Feasibility of using dialysis for determining calcium ion concentration and pH in calcium-fortified soymilk at high temperature

Abstract: Dialysis was performed to examine some of the properties of the soluble phase of calcium (Ca) fortified soymilk at high temperatures. Dialysates were obtained while heating soymilk at temperatures of 80 and 100 °C for 1 h and 121 °C for 15 min. It was found that the pH, total Ca, and ionic Ca of dialysates obtained at high temperature were all lower than in their corresponding nonheated Ca‐fortified soymilk. Increasing temperature from 80 to 100 °C hardly affected Ca ion concentration ([Ca²⁺]) of dialysate obtained from Ca chloride‐fortified soymilk, but it increased [Ca²⁺] in dialysates of Ca gluconate‐fortified soymilk and Ca lactate‐fortified soymilk fortified with 5 to 6 mM Ca. Dialysates obtained at 100 °C had lower pH than dialysate prepared at 80 °C. Higher Ca additions to soymilk caused a significant (P≤ 0.05) reduction in pH and an increase in [Ca²⁺] of these dialysates. When soymilk was dialyzed at 121 °C, pH, total Ca, and ionic Ca were further reduced. Freezing point depression (FPD) of dialysates increased as temperature increased but were lower than corresponding soymilk samples. This approach provides a means of estimating pH and ionic Ca in soymilks at high temperatures, in order to better understand their combined role on soymilk coagulation.     

Physicochemical properties of calcium-fortified soymilk with microencapsulated and chelated calcium salt

In the current research, soymilk was fortified with 2,000 mg L^?1 calcium (Ca) through direct addition and microencapsulated Ca. There have been no reports regarding Ca-fortification of soymilk by W/O/W double-emulsion method. In order to inhibit Ca–protein interaction and improve soymilk stability, different concentrations (0, 10, 15, 22, 25 and 30 g L^?1) of potassium citrate were added to soymilk samples as a metal-chelating agent (CA). Adding CA caused an undesirable aftertaste. Thus, in order to solve this problem, Ca was microencapsulated using water-in-oil-in-water (W/O/W) double-emulsion method, and coacervates were formed by means of gelatin–agar electrostatic interaction. Physicochemical properties of pasteurized soymilk including pH, phase separation index, sedimentation, viscosity, conductivity and color parameters (L, a, b and ΔE) were assayed over storage time. CA addition led to reduction in phase separation index, sedimentation, viscosity and increase in conductivity. However, microcapsule addition showed no phase separation so that soymilk stabilization was achieved; still, viscosity, conductivity and ΔE parameters were increased by Ca microcapsule addition. Microencapsulation was a proper Ca-fortification method in soymilk regarding higher stability of the final product over pasteurization shelf life.     

Fortification of reconstituted skim milk powder with different calcium salts: Impact of physicochemical changes on stability to processing

Reconstituted skim milk powder (RSMP) was fortified with 12.5 mM/L calcium (Ca) using soluble [Ca chloride (CChlor), Ca gluconate (CGluc) or Ca hydroxide (CHyd)] or insoluble [Ca carbonate (CCarb), Ca phosphate (CPhos) or Ca citrate (CCit)] salts. CPhos and CCit decreased heat stability moderately at 140 °C, while CCarb had no effect. Soluble salts had a pronounced destabilising effect at 140 °C due to increased ionic Ca levels. After a laboratory‐scale high‐temperature short‐time heating process, CHyd‐fortified RSMP had a lower viscosity than all other samples. CChlor and CGluc increased sedimentation during accelerated physical stability testing, with CHyd causing greater sedimentation than CChlor or CGluc.     

钠盐对果汁豆奶稳定性的影响

采用单因素实验及正交实验分别研究了单个磷酸盐、柠檬酸盐及复合磷酸盐等含钠离子的不同盐类豆奶稳定性的影响。结果表明,钠类盐的加入能使体系的粘度及稳定性升高,但其添加量有最佳值,此值因盐的种类不同而不同;柠檬酸三钠的稳定效果优于单个的磷酸盐,但不如复配磷酸盐。加入柠檬酸三钠和复合磷酸盐后,果汁豆奶中的平均粒径均表现出增大的趋势。     

Influence of calcium and phosphorus, lactose, and salt-to-moisture ratio on Cheddar cheese quality: pH buffering properties of cheese

The pH buffering capacity of cheese is an important determinant of cheese pH. However, the effects of different constituents of cheese on its pH buffering capacity have not been fully clarified. The objective of this study was to characterize the chemical species and chemical equilibria that are responsible for the pH buffering properties of cheese. Eight cheeses with 2 levels of Ca and P (0.67 and 0.47% vs. 0.53 and 0.39%, respectively), residual lactose (2.4 vs. 0.78%), and salt-to-moisture ratio (6.4 vs. 4.8%) were manufactured. The pH-titration curves for these cheeses were obtained by titrating cheese:water (1:39 wt/wt) dispersions with 1 N HCl, and backtitrating with 1 N NaOH. To understand the role of different chemical equilibria and the respective chemical species in controlling the pH of cheese, pH buffering was modeled mathematically. The 36 chemical species that were found to be relevant for modeling can be classified as cations (Na⁺, Ca²⁺, Mg²⁺), anions (phosphate, citrate, lactate), protein-bound amino acids with a side-chain pKa in the range of 3 to 9 (glutamate, histidine, serine phosphate, aspartate), metal ion complexes (phosphate, citrate, and lactate complexes of Na⁺, Ca²⁺, and Mg²⁺), and calcium phosphate precipitates. A set of 36 corresponding equations was solved to give the concentrations of all chemical species as a function of pH, allowing the prediction of buffering curves. Changes in the calculated species concentrations allowed the identification of the chemical species and chemical equilibria that dominate the pH buffering properties of cheese in different pH ranges. The model indicates that pH buffering in the pH range from 4.5 to 5.5 is predominantly due to a precipitate of Ca and phosphate, and the protonation equilibrium involving the side chains of protein-bound glutamate. In the literature, the precipitate is often referred to as amorphous colloidal calcium phosphate. A comparison of experimental data and model predictions shows that the buffering properties of the precipitate can be explained, assuming that it consists of hydroxyapatite [Ca₅(OH)(PO₄)₃] or Ca₃(PO₄)₂. The pH buffering in the region from pH 3.5 to 4.5 is due to protonation of side-chain carboxylates of protein-bound glutamate, aspartate, and lactate, in order of decreasing significance. In addition, pH buffering between pH 5 to 8 in the backtitration results from the reprecipitation of calcium and phosphate either as CaHPO₄ or Ca₄H(PO₄)₃.     

Breadmaking performance and technological characteristic of gluten-free bread with inulin supplemented with calcium salts

The fortification of gluten-free bread containing inulin with different organic and non-organic calcium sources was investigated. Calcium lactate, calcium citrate, calcium chloride and calcium carbonate were used as calcium sources. Gluten-free bread composed of corn starch, potato starch, salt, yeast, pectin, sugar and sunflower oil was used as a reference. The calcium salts were supplemented to the gluten-free formula to provide equal content of elementary calcium (Ca⁺²). The Mixolab^? device was used to analyse the behaviour of gluten-free dough subjected to a dual mechanical shear stress and temperature constraint. Calcium salts significantly modified the dough behaviour during heating and cooling. The addition of calcium carbonate and calcium citrate provoked an increase in dough consistency during heating and cooling compared with the other salt-enriched samples. The specific volume and texture parameters of gluten-free breads varied with the calcium salt used, but calcium carbonate and calcium citrate showed improved values. The higher calcium content of the enriched breads, compared with the control, confirmed the fortification. Sensory evaluation of the calcium-fortified breads confirmed that calcium carbonate followed by calcium citrate was the most recommended salt for obtaining calcium fortification of gluten-free breads.     

Bioavailability of calcium and physicochemical properties of calcium-fortified buffalo milk

Buffalo milk was fortified with calcium at the rate of 50 mg calcium/100 ml milk using calcium chloride, calcium lactate and calcium gluconate, and the resulting decrease in pH was restored to its original value by adding disodium phosphate. The maximum heat stability of calcium-fortified buffalo milk remained slightly lower than that of unfortified milk. Calcium gluconate-fortified milk had the highest heat stability, bioavailability of calcium, partitioning of calcium in the dissolved state and viscosity, and the least curd tension compared to other fortified milk, without any adverse impact on sensory properties. The bioavailability of calcium and heat stability was lowest in the case of buffalo milk fortified with calcium chloride.     

Impact of source and level of calcium fortification on the heat stability of reconstituted skim milk powder

Calcium enrichment of food and dairy products has gained interest with the increased awareness about the importance of higher calcium intake. Calcium plays many important roles in the human body. Dairy products are an excellent source of dietary calcium, which can be further fortified with calcium salts to achieve higher calcium intake per serving. However, the addition of calcium salts can destabilize food systems unless conditions are carefully controlled. The effect of calcium fortification on the heat stability of reconstituted skim milk was evaluated, using reconstituted skim milks with 2 protein levels: 1.75 and 3.5% (wt/wt) prepared using low and high heat powders. Calcium carbonate, phosphate, lactate, and citrate were used for fortification at 0.15, 0.18, and 0.24% (wt/wt). Each sample was analyzed for solubility, heat stability, and pH. The addition of phosphate and lactate salts lowered the pH of milk, citrate did not have any major effect, and carbonate for the 1.75% protein samples increased the pH. In general, changes in solubility and heat stability were associated with changes in pH. Calcium addition decreased the solubility and heat stability. However, interestingly, the presence of carbonate salt greatly increased the heat stability for 1.75% protein samples. This is due to the neutralizing effect of calcium carbonate when it goes into solution. The results suggested that the heat stability of milk can be affected by the type of calcium salt used. This may be applied to the development of milk-based calcium enriched beverages.     

Effects of calcium chloride and sodium hexametaphosphate on certain chemical and physical properties of soymilk

ABSTRACT:  Soymilks with sodium hexametaphosphate (SHMP) (0% to 1.2%) and calcium chloride (12.50, 18.75, and 25.00 mM Ca) were analyzed for total Ca, Ca ion concentration, pH, kinematic viscosity, particle diameter, and sediment after pasteurization. Higher added Ca led to significant ( P ≤ 0.05) increases in Ca ion concentration and significant ( P ≤ 0.05) decreases in pH. At certain levels of SHMP, higher concentrations of added Ca significantly increased ( P ≤ 0.05) kinematic viscosity, particle diameter, and sediment. Increasing SHMP concentration reduced Ca ion concentration, particle diameter, and dry sediment content, but reduced kinematic viscosity of samples ( P ≤ 0.05). Adding SHMP up to 0.7% influenced pH of soymilk in different ways, depending on the level of Ca addition. When the pH of Ca-fortified soymilk was adjusted to a higher level, ionic Ca decreased as pH increased. There was a negative linear relationship between the logarithm of ionic Ca concentration and the adjusted pH of the soymilk. Ionic Ca appeared to be a good indicator of thermally induced sediment formation, with little sediment being produced if ionic Ca was maintained below 0.4 mM.     

Effects of mineral salts and calcium chelating agents on the gelation of renneted skim milk

The effects of adding CaCl2, orthophosphate, citrate, EDTA, or a mixture of these, to reconstituted skim milk (90 g of solids/kg solution) on the gelation of renneted milk were mediated by changes in Ca2+ activity and the casein micelle. At pH 6.65, the addition of citrate or EDTA, which removed more than 33% of the original colloidal calcium phosphate with the accompanying release of 20% casein from the micelle, completely inhibited gelation. Reformation of the depleted colloidal calcium phosphate and casein in the micelle, by the addition of CaCl2, removed this inhibition. When the minimum requirements for colloidal calcium phosphate and casein in the micelle were met, the coagulation time decreased with increasing Ca2+ activity, leveling off at high Ca2+ activity. The storage modulus of renneted gels, measured at 3 h, increased with increasing colloidal calcium phosphate content of micelles up to a level at which it was approximately 130% of the original colloidal calcium phosphate in the micelles. Further increases in colloidal calcium phosphate by the addition of CaCl2, orthophosphate, or mixtures of these, which did not change the proportion of casein in the micelle, decreased the storage modulus. The gelation of the renneted milk was influenced by Ca2+ activity, the amounts of colloidal calcium phosphate, and casein within the micelle, with the effects of colloidal calcium phosphate and casein within the micelle clearly dominating the storage modulus. These results are consistent with the model of Horne (Int. Dairy J. 8:171-177, 1998) which postulates that, following cleavage of the stabilizing K-casein hairs by rennet, the properties of the rennet gel are determined by the balance between the electrostatic and hydrophobic forces between casein micelles.     

Chloride, gluconate, sulfate, and short-chain fatty acids affect calcium flux rates across the sheep forestomach epithelium

In ruminants, more than 50% of overall gastrointestinal Ca absorption can occur preintestinally, and the anions of orally applied Ca salts are thought to play an important role in stimulating ruminal Ca absorption. This assumption is based mainly on ion-exchange studies that have used gluconate as the control anion, which may bind Ca²⁺ ions and interfere with treatment effects. In the present study, we investigated the distinct effects of different anions on Ca absorption across the sheep rumen and on the concentration of free Ca²⁺ ions ([Ca²⁺]_ion). We showed that gluconate, sulfate, and short-chain fatty acids (SCFA) remarkably reduced [Ca²⁺]_ion in buffer solutions. Nevertheless, increasing the Cl or SCFA concentration by 60 mM stimulated net ruminal Ca absorption 5- to 7-fold, but these effects could be antagonized by gluconate. Therefore, ion-exchange experiments must be (re)evaluated very carefully, because changes in [Ca²⁺]_ion in the presence of gluconate, sulfate, or SCFA not only might entail an underestimation of Ca flux rates, but also might have effects on other cellular pathways that are Ca²⁺ dependent. Concerning the optimal Ca supply for dairy cows, the present study suggests that CaCl₂ formulations and Ca salts of the SCFA stimulate Ca absorption across the rumen wall and are beneficial in preventing or correcting a Ca deficiency.     

The role of calcium, phosphate and citrate ions in the stabilization of casein micelles.

To obtain greater insight into the interaction of Ca, citrate and phosphate ions with casein, 31PNMR measurements were performed on combinations of these ions with alphas- and kappa-caseins. It was found that addition of alphas-casein to a Ca phosphate solution in D2O at 27 degrees C and pD 6.4 resulted in a downfield shift of the 31P singlet. An almost identical shift was observed with kappa-casein, but no shift was found when only phosphate ions were present or when Ca2+ were added to phosphate ions in the absence of casein. Separate experiments with poly-L-lysine, mol. wt approx. 35,000, resulted in similar downfield 31P chemical shifts of Ca phosphate as with both caseins, whereas no shift was observed when poly-glycine was added. From these results it can be concluded that Ca and phosphate ions associate with casein in a co-operative manner, probably in the way described by ter Horst (1963) as a complex with the NH3+-groups of lysine or arginine in a structure such as: (casein--NH3+)--PO43---Ca2+. The formation of this complex may be enhanced by citrate ions, since preliminary results have shown that addition of Na citrate to a solution of alphas-casein with added Ca phosphate produces a broadening of the 31P signal as well as a chemical shift.     

Calcium Compounds to Improve Gel Functionality of Pacific Whiting and Alaska Pollock Surimi

The effect of calcium compounds during three thermal treatments with or without setting was studied. Formation of cross-linking was investigated using SDS-PAGE. Solubility varied. Calcium acetate, chloride, and caseinate were extremely soluble. Calcium lactate had good solubility at 0.2% or higher, then in descending order were phosphate, citrate, sulfate, and carbonate. Effects of temperature on solubility were not measurable except for caseinate. When 25°C setting was applied to surimi, calcium was most effective. Effect of calcium on shear stress was dependent on species, setting temperature, and specific compound. SDS-PAGE indicated that improved gel functionality was likely due to Ca⁺⁺-dependent trans-glutaminase. Shear strain values were not affected by adding calcium compounds regardless of species or thermal treatments.     

Effect of components extracted from okara on the physicochemical properties of soymilk and tofu texture

ABSTRACT:  The physicochemical properties of soymilk and the texture of tofu were compared with regard to 2 kinds of soymilk, one of which was prepared by squeezing homogenates before heating and the other was prepared by squeezing after heating raw soymilk with okara, residue of soymilk production. Relative particulate protein content and viscosity were higher and pH was lower in the soymilk prepared by the latter method, in which liberated lipid bodies were decreased and more lipids were precipitated with protein after centrifugation, suggesting a change in the interaction between proteins and lipids. A difference in the distribution of proteins and lipids was also implied by analysis with a laser particle size analyzer. The breaking stress of tofu made with 0.30% glucono-delta-lactone increased in accordance with an increase in particulate protein. The calcium and magnesium contents increased in soymilk prepared by squeezing after heating with okara. Viscosity was slightly increased and pH decreased by adding calcium to the soymilk, but the particulate protein content and breaking stress of tofu did not increase significantly. To examine the effect of macromolecules, okara was extracted by boiling and dialyzed. Viscosity and particulate protein content in soymilk increased as the dialyzed extracts of the okara were added. The breaking stress of tofu was increased by adding the dialyzed extracts but excessive amounts of the extracts resulted in softer tofu. Spectra of Fourier-transform infrared spectroscopy and electrophoresis-separated patterns of proteins indicated that the dialyzed extracts contained mainly polysaccharides and the Basic 7S globulin protein.     

柠檬酸钠协同碳酸氢钠替代磷酸盐对法兰克福香肠品质的影响

为减少磷酸盐在肉类加工中的使用,降低乳化肉糜制品中磷酸盐的含量,开发高效的无磷保水剂正逐步成为肉品行业的研究热点.本研究在添加0.2％(w/w)碳酸氢钠的基础上,将柠檬酸钠分别以0.1％、0.15％、0.2％、0.25％和0.3％(w/w)的添加量与碳酸氢钠进行复配,利用其替代传统的磷酸盐,探究其对乳化肉糜制品(以法兰...     

乳酸钙充填豆腐工艺技术研究

为了探明乳酸钙豆腐凝固剂应用参数对豆腐成品物理特性的影响,从豆腐凝固剂的应用参数:乳酸钙添加量、豆浆浓度(磨浆时干豆与水的比例),点浆温度及凝固温度和时间对成品凝胶强度、保水率和感官品质的影响进行研究。结果表明乳酸钙作豆腐凝固剂最佳应用参数:乳酸钙添加量0.2%(以豆浆体积计),豆浆浓度1:6(干豆/水=1/6,w/w),点浆温度30℃,凝固温度90℃,凝固时间30min。     

Design of a new cooked meat sausage enriched with calcium

The effect of calcium lactate, calcium gluconate and calcium citrate addition on the sensory properties of cooked meat sausages has been studied. Conventional and reduced-fat products (approx. 40%) were manufactured. The calcium salts studied were added in sufficient amounts to 100g of final product to give 20% and 25% of calcium RDA (1200mg). The energy value reduction in the final products was close to 30%. The instrumental measurement of colour and texture was performed. The presence of calcium salts only slightly decrease the lightness of the sausage and few changes were observed in relation to the texture. These were mainly related to increased hardness, observed at levels of calcium at 25% RDA. Sensory properties were estimated by a hedonic test. In general terms, they were very acceptable, which indicated that it is possible to manufacture conventional and reduced-fat cooked meat products enriched with calcium as a new healthier meat product.     

Use of calcium lactate with salt-phosphate and alginate-calcium gels in restructured pork rolls

The study was carried out to evaluate restructured pork rolls (RPR) prepared by using salt-phosphate and alginate-calcium gels with or without calcium lactate. Five types of RPR were prepared with: (1) 1.75% sodium chloride+0.3 phosphate (SP); (2) 1.75% sodium chloride+0.3% phosphate+0.3% calcium lactate (SPL); (3) 0.7% sodium alginate+0.125% calcium carbonate (AC); (4) 0.7% sodium alginate+0.3% calcium lactate (AL); and (5) 0.7% sodium alginate+0.125% calcium carbonate+0.3% calcium lactate (ACL). Cooking yield and cooked binding strength were significantly (P<0.05) higher in RPR containing salt and phosphate whereas pH and raw binding strength were significantly (P<0.05) higher in RPR containing alginate and calcium. Texture profile analysis indicated significantly (P<0.05) higher firmness and cohesiveness in RPR containing SPL and ACL. Sensory scores were significantly (P<0.05) higher in SP, SPL and ACL than AC and AL treatments. Results of storage studies indicated significant (P<0.05) increases in pH, TBARS numbers, metmyoglobin and microbial counts with storage in all the treatments. The results suggest that quality characteristics of raw product were better when RPR were prepared with alginate-calcium whereas quality characteristics of cooked product were better when rolls were prepared with salt-phosphate. Further, addition of calcium lactate improved sensory characteristics and shelf life of both alginate-calcium and salt-phosphate restructured pork rolls.     

Protein quality and antioxidant properties of soymilk derived from black soybean after in vitro simulated gastrointestinal digestion

Protein quality and antioxidant properties of soymilk derived from black soybean (eight varieties) in China were analysed following in vitro simulated gastrointestinal digestion (including dialysis). Soymilk from black soybean possessed high okara weight but low yield, protein content and sensory scores. The in vitro digestibility of protein in all black soymilk samples was higher than 60%, and the Shenmu black soybean exhibited the highest digestibility. Non-digested milk from the black soybean exhibited significantly high total phenolic content (TPC) (127.15–173.04 mg/100 mL), ferric-reducing antioxidant power (FRAP) (272.18–366.27 μmol L⁻¹) and DPPH free radical-scavenging activity (61.20–83.81%). These parameters were significantly lower in the non-digested soymilk than those in soymilk after gastric digestion but higher than those of soymilk in the dialysed fraction. Gastric digestion significantly increased bioactive compound levels released from black soymilk, and the bioaccessibility of phenolic compounds was 24.37–36.05%. Hence, black soymilk was sufficiently available for human absorption.     

Heat stability and calcium bioavailability of calcium-fortified milk

The objective of the study was to fortify calcium in cow milk in order to prepare calcium-enriched heat-stable milk for individuals who may not ingest enough calcium to meet minimum daily requirements. Therefore, cow milk was fortified with calcium at the rate of 50 mg/100 ml using three salts of calcium, viz. calcium chloride, calcium lactate and calcium gluconate. Upon addition of calcium salts, there was a marked drop in the pH and heat stability. However, restoration of pH to the original value with the addition of disodium phosphate stabilized the fortified milk and enhanced its heat stability over unfortified milk. The maximum in heat stability (HCT) of calcium-fortified cow milk samples remained slightly higher than that of unfortified milk. Metabolic study on mice revealed that calcium bioavailability of cow milk fortified with calcium lactate and calcium gluconate and stabilized with disodium phosphate was slightly higher than unfortified cow milk. Fortification of cow milk with calcium and restoration of its pH resulted in a calcium to phosphorus ratio still greater than one, which is considered ideal for retention of calcium in the body.