Effects of Frying Processes on the Nutritional and Sensory Characteristics of Different Mackerel Products

Optimizing Protein Profile, Flavor, Digestibility, and Microstructure: The Impact of Preheating and Reheating in Stir-Fried Chicken

Preheating and reheating play key roles in enhancing the nutritional and sensory qualities of stir-fried chicken. Thus, this study investigated the effect of preheating (D1) and reheating (D30) after 30 days of storage on the protein profile, lipid oxidation, flavor, texture, color, sensory properties, protein digestibility, and microstructure of household stir-fried chicken. Four doneness levels of preheating (medium rare (T1 = 62 °C), medium (T2 = 65 °C), medium well (T3 = 68 °C), and well done (T4 = 71 °C) and reheating (72 °C) were selected. Results revealed that preheating and reheating enhanced protein and lipid oxidation, while the unfolding of α-helix improved quality and digestibility. GC-MS identified 59 volatile compounds, including β-phellandrene and 1-octen-3-ol in preheating and anethole and benzaldehyde in reheating. Texture analysis showed decreased hardness, chewiness, and gumminess at T3. Lightness (L*) and redness (a*) were largely unaffected, except for the well done (D1T4, D30T4) doneness level, although yellowness (b*) increased with the increasing doneness levels. Sensory evaluation highlighted improved appearance, tenderness, and overall acceptability, particularly for D30T3. Digestibility enhanced with reheating, reaching up to 80% intestinal digestibility at D30T3. Microstructural analysis unveiled structural deformation, which was most pronounced at T4. Preheating followed by reheating enhanced meat quality attributes, with D30T3 emerging as the optimal doneness level for the industrial production of stir-fried chicken.

Analysis of the nutritional and fatty acid profile of sacha inchi tempe (Plukenetia volubilis L.) using different cooking methods

Background

Indonesia is experiencing food insecurity regarding soybean products. To address this challenge, sacha inchi (Plukenetia volubilis. L) has been identified as a potential raw material for making tempe due to the high levels of protein and polyunsaturated fatty acid (PUFA).

Objective

This research aimed to determine the potential of sacha inchi bean tempe on proximate content, PUFA, and the effect of different cooking methods.

Method

Water and ash content were analyzed using the gravimetric method. Moreover, protein, fat, carbohydrates, and fatty acid were evaluated using the Kjeldahl, Soxhlet, difference, and Gas Chromatography (GC) method.

Results

There were significant differences (p ≤ 0.05) in water content, ash content, protein, saturated fat, unsaturated, and PUFA in fermentation time. Fermentation increased protein (19.50-20.50%) while reducing water (30.26-28.51%) and PUFA (35.35-32.99%). Cooking methods significantly impacted fatty acids, with steaming retaining the highest PUFA (29.97%) and linolenic acid (14.63%), while frying increased saturated fat (11.24%).

Conclusion

Fermentation process in sacha inchi bean tempe could reduce the water content and saturated fat. This process also increased the ash, protein, and monounsaturated fat content, while the best cooking method was found to be steaming.

In Vitro Digestion of Vacuum-Impregnated Yam Bean Snacks: Pediococcus acidilactici Viability and Mango Seed Polyphenol Bioaccessibility

This study investigates the in vitro digestion of vacuum-impregnated yam bean snacks enriched with Pediococcus acidilactici and mango seed polyphenols, focusing on bacterial survival and polyphenol bioaccessibility. The snacks were prepared by vacuum impregnation (VI) with solutions containing either mango seed extract, P. acidilactici, or a combination of both, followed by dehydration. The antimicrobial activity of the treatments was assessed against pathogens, revealing limited effectiveness, likely due to insufficient concentrations of mango seed extract and the intrinsic resistance of the bacteria. VI of mango seed extract improved the total soluble phenols (TSP) content up to 400% and maintained the initial probiotic concentration (106 cell/mL). In vitro digestion was performed to simulate gastrointestinal conditions, measuring the stability of TSP and the survival of P. acidilactici. The results indicated that the viability of P. acidilactici fluctuated throughout the digestion process (106 to 104 log UFC/g), the polyphenols showed varying degrees of bioaccessibility (11 to 30%), and the TSP content in the intestinal fraction ranged from 1.95 to 6.54 mg GAE/g. The study highlights the potential of VI for incorporating functional components into plant-based snacks, though further optimization is necessary to enhance the stability of P. acidilactici and the effectiveness of the bioactive ingredients.

Cold plasma: A success road to mycotoxins mitigation and food value edition

Mycotoxins are common in many agricultural products and may harm both animals and humans. Dietary mycotoxins are reduced via physical, chemical, and thermal decontamination methods. Chemical residues are left behind after physical and chemical treatments that decrease food quality. Since mycotoxins are heat-resistant, heat treatments do not completely eradicate them. Cold plasma therapy increases food safety and shelf life. Cold plasma-generated chemical species may kill bacteria quickly at room temperature while leaving no chemical residues. This research explains how cold plasma combats mold and mycotoxins to guarantee food safety and quality. Fungal cells are damaged and killed by cold plasma species. Mycotoxins are also chemically broken down by the species, making the breakdown products safer. According to a preliminary cold plasma study, plasma may enhance food shelf life and quality. The antifungal and antimycotoxin properties of cold plasma benefit fresh produce, agricultural commodities, nuts, peppers, herbs, dried meat, and fish.

Development and Quality Characteristics of Jangjorim Prepared Using Long-Arm Octopus (Octopus minor) as an Elderly-Friendly Food

We prepared a long-arm octopus Jangjorim prototype (LOJP) by optimizing the ratio of ingredients for seasoning and establishing heat sterilization parameters. The optimal amounts of purified water (2.9-56.6%, A), starch syrup (0.3-37.8%, B), and soy sauce (25.5-71.5%, C) for the production of seasoning soy sauce were obtained using response surface analysis. The LOJP was prepared by combining A, B, and C under the optimal conditions and evaluated for consumer preferences and physicochemical, nutritional, and microbiological properties and compared with Korea's legal management standards for geriatric nutrition. The hardness of the LOJP produced using the optimal mixing ratio of purified water (51.2%, 154.0 g), starch syrup (29.3%, 308.0 g), and soy sauce (19.5%, 256.9 g) was 36.7 × 1000 N/m2. This value was lower than the hardness of raw octopus (2153.6 × 1000 N/m2) by 2116.9 × 1000 N/m2. It received the highest score (8.7) in the preference evaluation of older consumers. The LOJP was classified as level 2, allowing consumption through the gums of elderly consumers per Korea's food standards for the elderly. The LOJP was the product highly preferred by elderly consumers with chewing disorders due to its ease of intake and nutritional content.

Insights into application progress of seafood processing technologies and their implications on flavor: a review

Seafood tends to be highly vulnerable to spoilage and deterioration due to biochemical reactions and microbial contaminations, which requires appropriate processing technologies to improve or maintain its quality. Flavor, as an indispensable aspect reflecting the quality profile of seafood and influencing the final choice of consumers, is closely related to the processing technologies adopted. This review gives updated information on traditional and emerging processing technologies used in seafood processing and their implications on flavor. Traditional processing technologies, especially thermal treatment, effectively deactivate microorganisms to enhance seafood safety and prolong its shelf life. Nonetheless, these methods come with limitations, including reduced processing efficiency, increased energy consumption, and alterations in flavor, color, and texture due to overheating. Emerging processing technologies like microwave heating, infrared heating, high pressure processing, cold plasma, pulsed electric field, and ultrasound show alternative effects to traditional technologies. In addition to deactivating microorganisms and extending shelf life, these technologies can also safeguard the sensory quality of seafood. This review discusses emerging processing technologies in seafood and covers their principles, applications, developments, advantages, and limitations. In addition, this review examines the potential synergies that can arise from combining certain processing technologies in seafood processing.

Special Issue on “Feature Review Papers in Section Food Processes”

The successive growth of the population, degradation of the natural environment, and development of civilization diseases force a continuous increase in the production of high-quality food [...]