8 mM clearly differed from the curves obtained at 10 and 12 mM, respectively, a fact probably related to a change in the CCA net charge. This behavior showed the effect of citrate concentration on CCA functional properties.     

Combined effects of Ca2+ and humic acid on colloid transport through porous media

We report the separate and combined effects of humic acid and Ca²⁺ ions on the transport of colloidal particles through a sand-packed column. Polystyrene latex particles with a sulfate functional group were used as model colloids. The concentrations of both the inlet solution and the effluent solutions were measured during each experimental run. Breakthrough curves were obtained by taking the ratios of each effluent sample concentration to the inlet solution concentration. In the absence of humic acid, the results indicate that increasing the concentration of Ca²⁺ increases particle attachment to the sand, thus causing decreased transport rates of latex particles through the porous bed matrix. Once 4 mg/l humic acid was added to the system, changes were observed in the effect that Ca²⁺ has on latex particle breakthrough. In a system containing calcium, increasing the humic acid concentration was shown to reduce particle attachment and increase transport rates. In the absence of calcium, the ratios for the outlet-to-inlet concentrations were similar for each concentration of humic acid. The electrophoretic mobility was also measured in order to determine the role of electrostatic repulsion in the latex particle transport. The electrophoretic mobility of the latex particles was found to be dependent on humic acid concentration in the absence of Ca²⁺ but not in its presence. Received: 2 February 2001 Accepted: 6 2001     

Distribution of strontium in milk component

The distribution of strontium between the milk components, i.e., serum, casein micelles, whey and hydroxyapatite was determined. The sorption on hydroxyapatite was investigated using batch method and radiotracer technique. The aqueous phase comprised of either milk or whey. The sorption of strontium on hydroxyapatite depended on the method of its preparation and on the composition of the aqueous phase. The sorption of strontium was increased with an increase of pH. The presence of citrate species resulted in decrease of the sorption of strontium on hydroxyapatite. The sorption of ⁸⁵Sr on hydroxyapatite decreased with the increasing concentration of Ca²⁺ ions. Addition of Ca²⁺ ions to milk resulted in milk pH decrease. The decrease in pH value after calcium addition to milk is related to exchanges between added calcium and micellar H⁺. The average value of strontium sorption on casein micelles in milk with presence of hydroxyapatite was (47.3 ± 5.6) %. The average value of sorption of ⁸⁵Sr on casein micelles in milk without the addition of hydroxyapatite was (68.9 ± 2.2) %.     

Photochemistry of semiconductor colloids. Preparation of extremely small ZnO particles,fluorescence phenomena and size quantization effects

Extremely small ZnO particles (< 2.5 nm) are formed in the precipitation of Zn²⁺ by OH⁻ in alcoholic solution. The absorption threshold and fluorescence band shift towards longer wavelengths upon growth of the colloidal particles. These shifts are typical for the transition from molecular to semiconductor material. The colloidal ZnO could be separated in the form of a powder with a specific surface of 108 m²/g. A Cu²⁺-doped colloid was also prepared. Colloidal ZnO has a strong fluorescence, λ_max = 540 nm, which decays with τ = 10 ns, and a weak one, λ_mun = 370 nm, τ < 1 ns. Intense illumination in the absence of O₂ results in the disappearance of the 540 nm fluorescence and a blue-shift of the absorption spectrum. Both changes are immediately reversed upon admission of air. The results are explained on the basis of the Hauffe mechanism for the dissolution of ZnO, in which intermediate Zn⁺ plays a role. Prolonged illumination of a propanolic sol leads to precipitation of zinc metal. In the presence of 1 × 10⁻¹ M methylviologen. MV⁺ is formed with a quantum yield of 60%.     

Peanut-shaped aggregation of CaCO<Subscript>3</Subscript> crystallites in the presence of an amphiphilic derivative of carboxymethylchitosan

An amphiphilic derivative of carboxymethylchitosan (CMCS), (2-hydroxyl-3-butoxyl)propyl-CMCS (HBP-CMCS), was used as an organic additive in the precipitation process of calcium carbonate (CaCO₃). HBP-CMCS molecules can interact with calcium ions, the functional groups of which act as active sites for the nucleation and crystallization of CaCO₃. Simultaneously, HBP-CMCS molecule also functionalizes as a colloidal stabilizer to prohibit the sedimentation of the grown CaCO₃ crystals, depending upon the molar ratio of the initial Ca²⁺ ions to the repeat units of HBP-CMCS molecules. The combination investigations of scanning electron microscopy, X-ray diffraction, and Fourier transform infrared spectroscopy on the precipitated CaCO₃ crystals proved that concentrations of HBP-CMCS and Ca²⁺ exert great influence on the crystallization habit of CaCO₃, such as the nucleation, growth, morphology, crystal form, etc. The formation of the peanut-shaped CaCO₃ particles suggests the template effect of HBP-CMCS molecules on the aggregation behavior of CaCO₃ nanocrystals.     

Synthesis of Calcium Phosphate Nanoparticles in Collagen Medium

Summary: Mineralization of the proteic matrix composed mostly of collagen type I is controlled by specific interactions of ions Ca²⁺ and PO, present in the biological fluid, with the matrix, and by the diffusion of these ions. The specific interactions and the diffusion of ions combined; result in the nucleation and formation of calcium phosphate particles. Moreover, they control the morphology, size, crystallinity and composition of the particles. In this work, precipitation of calcium phosphate particles in a collagen matrix type I was carried out through impregnation of the matrix with a Ca²⁺ and PO solution, with Ca/P ratio 1.67 and pH 2.5. Precipitation of particles associated with matrix structuring was carried out by adsorption of gaseous ammonia.     

Coordination properties of polymeric azacrown ethers

New polymeric aza-crown ethers (PACE), soluble in water and organic solutions and cross-linked ones, containing different macrocycles in side chains have been synthesised by polymerisation and chemical modification reactions. The coordination próperties of these PACE are studied. It is shown that during coordination of the VO²⁺, Cu²⁺ ions with PACE, cross-linking of macromolecules by metal ions takes place by “sandwich” complex formation. The character of complexes distribution along PACE coils may be equal or nonequal, depending on polymer reactivity. The synthesised PACE are used as high specific polymer reagents for colloid rare metals recovery. It is shown that flocculation of negatively charged inorganic sols with PACE is due to electrostatic adsorption and specific binding. In acid and neutral media, dispersions of gold, silver, copper ferrocyanide and silicon dioxide undergo high flocculation as a result of non-specific electrostatic adsorption. Alkaline media provide conditions for donor-acceptor binding, increasing flocculation selectivity. In the uncharged state (pH 11,2) PACE exhibit high selectivity in binding gold particles. Stability of colloidal dispersions in the presence of monomer aza-crown ether (ACE) indicates an important polymer influence on the fine metal particles flocculation.     

Near-IR spectroscopy as a method for studying the formation of calcium naphthenate

A method for studying the precipitation of calcium naphthenate particles by means of near-IR spectroscopy is presented. Naphthenic or fatty acids were dissolved in water at high pH (11.2–11.5). Upon addition of a Ca²⁺ solution the nucleation period and particle growth were monitored. The near-IR spectra experience a baseline elevation owing to the formation and growth of calcium naphthenate particles. The resulting change in optical density over time is discussed on the basis of supersaturation, particle sizes, agglomeration, Ca²⁺-to-carboxylic acid ratio and nucleation process. Solubility products, defined as the ion concentration products where no particle growth was detected, were estimated for the calcium soaps. The method showed some quantitative limitations since the particle sizes changed with supersaturation. Smaller particles will have less influence on the optical density and the larger particle will dominate the resulting scattering contribution. However, it is obvious that the method has qualitative value, for example, to study the efficiency of different calcium naphthenate inhibitors.     

Thermal behavior of Ca2+ and Cu2+ oxalates obtained by precipitation in homogeneous solution from dimethyl oxalate hydrolysis

Mixed calcium and copper oxalates, with different proportions of Ca²⁺ and Cu²⁺ ions, were precipitated by dimethyl oxalate hydrolysis in homogeneous solution. The compounds were evaluated by means of scanning electron microscopy, energy dispersive X-ray spectroscopy, thermogravimetry (TG), and differential thermal analysis (DTA). The results suggested quantitative precipitation without solid solution formation. From the TG and DTA curves, it was possible to evaluate the Ca²⁺ ion proportion in the solid phase and to confirm the precipitation of the individual species.     

Significance of transparent exopolymer particles derived from aquatic algae in membrane fouling

In recent years, Transparent exopolymer particles(TEPs) have been identified as significant contributors to membrane surface biofouling. Reported research on the effect of TEPs on membrane fouling has mainly focused on algae-derived TEPs in the ocean, and very limited investigations have been conducted on those in freshwater systems. In this study, we investigated the characteristics of TEPs derived from Microcystis aeruginosa and their influence on membrane fouling in an ultrafiltration (UF) system. The results indicated that bound TEPs could lead to more serious membrane fouling while free TEPs caused more serious irreversible membrane fouling. Further studies showed that in free TEP solutions, small-sized colloidal TEPs (c-TEPs) rather than large-sized particle TEPs (p-TEPs) showed a significantly positive correlation with irreversible membrane fouling. The presence of Ca²⁺ ions in influent water can reduce membrane fouling to some extent since a low concentration of Ca²⁺ ions (1 mM) can lead to the transformation of most free TEPs from the colloidal to particulate state. Both acidic and alkaline environments of free TEP solutions result in more serious membrane fouling compared to a neutral environment of free TEP solution. The negative impact of the acidic environment on membrane fouling was more significant than that of the alkaline environment. The abovementioned results show that when using a UF system to filter water with high algal content, greater attention should be paid to free TEPs, especially those in the colloidal state, because they can cause serious, irreversible membrane fouling.     

Selective separation of strontium by multitopic ion‐pair receptor: A DFT exploration

Selective extraction of a radionuclide in the presence of other interfering ions is one of the vital steps in the back‐end‐of‐the‐nuclear fuel cycle. The presence of interfering cations (such as Ca²⁺) in the radioactive waste and involvement of multiple separation steps are known to be bottlenecks in the efficient Sr²⁺ extraction. Here, using free energy corrected density functional theory, we have proposed a two‐step Sr²⁺ extraction methodology in nitrate media in the presence of interfering Ca²⁺ ion using a multitopic ion‐pair receptor, which was earlier reported to be strongly selective for K⁺ (Kim et al. J. Am. Chem. Soc. 2012, 134 , 1782–1792). To depict the correct free energy trend in the proposed extraction processes, the most probable binding mode of the metal (Sr²⁺, Ca²⁺, and K⁺) nitrates in the host are identified. In excellent agreement with the previously reported experiment, Crown/Pyrrole (C/P) binding is noted to be the most preferable mode for KNO₃, where K⁺ and occupied the Crown (C) and Pyrrole (P) site, respectively. However, the divalent metal ions (Ca²⁺ and Sr²⁺) are noted to marginally prefer Crown/Crown‐Pyrrole (C/CP) mode, in which metal reside at the C site while two nitrates occupy the P site and also simultaneously bind at the outer sphere of C site to coordinate with the metal via monodentate motif. Based on the free energy of extraction, we predict that the selective separation of chemically alike Ca²⁺/Sr²⁺ pair is indeed achievable using this receptor. We propose that once [Sr(NO₃)₂] is extracted in organic media, the receptor's high affinity toward K⁺ in nitrate media can be used to back strip Sr²⁺ to the aqueous phase.     

Formability and properties of self-standing clay film by montmorillonite with different interlayer cations

Influences of exchangeable interlayer cations were investigated on self-standing film formability, film morphology, and properties of the clay films such as flexibility and gas barrier property. Ion-exchanged montmorillonite samples were prepared by a cation exchange from naturally bearing cation, mostly Na⁺, to Li⁺, Mg²⁺, Ca²⁺, Al³⁺, and Fe^{2+, 3+}. Self-standing films were prepared from aqueous colloidal dispersions of these montmorillonite samples with no additives. The montmorillonite samples with monovalent or divalent cation formed flat self-standing films while the Al-montmorillonite sample produced a distorted film. The Fe-montmorillonite sample formed many separated reddish-brown rod-shaped pieces. Clay film microstructures were different with interlayer cations. The films with monovalent interlayer cations were constructed by the stacking of units with delicately waved thin clay sheets in the whole film, but other films show different morphologies between the upper side and lower side; the upper side is laminated with thin sheets; the lower side is laminated with large thick sheets.The self-standing films’ flexibility and gas barrier property differed according to the interlayer cations. These properties were good in cases of samples with monovalent cations. The innumerable short wave and sheet thinness are considered to foster good flexibility and gas barrier properties. The differences in film formability and properties of the films are attributable to different swellability among samples with different interlayer cations. The montmorillonite samples with monovalent cations swell sufficiently by water, but those with polyvalent cations swell poorly. In the latter case, clay crystals aggregate in water, then the aggregate grows into large particles, creating a film with large particles.     

Structure of Redispersible SnO2 Nanoparticles

Suspensions of undoped SnO₂ nanoparticles and containing Eu³⁺ ions were prepared by a sol-gel procedure. Using the classical synthesis method (precipitation), the particles tend to grow by a coarsening process in order to minimize the surface free energy. This effect can strongly be reduced by the addition of an amide and surfactant during the synthesis, which decreases the surface free energy of the colloidal particles. These additives promote the formation of powders composed of very small primary particles formed by a crystallite of 10 Å, and exhibit good redispersion properties. The local and long order structures of the redispersible powder were studied by X-rays absorption spectroscopy at Sn L_I edge and X-rays diffraction, respectively. The structure of the colloidal aggregates in suspension was investigated by small angle X-rays scattering (SAXS). SAXS results indicate the sol are composed by a polidisperse system of hard spheres resulting of agglomeration of the primary particles and their size increasing by agglomeration for progressively higher Eu³⁺ content.     

Interaction of trialkyltin(IV) chlorides with sarcoplasmic reticulum calcium ATPase

The interaction of the organotin compounds trimethyltin(IV) and tributyltin(IV) chlorides with the calcium pump from sarcoplasmic reticulum membranes was studied. It was found that the presence of calcium fully protects against the inhibitory effect of both organotin compounds. However, the apparent affinity of the protein for tributyltin chloride is two orders of magnitude higher than for trimethyltin chloride (K_0.5 values of 14 µ m and 1.4 m m , respectively). Studies of intrinsic fluorescence of the Ca²⁺‐ATPase and enzyme phosphorylation by ATP and Pi support the hypothesis that the inhibitory properties of trialkyltin compounds are due to the inhibition of calcium binding to the high‐affinity binding sites of the Ca²⁺‐ATPase. This suggests that there is a specific interaction between the trialkyltin compounds and the calcium binding sites of the protein. The effect of trialkyltin compounds on Ca²⁺‐ATPase was also addressed by differential scanning calorimetry to assess the thermal transition of the protein denaturation, and by infrared spectroscopy in the absorption region corresponding to the amide I band (1600–1700 cm^?1) to observe changes in the secondary structure of the protein. We conclude that the interaction of trialkyltin compounds with Ca²⁺‐ATPase reduces the affinity and cooperativity for calcium binding and, consequently, the inhibition of ATPase activity. These events are accompanied by changes in the secondary structure of the protein, including loss of α‐helix structure and a concomitant increase in protein aggregation or unfolding. The activity of trialkyltin compounds on the Ca²⁺‐ATPase is discussed in relation to their solubility in water and in the lipid phase. Copyright © 2012 John Wiley & Sons, Ltd.     

Quantitative parameters for the sequestering capacity of polyacrylates towards alkaline earth metal ions

The complex formation constants of polyacrylic (PAA) ligands (1.4≤log N≤2.4, N=number of monomer units) with calcium and magnesium ions were determined in different ionic media at different ionic strengths, 0≤I≤1 mol l⁻¹, at t=25 °C. Experimental pH-metric data in the presence of Ca²⁺ or Mg²⁺ were firstly analysed in terms of apparent protonation constants, log K^H*, using the “three parameter model” proposed by Högfeldt; differences in log K^H*, determined in different ionic media, were interpreted in terms of complex species formation. The only species present in the system M-PAA (M=Ca²⁺ or Mg²⁺) is ML₂: attempts to find species of different stoichiometry were unsuccessful. The stability dependence of this species on ionic strength, on the degree of neutralisation (α) and on PAA molecular weight is discussed using empirical equations. The formation constant, log β₂, is significantly higher for Ca²⁺ than for Mg²⁺: at I=0.1 mol l⁻¹ (NaCl), log N=1.8 and α=0.5, log β₂^Ca=4.43 and log β₂^Mg=4.24. The formation of polyacrylate-alkaline earth metal complexes is discussed in the light of sequestering effects in natural waters.     

Effect of the nature and concentration of salting-out agents on the extraction of cobalt(II) from chloride solutions with trialkylamine

The effect of chlorides of Ca²⁺, Ni²⁺, Mg²⁺, Al³⁺, Li⁺, Fe²⁺, Cr³⁺, Na⁺, NH ₄ ⁺ , La³⁺, Nd³⁺ on the extraction recovery of cobalt from chloride solutions with mixtures based on trialkylamine was studied. The series of the salting-out activity of differently charged cations and the degree of their coextraction were determined.     

Use of Different Salt Solutions in Salting-Out TLC of Co(III) Complexes on Silica Gel

Saturated aqueous solutions of 28 different salts have been studied as a potential mobile phases for salting-out thin-layer chromatography, on silica gel, of a series of four mixed bis-aminocarboxylato cobalt(III) complexes. In addition, by linear regression analysis of chromatographic data obtained for fifteen mixed aminocarboxylato Co(III) complexes (four series) with solutions of ammonium chloride, three alkali metal chlorides, and four alkaline earth metal chlorides, four linear dependences previously established on different adsorbents with (NH₄)₂SO₄ solutions were confirmed. The qualities of the separations achieved with the salts were compared and Li⁺, Mg²⁺, and Ca²⁺ chlorides are proposed as the most suitable.     

Photochemical reaction and diffusion of caged calcium studied by the transient grating

A photoreaction of caged calcium (Ca²⁺) was investigated by using the time-resolved transient grating (TG) method. The q²-dependent feature of the TG signal was analyzed based on a model that there are two parallel dissociation steps with different rates and Ca²⁺ is released promptly after the fracture of the caged compound. The TG signal representing the presence of Ca²⁺ was appeared by the volume contribution. Although the diffusion coefficients of Cg and the decomposed product are different without Ca²⁺, only one diffusion component was observed after the dissociation of CgCa²⁺, indicating that the caged compounds and Ca²⁺ diffuse together.     

Hydroxyapatite nanoparticle prepared by controlled precipitation from aqueous phase

Hydroxyapatite nanoparticles (NPs) were prepared by controlled precipitation in the presence of stabilizers that confined growth and inhibited the aggregation of nanoparticles. Electrostatically stabilized NPs were prepared in the presence of sodium citrate; Tween 80 was used for steric stabilization. At low stabilizer concentrations, nanorods were formed of grown together, spheroidal hydroxyapatite NPs of ~20 nm in diameter. The rod length decreased as ether sodium citrate or Tween 80 concentration increased. When Cit^3–/Ca²⁺ = 3mol/mol, platelike NPs were formed 20–45 nm long and ~10 nm wide; for Cit^3–/Ca²⁺ = 4 mol/mol, NPs had sizes of 10–15 nm. At relatively high Tween 80 concentrations (>0.05 mol/L), foamlike structures were obtained.     

Thermodynamics and Kinetics of Heat Inactivation of a Novel Keratinase from Chryseobacterium sp. Strain kr6

A novel keratinase from Chryseobacterium sp. strain kr6 was purified to homogeneity by (NH₄)₂SO₄ precipitation, gel permeation on Sephadex G-100, and Q-Sepharose Fast Flow anion-exchange chromatography. The molecular weight of the purified enzyme was around 20 kDa. Kinetic and thermodynamic parameters for thermal inactivation were determined. The influence of Ca²⁺ and Mg²⁺ ions and purification degree on the enzyme stability was evaluated in the range of 50 to 60 °C. The results showed that first-order kinetics explained well the thermal denaturation of the keratinase in this temperature interval. The presence of Ca²⁺ increases significantly the enzyme stability. Compared with the controls, the half-life of the purified enzyme after two purification steps in the presence of Ca²⁺ increased 7.3, 20.2, and 9.8 fold at 50, 55, and 60 °C, respectively. Thermodynamics parameters for thermal inactivation were also determined.