Characterization of citric acid/glycerol co-plasticized thermoplastic starch prepared by melt blending

A novel citric acid (CA)–glycerol co-plasticized thermoplastic starch (CGTPS) was prepared by melt blending. The CA content varies from 10% to 40 wt%. Result from Fourier Transform Infrared spectroscopy (FTIR) show that partial esterification occurred during blending. The degrees of substitution and esterification increased as the CA content increased. Results from intrinsic viscosity measurement, laser light scattering (LLS), and FTIR demonstrate the molecular weight of starch decreased as the CA percentage increased. The weight average molecular weight (M_w) of CGTPS with 20 wt% CA was only one-tenth of that without CA under the same processing conditions. Crystal type and crystallinity changes as a function of CA were recorded by X-ray diffraction (XRD). Thermal stability and the glass transition temperature (T_g) were detected by thermogravimetric (TG) and differential scanning calorimeter (DSC). Compared to the traditional GTPS, the novel CGTPS exhibits the special characters of partial esterification, low molecular weight and stronger interaction between starch and plasticizers. These new properties can be expected to prevent retrogradation, promote compatibility with polyesters, improve the processing ability, and adjust the degradation properties.     

Citric acid and maleic anhydride as compatibilizers in starch/poly(butylene adipate-co-terephthalate) blends by one-step reactive extrusion

Starch/poly(butylene adipate-co-terephthalate) films were obtained by one-step reactive extrusion using maleic anhydride (MA) and citric acid (CA) as compatibilizers. The mechanical, structural, optical and barrier properties of the films were analyzed when glycerol (GLY), CA and MA were added to the starch/PBAT (55:45, w/w) according to mixture design. FTIR analysis showed that CA and MA were able to promote esterification/transesterification reactions and that CA induced them more efficiently. When a greater proportion of compatibilizer (1.5 wt%) was used, the resulting films were more opaque and had a greater tensile strength. A greater proportion of GLY (10.0%, w/w) improved the elongation at the break of the films. The barrier properties to water vapor of the films were improved by high levels of CA (1.5 wt%) and intermediate levels of GLY (9.25 wt%). The inclusion of compatibilizers resulted in blends with improved properties, representing a potential replacement for non-biodegradable films.     

The effect of citric acid and microbial phytase on mineral utilization in broiler chicks

An experiment was conducted to study the effect of microbial phytase (Natuphos^® 500) supplementation in chicks fed different levels of available phosphorus (AP) and citric acid (CA) on performance, mineral retention (Ca, P, Mg, and Zn), bone and plasma minerals (Ca, P, Mg, and Zn), plasma total protein (TP), and serum aspartate aminotransferase (AST), alanine aminotransferase (ALT), alkaline phosphatase (ALP), lactate dehydrogenase (LDH) activities. Data were analyzed as a 2×4×2 factorial arrangement with two levels of AP (3.5 and 2.5 g/kg), four levels of phytase (0, 200, 400 and 600 U/kg), and two levels of citric acid (0 and 20 g/kg). The low-AP diets reduced performance. Phytase supplementation increased weight gain (up to 7% quadratically) and feed consumption (up to 5%). This response was statistically maximized by 200 U/kg phytase. Feed to gain ratio was not affected by phytase addition. Growth response to phytase was negatively affected by citric acid. Decreasing AP content in the diet increased Ca, P, and Mg retention, and reduced Zn retention. Phytase supplementation linearly increased Ca, P, and Zn retention by 9, 10 and 16%, respectively. Citric acid addition also increased Ca, P, and Zn retention by 3, 3 and 4%, respectively. Likewise, the decrease in AP content in the diet caused a reduction of tibia ash and tibia Zn, and an increase in tibia Ca and P contents. Phytase supplementation increased tibia ash (up to 4%), tibia Ca (up to 2%), P (up to 1%) and Zn (up to 4%) contents, tibia weight (up to 9%), and relative tibia (up to 19%) and liver (up to 13%) weights. Citric acid increased tibia ash (2%), and tibia Ca (2%) and P (2%) contents. Finally, by decreasing AP levels in the diet, plasma Ca and Zn concentrations as well as AST, ALP, and LDH activities were increased. However, plasma P and TP content were reduced. Phytase supplementation increased linearly plasma Ca (up to 4%), P (up to 12%), Mg (up to 10%), Zn (up to 22%) and TP (up to 7%) content, and serum AST (up to 22%), ALT (up to 40%), and LDH (up to 17%) activities, and reduced linearly serum ALP (up to 34%) activity. Citric acid addition increased plasma Ca, Mg, and Zn content by 10, 4, and 5%, respectively, and reduced ALP activity by 13%. In conclusion, these results indicated that the addition of phytase to maize and soyabean meal low-AP diets improved the performance and increased Ca, P, and Zn utilization in chicks. However, the inclusion of citric acid depressed the performance and caused an increase in mineral utilization. Growth response to phytase was negatively affected by citric acid.     

Effect of citric acid on aflatoxin degradation and on functional and textural properties of extruded sorghum

Sorghum contaminated with a total concentration of aflatoxin B₁ (AFB₁) and aflatoxin B₂ (AFB₂) at 140 ± 7.3 ng/g was extrusion-cooked in a single screw extruder. The temperature profile in the barrel sections of the extruder was 80–150–200 °C. The flour moisture content (M.C.) was adjusted at 200, 250 and 300 g/kg by means of aqueous citric acid at concentrations of 0, 0.5, 1, 2, 4 and 8N. The barrel temperature profile, in combination with the M.C. and the citric acid concentration, significantly affected the extent of aflatoxin reduction in the extruded sorghum. The recovered aflatoxin decreased with an increase in M.C. and acid concentration. The maximum percentage of aflatoxins degraded from cooking the milled sorghum ranged from 17 to 92%. Even when using a severe extrusion condition combined with high citric acid concentrations, acceptable product colour, viscosity, functional and textural properties were obtained.     

Study on injury effect of food additive citric acid on liver tissue in mice

To investigate the damaging effect and action mechanism of the food additive citric acid (CA) on mouse liver, 40 healthy male Kunming mice were randomly divided into control group (0.9 % saline), low CA dose (120 mg/kg), middle dose (240 mg/kg) and high dose groups (480 mg/kg). All experimental mice have received peritoneal injection of the corresponding reagent each week for 3 weeks. After 7 days since the third injection, morphological changes were observed by light microscope; activities of T-SOD, glutathione peroxidase (GSH-Px), caspase-3, and contents of hydrogen peroxide (H₂O₂) and malonyldialdehyde (MDA) in the liver were evaluated using the corresponding assay kits; DNA fragmentation was assayed using agarose gel electrophoresis. Microscopical detection showed a series of hispathological changes in mouse livers treated with CA, such as indiscriminate liver cell cord, blood clot in central veins, and lymphocyte infiltrating. Biochemical examination suggested the gradually but moderately reduced T-SOD activity and elevated H₂O₂ level with the increase of CA dose (P > 0.05), and the gradually reduced GSH-Px activity and increased MDA content depending on graded doses with a significant difference (P < 0.05) between the high dose group and the control group. According to cell apoptosis assays, caspase-3 activity were significantly higher in all treatment groups than in the control (P < 0.05) in a dose-dependent manner. Contrasting to the control, characteristic DNA laddering was observed when injected with any of the three graded doses. It can be concluded that certain concentrations of CA cause oxidative damage of the liver by means of the decrease of antioxidative enzyme activities, thus resulting in MDA level elevation and DNA fragmentation inducing active caspase-3.     

The influence of intracellular pH of spores on citric acid production by Aspergillus niger

The spores with different intracellular pH values were produced by cultivating Aspergillus niger on potato-dextrose agar at different pH_e values. High citric acid production is obtained using spores with the highest initial pH values (pH_i) around 7.5. After a drop of intracellular pH during germination of spores of about 0.7 units, the conditions for highest rate of metabolic flow through the glycolytic pathway were achieved only by the mycelium grown out of spores with the highest pH_i, since a very narrow pH optimum of 6-phosphofructokinase activity has been found around 7.5.     

Structural characterization and properties of starch/konjac glucomannan blend films

In this work, a series of glycerol-plasticized pea starch/konjac glucomannan (ST/KGM) blend films was prepared by a casting and solvent evaporation method. The structure, thermal behavior, and mechanical properties of the films were investigated by means of Fourier Transform Infrared Spectroscopy, wide-angle X-ray diffraction, scanning electron microscopy, differential scanning calorimetry, and tensile testing. The results indicated that strong hydrogen bonding formed between macromolecules of starch (ST) and konjac glucomannan (KGM), resulting in a good miscibility between ST and KGM in the blends. Compared with the neat ST, the tensile strength of the blend films were enhanced significantly from 7.4 to 68.1 MPa with an increase of KGM content from 0 to 70 wt%. The value of elongation at break of the blend films was higher than that of ST and reached a maximum value of 59.0% when the KGM content was 70 wt% and 20% of glycerol as plasticizer. The incorporation of KGM into the ST matrix also led to an increase of moisture uptake for the ST-based materials. The structure and properties of pea starch-based films were modified and improved by blending with KGM.     

Influence of thickness on the mechanical properties for starch films

The aim of the present study was to investigate some mechanical properties of starch films. Starch is a natural common polymer in nature and the use of natural materials is increasing in the industries. In this study, the mechanical properties of starch plasticized with 30 parts by weight, of glycerol, are investigated. For the mechanical testing films of different thickness were used, the thickness varied between 0.5 and 2.5 mm. T_g was measured with a differential scanning calorimeter and with a dynamical mechanical analysis. The starch films were tested in tension and characterised in terms of stiffness, strength and failure strain. Fracture toughness was measured by single edge notch tests. Both stiffness and strength showed a strong dependence on film thickness, stronger then expected from linear fracture mechanics. This can be due to the different molecule orientation in the films, and due to the crystallinity of the films.     

Influence of kepok banana bunch as new cellulose source on thermal,mechanical, and biodegradability properties of Thai cassava starch/polyvinyl alcohol hybrid-based bioplastic

Bioplastics were developed to overcome environmental problems that are difficult to decompose in the environment. This study analyzes Thai cassava starch-based bioplastics' tensile strength, biodegradability, moisture absorption, and thermal stability. This study used Thai cassava starch and polyvinyl alcohol (PVA) as matrices, whereas Kepok banana bunch cellulose was employed as a filler. The ratios between starch and cellulose are 10:0 (S1), 9:1 (S2), 8:2 (S3), 7:3 (S4), and 6:4 (S5), while PVA was set constant. The tensile test showed the S4 sample's highest tensile strength of 6.26 MPa, a strain of 3.85%, and a modulus of elasticity of 166 MPa. After 15 days, the maximum soil degradation rate in the S1 sample was 27.9%. The lowest moisture absorption was found in the S5 sample at 8.43%. The highest thermal stability was observed in S4 (316.8°C). This result was significant in reducing the production of plastic waste for environmental remediation.     

The kinetics of simultaneous glucose and fructose uptake and product formation by Aspergillus niger in citric acid fermentation

The kinetics of substrate uptake and product formation in the process of citric acid accumulation by Aspergillus niger on sucrose as a sole carbon source are presented. The experiments are aimed at studying if glucose and fructose obtained from the hydrolysis of sucrose are equivalent carbon sources for A. niger and how the presence of the two different carbon substrates might influence the citric acid formation process. Beet sugar was used as a sole carbon source in the first series of experiments conducted in two types of bioreactors: stirred tank and air-lift. The fructose uptake rate was significantly lower than the glucose uptake rate in the late idiophase. A substrate utilisation breakpoint occurred when a large amount of citric acid was accumulated in the fermentation broth. A similar phenomenon was also detected in repeated fed-batch fermentation. This phenomenon was confirmed by the second series of parallel shake culture runs, in which fungal growth and citric acid accumulation by A. niger was simultaneously tested on the media containing the following carbon sources: sucrose, glucose and fructose, with and without addition of concentrated citric acid solution. Finally, it was shown that high concentration of citric acid strongly depleted fructose uptake rate.     

Mechanical and water barrier properties of starch/PVA composite films by adding nano-sized poly(methyl methacrylate-co-acrylamide) particles

The aim of this work is to prepare starch/PVA composite films added nano-sized poly(methyl methacrylate-co-acrylamide) (PMMA-co-AAm) particles and to investigate the mechanical properties, water barrier properties, and soil burial degradation for the films. Composite films were prepared by using corn starch, polyvinyl alcohol (PVA), nano-sized PMMA-co-AAm particles, and additives, i.e., glycerol (GL), xylitol (XL), and citric acid (CA). Nano-sized PMMA-co-AAm particles were synthesized by emulsion polymerization. The results of the evaluation of properties for prepared films indicated that compared with films without PMMA-co-AAm particles, the mechanical properties and water resistance were improved up to 70-400% by the addition of nano-sized PMMA-co-AAm. In addition, the results of the soil burial biodegradation revealed that films added PMMA-co-AAm particles were degraded by about 45-65% after 165 days.     

Physiological aspects of free and immobilized Aspergillus niger cultures producing citric acid under various glucose concentrations

Similarities and differences between cultures of free and immobilized Aspergillus niger were identified under various glucose concentrations. Growth and citric acid production rates were compared, and the macro-morphology and fine structure of the mycelia examined to determine which parameters were significant in the production of citric acid. With free cultures the diameter of pellets was inversely related to glucose concentration, while biomass levels were lower for immobilized cultures than the equivalent free cultures. Rates of citric acid production were higher with immobilized mycelium, especially at higher glucose levels. The morphology that characterized high citric acid productivity was that of swollen hyphal tips which were seen at concentrations over 100 kg/m³ glucose in both free and immobilized mycelium. Although there is a characteristic morphology associated with high productivity it does not account for the difference observed between free and immobilized mycelia. The increased glucose uptake and productivity was not due to an increased surface area either, since the immobilized system was slightly lower in total surface area than the equivalent free cultures. The major difference was in the mean diffusion path in the two systems.     

Electrospun poly-l-lactic acid/polyvinyl alcohol nanofibers improved insulin-producing cell differentiation potential of human adipose-derived mesenchymal stem cells

Combination of adipose-derived mesenchymal stem cells (ADSCs) and synthetic materials in terms of pancreatic tissue engineering can be considered as a treatment of diabetes. This study aimed to evaluate the differentiation of human ADSCs to pancreatic cells on poly-l -lactic acid/polyvinyl alcohol (PLLA/PVA) nanofibers as a three-dimensional (3D) scaffold. Mesenchymal stem cells (MSCs) were characterized for mesenchymal surface markers by flow cytometry. Then ADSCs were seeded on 3D scaffolds and treated with pancreatic differentiation medium. Immunostaining assay showed that ADSCs were very efficiently differentiated into a relatively homogeneous population of insulin-producing cells. Moreover, real-time RT-PCR results revealed that pancreas-specific markers were highly expressed in 3D scaffolds compared with their expression in tissue culture plates and this difference in expression level was significant. In addition, insulin and C-peptide secreted in response to varying concentrations of glucose in the 3D scaffold group was significantly higher than that in 2D culture. The results of the present study confirmed that PLLA/PVA scaffold seeded with ADSCs could be a suitable option in pancreatic tissue engineering.     

Improved production of citric acid by Yarrowia lipolytica using oleic acid as the oxygen‐vector and co‐substrate

Yarrowia lipolytica is able to secrete large amounts of citric acid (CA), which is greatly affected by the dissolved oxygen concentration (DOC) in the fermentation medium. In this study, oleic acid was selected as oxygen‐vector to improve DOC during CA fermentation. When 2% (v/v) of oleic acid was added to the culture broth, higher DOC (>42.1%) was determined throughout the CA synthesis phase. The yield of CA reached a maximum of 32.1 g/L (25.4% higher than the control) and the biomass was 8.8 g/L. The substrate uptake rate, products formation rate and key enzyme activities were also determined, and the results indicated that CA synthesis was strengthened with oleic acid addition. Furthermore, it was detected that oleic acid could be assimilated by the cells, which means that oleic acid could be served both as oxygen‐vector and co‐substrate for CA synthesis by Y. lipolytica. In a bioreactor with working volume of 3 L, the highest concentration of CA reached to 36. 4 g/L in the presence of 2% (v/v) oleic acid after 192 h of fermentation. These results confirmed that oleic acid could be applied in the large‐scale production of CA by Y. lipolytica.     

The plasticizing mechanism and effect of calcium chloride on starch/poly(vinyl alcohol) films

Starch/poly(vinyl alcohol) (PVA) films were prepared with calcium chloride (CaCl(2)) as the plasticizer. The micro morphology of pure starch/PVA film and CaCl(2) plasticized starch/PVA film was observed by scanning electron microscope. The interaction between CaCl(2) and starch/PVA molecules was investigated by Fourier transform infrared spectroscopy. The influence of CaCl(2) on the crystalline, thermal and mechanical properties of starch/PVA films was studied by X-ray diffraction, differential scanning calorimetry, thermogravimetric analysis, and tensile testing, respectively. The results indicated that CaCl(2) could interact with starch and PVA molecules and then effectively destroy the crystals of starch and PVA. Starch/PVA films plasticized with CaCl(2) became soft and ductile, with lower tensile strength and higher elongation at break compared with pure starch/PVA film. The water content of starch/PVA film would increase with the addition of CaCl(2). This is an important cause of the plasticization of CaCl(2) on starch/PVA film.     

On a hypothetical generational relationship between HCN and constituents of the reductive citric acid cycle

Encouraged by observations made on the course of reactions the HCN-tetramer can undergo with acetaldehyde, I delineate a constitutional and potentially generational relationship between HCN and those constituents of the reductive citric acid cycle that are direct precursors of amino acids in contemporary metabolism. In this context, the robustness postulate of classical prebiotic chemistry is questioned, and, by an analysis of the (hypothetical) reaction-tree of a stepwise hydrolysis of the HCN-tetramer, it is shown how such a non-robust chemical reaction platform could harbor the potential for the emergence of autocatalytic cycles. It is concluded that the chemistry of HCN should be revisited by focussing on its non-robust parts in order to demonstrate its full potential as one of the possible roots of prebiotic self-organizing chemical processes.     

Influence of impeller speed on citric acid production and selected enzyme activities of the TCA cycle

Summary The effect of impeller speed on citric acid production and selected enzyme activities of the TCA cycle was studied. The highest yield of citric acid (28 g/l) was obtained in culture agitated at lower speed (300 rpm). The activity of citrate synthase decreased with the increase of speed of agitation, while the activity of aconitase and isocitrate dehydrogenase increased with the increase in agitation speed.     

The effect of mutant genes at the r, rb, rug3, rug4, rug5 and lam loci on the granular structure and physico-chemical properties of pea seed starch

The granular structure and gelatinisation properties of starches from a range of pea seed mutants were studied. Genes which affect the supply of substrate during starch synthesis (rb, rug3, rug4) affected the total crystallinity and possibly increased the content of A polymorphs in the starch. Conversely, genes directly affecting the synthesis of starch polymers (r, rug5, lam) increased the content of B polymorphs, but had a minimal effect on total crystallinity. During gelatinisation, starches from the rb, rug3, rug4 and lam mutants had narrow endothermic peaks which were similar to starch from the wild-type, although all the starches had different peak temperatures and enthalpy changes. Starches from r and rug5 mutants were very different to all other starches, having a very wide transition during gelatinisation. In addition, the amylopectin in starch from these mutants had altered chain lengths for those parts of the polymer which form the ordered structures in the granule.