Nakako Katsuno

Water-soluble extracts from defatted sesame seed flour show antioxidant activity in vitro

Defatted white and gold sesame seed flour, recovered as a byproduct after sesame oil extraction, was extracted with 70% ethanol to obtain polar-soluble crude extracts. The in vitro antioxidant activity of the extract was evaluated by DPPH free radical scavenging activity and oxygen radical absorbing capacity (ORAC). The polar-soluble crude extracts of both sesame seed types exhibited good antioxidant capacity, especially by the ORAC method with 34,720 and 21,700 μmol Trolox equivalent/100g of white and gold sesame seed extract, respectively. HPLC, butanol extraction, and UPLC-MS analyses showed that different compounds contributed to the antioxidant activity of the polar-soluble crude extracts. Sesaminol glycosides were identified in the butanol-soluble fractions; whereas, purified water-soluble fraction contained ferulic and vanillic acids. This study shows that hydrophilic antioxidants in the purified water-soluble fraction contributed to the antioxidant activity of white and gold sesame seed polar-soluble crude extracts.

Airflow resistance measurement for a layer of granular material based on the Helmholtz resonance phenomenon

A Helmholtz resonance technique was employed to predict the airflow resistance of layers of granular materials, namely glass beads, brown rice, soybean, adzuki beans, and corn kernels. Each granular sample was placed on the tube mouth of an open-type Helmholtz resonator. The resonant frequency was determined by measuring the electric impedance of a loudspeaker that was installed in the resonator and driven by a chirp signal linearly sweeping from 90 to 220 Hz for 6.0 s. For a changing sample layer thickness, the resonant frequency was measured, and the specific airflow resistance was calculated by measuring the static pressure drop required for N2 gas to flow through the layer at a constant velocity of 0.042 m/s. When the thickness of the layer was fixed, the Helmholtz resonant frequency decreased as the specific airflow resistance increased, regardless of the kind of granular material. Graphical Abstract A method of measuring the airflow resistance of a grain layer using an open-type Helmholtz resonator was proposed. The Helmholtz resonant frequency decreased as the specific airflow resistance increased, regardless of the kind of granular material.

The Relationship between the Fracture Properties and the Tissue Structure of Roasted Sesame Seeds

Using seven varieties of roasted sesame seeds, we examined the relationship between the fracture properties and the internal structure of roasted seeds. Analysis of fracture properties revealed significant differences across the samples in terms of fracture force and fracture strain at the biggest fracture point, and in the number of small fractures (p<0.05). Analysis of the cross-sectional structure revealed significant differences across the samples in the size of the void at the center of the sesame seed and in the overall thickness of the seed (p<0.05). Strong negative correlations were found for the center-void-to-seed thickness ratio against fracture force and fracture strain at the biggest fracture point. Moreover, fracture properties and cross-sectional structure were strongly correlated with sensory evaluations of crispness. Hence we concluded that the presence of a void in the central area of a seed decreases the necessary fracture force, resulting in a crispy texture.

Effects of Dual Modification with Succinylation and Annealing on Physicochemical, Thermal and Morphological Properties of Corn Starch

The objective of this study was to investigate the effects of annealing, succinylation, and a dual modification process (succinylation–annealing) on the physicochemical, thermal, and morphological properties of corn starch. Specifically, the properties of interest were the water-binding capacity (WBC), swelling power, paste clarity, solubility, pasting properties, stability ratio, and thermal and morphological characteristics. The dual modification process increased the physicochemical properties (WBC, swelling power, peak viscosity, and paste clarity) and increased the gelatinization temperature and gelatinization enthalpy (∆H), but had no effect on the morphological properties and X-ray diffraction patterns. A comparison of samples, made using each of the processes, showed that dual modification increased the stability ratio (more stable viscosity under thermal and shear stress), which was 0.69 for dual modified starch, compared with 0.64, 0.58 and 0.44 for native, succinylated, and annealed starches, respectively. The findings of the present study are of potential use in the food industry.

Kinetic Analysis of Freeze-Thaw Stability of Mayonnaise

Kinetic analysis was used to study the destabilization of mayonnaise by focusing on the fat crystals. Mayonnaise prepared from rapeseed oil and soybean oil was stored at temperatures ranging from −20 to −40 °C. The destabilization kinetic parameters were measured by observing oil separation over time. The destabilization rate constant, kd, increased with decreasing temperature. The highest value of kd was 1.28 × 10−3 min−1 at −40 °C for rapeseed oil mayonnaise (RoM) and the lowest was 1.95 × 10−6 min−1 at −20 °C for soybean oil mayonnaise (SoM). At each temperature, the kd value in RoM was higher than that in SoM. However, the order of destabilization, n, followed no specific pattern. The crystallization rate constant, Kc, and Avrami constant, n, were calculated using microscopic images of the fat crystals. The increase in crystallization kinetic parameters with decreasing temperature revealed changes in crystal behavior. Both the destabilization rate constant, kd, and the crystallization rate constant, Kc, depended on the temperature. This temperature dependency behavior showed a correlation between kd and Kc, suggesting that the destabilization rate depended on the rate of growth of fat crystals during the freeze-thawing of mayonnaise.

The effects of water absorption and roasting conditions on fracture properties and internal structure of sesame seeds

We investigated the effects of soaking, residence time before roasting and roasting conditions on the fracture properties and structure of the cross-section of sesame seeds. Soaking time affected only the size of the side voids of the seed cross-section. The fracture force and strain of the roasted seeds decreased as residence time increased. The center void of the roasted seeds, important for seed crispness increased as residence time increased. In contrast, the side void of the roasted seeds only increased with residence time during the first 10 min. Seeds roasted at higher temperatures had smaller fracture forces and larger central voids than those roasted at lower temperatures. During roasting at 300 °C, the fracture force and strain decreased as the center void ratio increased. Overall, both a sufficient time for moisture diffusion in the seeds and a high roasting temperature were necessary to produce crisp roasted seeds. Graphical abstract We investigated the effect of soaking, residence time before roasting, and roasting conditions on the structure of the cross-section of sesame seeds.

White sesame seed water-soluble fraction enhances human neuroblast cell viability via an anti-apoptotic mechanism

Defatted sesame seed flour is recovered as a byproduct after oil extraction and is usually considered a waste product. Previously, we showed that water-soluble fractions purified from defatted white and gold sesame seed flour exhibited good antioxidant activity in vitro. We also identified ferulic acid and vanillic acid as the bioactive antioxidants in both white and gold sesame seed water-soluble fractions (WS-wsf and GS-wsf, respectively). In this study, we hypothesized that WS-wsf and GS-wsf may have neuroprotective effects due to their antioxidant potential. Treatment with WS-wsf for 24 hours enhanced human neuroblastoma SH-SY5Y cell viability and proliferation, while GS-wsf, ferulic acid, and vanillic acid did not show similar effects. In addition, WS-wsf (1-3 mg/mL) significantly and dose-dependently protected SH-SY5Y cells against camptothecin-induced apoptosis, suggesting the involvement of an anti-apoptosis mechanism in the neuroprotective effects of WS-wsf. In fact, treatment with WS-wsf significantly decreased the mRNA expression levels of pro-apoptotic Bax and p53 genes. WS-wsf also enhanced Bcl-2 protein level and Akt phosphorylation. Taken together, this study showed that WS-wsf has interesting neuroprotective potential via an anti-apoptotic mechanism, which is independent from its antioxidant capacity.