Wheat germ stabilization by infrared radiation

Gili, Renato D.; Palavecino, Pablo Martín; Penci, María Cecilia; Martínez, Marcela Lilian; Ribotta, Pablo Daniel

doi:10.1007/s13197-016-2437-z

Cited by 40 publications

(33 citation statements)

References 27 publications

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“…Therefore, a process to stabilize the wheat germ has to be devised. Different techniques can be found: application of heat (thermal processes) (Ferrara et al, 1991;Gili et al, 2017), irradiation (Jha et al, 2013), dehydration processes (Rothe, 1963) or else by chemical preservation, as, for instance by adding some chemical compound as antioxidant (Barnes, 1948) or alkalis (Grandel, 1959). Thermal processes have demonstrated to be effective to stabilize wheat germ, one of these, fluidization, provides an intense heat and mass transfer between material and the hot air, which imply a uniform treatment to the bed being fluidized.…”

Section: Introductionmentioning

confidence: 99%

Physical characterization and fluidization design parameters of wheat germ

Gili

Irigoyen

Penci

et al. 2017

Journal of Food Engineering

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Wheat germ is the embryo of de wheat seed, it contains a high tocopherol and protein content, and high quality proteins and fatty acids. Also, wheat germ has a considerable enzymatic activity that limits its shelf life. The aims of the study were to physically and sorptionally characterize wheat germ particles, select the more convenient model to describe the relationship between moisture content and water activity of wheat germ and to determine their design parameters of thermal fluidization process with air. The principal axes of the particle were measured by image analysis, and their dimensions and geometric parameters were calculated. Four isotherm models were fitted to experimental data. GAB model was the more accurate to explain the experimental data. The fixed bed density and the void fraction were measured. The fluid-dynamic studies permitted to determine laminar (277.46 ± 17.48) and turbulent (7.79 ± 0.69) coefficients of the Ergun equation and the minimum fluidization velocity (0.35 ± 0.02 m/s).

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Section: Introductionmentioning

confidence: 99%

Physical characterization and fluidization design parameters of wheat germ

Gili

Irigoyen

Penci

et al. 2017

Journal of Food Engineering

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“…The lines of the dehydration time and heating time were almost parallel lines. In the meantime, the water activity of the WG could be maintained within a target range of 0.3 ± 0.1, which was able to attain the condition of the WG stored at a water activity of 0.4-0.5, so as to avoid spoilage from the enzymatic activity and lipid quality losses [16]. From a cost perspective, it had an effective drying performance in a batch process when the WG loading increased.…”

Section: Effect Of Wg Loading On Dehydration Time Heating Time and Wamentioning

confidence: 99%

“…Stabilization methods for preventing WG spoilage can be grouped into the following three types: physical, chemical, and biological approaches [2]. The most common physical stabilization methods can be categorized as a number of different treatments, including fermentation [6,7,10,11], microwave [12][13][14], gamma irradiation [15], infrared radiation [16,17], and fluidization [11,[18][19][20][21], which limit the WG enzymatic activity. Controlling the water activity (WA) or moisture content (MC) of WG within a desired range is an important factor when preventing WG spoilage [18].…”

Section: Introductionmentioning

confidence: 99%

Effect of Loading on Wheat Germ Drying in a Batch Fluidized Bed for Industrial Production

Chan

Kuo

2019

Processes

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A high loading production in the manufacturing process of wheat germ (WG) drying is important for reducing the production costs. From a cost perspective, the drying performance become more effective in a batch process when the loading increases. The objective of this investigation was to evaluate the drying performance of WG with different loadings, from 2 to 9 kg, at 120 °C in a fluidized bed dryer. The moisture content, according to the American Association of Cereal Chemists (AACC) method, and the water activity using a thermal hygrometer were measured. The absolute humidity, diffusivity of moisture, and thermal efficiency were analyzed using a mathematical model. An analysis of the dehydration flux demonstrated a linear relationship between dehydration time and WG loading using a fluidized bed dryer. The kinetics of WG drying were observed with a simple exponential model used to match the experimental observation, indicating that the drying rate constant decreases with an increase in WG loading. A linear relationship was obtained between the WG loading and heating time (heating time = −0.212 + 0.577 × WG loading). On this basis, a process optimization was developed for industrial operation, and for predicting the drying performance of WG for industrial-scale production.

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“…Wheat germ (WG) is an important by‐product of the wheat milling industry that makes up about 2–3% of the kernel and it is valuable for human nutrition . However, the shelf life of the germ is adversely affected by the high oil content due to oxidative and hydrolytic enzyme activities.…”

Section: Introductionmentioning

confidence: 99%

“…8 Wheat germ (WG) is an important by-product of the wheat milling industry that makes up about 2-3% of the kernel and it is valuable for human nutrition. 9 However, the shelf life of the germ is adversely affected by the high oil content due to oxidative and hydrolytic enzyme activities. In order to eliminate this negative situation and extend the shelf life of the raw germ, various processes are applied, such as defatting process, heat treatment applications or using some chemical substances.…”

Section: Introductionmentioning

confidence: 99%

Investigating release kinetics of phenolics from defatted wheat germ incorporated chewing gums

2019

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BACKGROUND Wheat germ (WG) is a valuable by‐product of the commercial milling industry and is used as a functional ingredient in various foods. Therefore, in this study, it is aimed to utilize defatted wheat germ (DWG) (1%, 3%, 5%, 10%) in chewing gum formulation, which is a different food matrix besides the conventional structures, and investigate the release kinetics of phenolics from DWG incorporated chewing gums with a new centrifugation method. RESULTS According to the results, it was observed that DWG was a good source of total phenolics (2254.15 mg GAE kg−1). Based on the results obtained from texture profile and sensory analyses, DWG addition did not cause any reverse effect on the chewing gum texture. Centrifugation method was used to indirectly simulate the physical effects of the chewing process. In particular, after 5 min of chewing and centrifugation, phenolic release levels were 59.07% and 59.41%, respectively. The model used in the previous studies showed a better correlation than Korsmeyer–Peppas model for ABTS (2,2′‐azino‐bis‐(3‐ethylbenzothiazoline‐6‐sulphonic acid), CUPRAC (cupric ion reducing antioxidant capacity), and DPPH (2,2‐diphenyl‐1‐picrylhydrazyl) assay results. CONCLUSION The results showed that phenolics release from gum base polymer matrix might be dominated by erosion of matrix due to chewing action. Similar phenolic release kinetics were obtained by centrifugation and chewing methods. Therefore, centrifuge equipment can be used to simulate the chewing forces acting on the gum when optimization is performed. © 2019 Society of Chemical Industry

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Wheat germ stabilization by infrared radiation

Cited by 40 publications

References 27 publications

Physical characterization and fluidization design parameters of wheat germ

Physical characterization and fluidization design parameters of wheat germ

Effect of Loading on Wheat Germ Drying in a Batch Fluidized Bed for Industrial Production

Investigating release kinetics of phenolics from defatted wheat germ incorporated chewing gums

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