Previous
Aim:
The study evaluated the influence of different wall materials on the bioactive compounds in encapsulated Justicia carnea leaves extract.
Methods:
Combinations of gelatin with maltodextrin or starch, and gum arabic with maltodextrin or starch were prepared in ratios of 1:3 to create four types of wall matrices. Each combination was dissolved in water to obtain 20% w/v solutions. J. carnea leaves were extracted, concentrated, and the resulting extract added to the wall material at a ratio of 1:2 and homogenized. Encapsulation was achieved through homogenization at 12,000 rpm for 30 min, followed by freeze drying. The resulting microcapsules were characterized using a scanning electron microscope (SEM) and differential scanning calorimeter (DSC). Physicochemical properties, pigment concentrations, and micronutrient compositions of the microcapsules were also evaluated using standard methods.
Results:
Carotenoids, chlorophyll, and anthocyanin were significantly higher (P ≤ 0.05) in the sample containing starch and gelatin [gelatin + starch + core (DGES)] as the wall matrix compared to other samples. Vitamins E and D, calcium (Ca), and manganese (Mn) in sample gum arabic + starch + core (CGS; blend of gum arabic starch) and sample DGES were not significantly different from each other. DGES exhibited significantly lower (60.19%) solubility than others (60.48–70.86%) and the highest (76.72%) encapsulation efficiency. SEM analysis revealed smooth surfaces and mostly polyhedral shapes, with particle sizes ranging from 10.534–14.159 μm across all samples. DSC analysis revealed that the particles are endothermic and amorphous in nature, except for the CGS sample, which became semi-crystalline at about 203.2°C.
Conclusions:
The study showed that a composite wall material comprising starch and gelatin demonstrates enhanced effectiveness in the encapsulation of J. carnea leaves bioactive compounds.
Aim:
The study evaluated the influence of different wall materials on the bioactive compounds in encapsulated Justicia carnea leaves extract.
Methods:
Combinations of gelatin with maltodextrin or starch, and gum arabic with maltodextrin or starch were prepared in ratios of 1:3 to create four types of wall matrices. Each combination was dissolved in water to obtain 20% w/v solutions. J. carnea leaves were extracted, concentrated, and the resulting extract added to the wall material at a ratio of 1:2 and homogenized. Encapsulation was achieved through homogenization at 12,000 rpm for 30 min, followed by freeze drying. The resulting microcapsules were characterized using a scanning electron microscope (SEM) and differential scanning calorimeter (DSC). Physicochemical properties, pigment concentrations, and micronutrient compositions of the microcapsules were also evaluated using standard methods.
Results:
Carotenoids, chlorophyll, and anthocyanin were significantly higher (P ≤ 0.05) in the sample containing starch and gelatin [gelatin + starch + core (DGES)] as the wall matrix compared to other samples. Vitamins E and D, calcium (Ca), and manganese (Mn) in sample gum arabic + starch + core (CGS; blend of gum arabic starch) and sample DGES were not significantly different from each other. DGES exhibited significantly lower (60.19%) solubility than others (60.48–70.86%) and the highest (76.72%) encapsulation efficiency. SEM analysis revealed smooth surfaces and mostly polyhedral shapes, with particle sizes ranging from 10.534–14.159 μm across all samples. DSC analysis revealed that the particles are endothermic and amorphous in nature, except for the CGS sample, which became semi-crystalline at about 203.2°C.
Conclusions:
The study showed that a composite wall material comprising starch and gelatin demonstrates enhanced effectiveness in the encapsulation of J. carnea leaves bioactive compounds.
DOI: https://doi.org/10.37349/eff.2025.101089
Aim:
Protein structure-function relationship understanding is very important to the study of protein chemistry. In this study, we determined the 3D structure of glutelin type-B 5-like (GTB) protein from proso millet and investigated the effects of simulated temperature and static electric field on GTB protein’s secondary structures, solvent accessibility surface area (SASA), the radius of gyration (Rg), root mean square deviation (RMSD), and total dipole moment with the view to elucidate its structural behavior under different simulated processing stresses.
Methods:
This study leveraged homology modeling to determine the 3D structure of the GTB protein from proso millet. We further explored in silico modeling using molecular dynamic modeling tools to study the behavior of the GTB protein structure under simulated temperatures and static electric field processing stresses.
Results:
The 3D protein structure of GTB is majorly a protomer that comprises three monomers with one jelly-like β-barrel and two extended helix domains, and the remaining 35% as coils. From the molecular dynamic simulation, the secondary structure of the protein was not disrupted at temperatures between 300–400 K and static electric fields between 0.1–3 V/nm, albeit with the loss of a few amino acid residues. The RMSD increased significantly with temperature, static electric field, and simulation time increase. However, the Rg and SASA decreased for the same conditions, suggesting that the protein structure is compacting during thermal and electrical treatment.
Conclusions:
We concluded that low levels of simulated temperature and low levels of the electric field may cause a temporary reversible conformational change of GTB protein, not enough to cause a major disruption as may be expected during empirical processing of protein. To achieve greater disruption that would mimic protein denaturation, there is a need for in silico study of protein molecules under more aggressive simulated stressors for a longer time, and consideration given to protein structure development from AlphaFold3.
Aim:
Protein structure-function relationship understanding is very important to the study of protein chemistry. In this study, we determined the 3D structure of glutelin type-B 5-like (GTB) protein from proso millet and investigated the effects of simulated temperature and static electric field on GTB protein’s secondary structures, solvent accessibility surface area (SASA), the radius of gyration (Rg), root mean square deviation (RMSD), and total dipole moment with the view to elucidate its structural behavior under different simulated processing stresses.
Methods:
This study leveraged homology modeling to determine the 3D structure of the GTB protein from proso millet. We further explored in silico modeling using molecular dynamic modeling tools to study the behavior of the GTB protein structure under simulated temperatures and static electric field processing stresses.
Results:
The 3D protein structure of GTB is majorly a protomer that comprises three monomers with one jelly-like β-barrel and two extended helix domains, and the remaining 35% as coils. From the molecular dynamic simulation, the secondary structure of the protein was not disrupted at temperatures between 300–400 K and static electric fields between 0.1–3 V/nm, albeit with the loss of a few amino acid residues. The RMSD increased significantly with temperature, static electric field, and simulation time increase. However, the Rg and SASA decreased for the same conditions, suggesting that the protein structure is compacting during thermal and electrical treatment.
Conclusions:
We concluded that low levels of simulated temperature and low levels of the electric field may cause a temporary reversible conformational change of GTB protein, not enough to cause a major disruption as may be expected during empirical processing of protein. To achieve greater disruption that would mimic protein denaturation, there is a need for in silico study of protein molecules under more aggressive simulated stressors for a longer time, and consideration given to protein structure development from AlphaFold3.
DOI: https://doi.org/10.37349/eff.2025.101088
Aim:
The germination of maize leads to many physiological changes in the plant. These changes are responsible for the appearance, disappearance, and variation in concentration of numerous compounds, including secondary metabolites. The aim of this study was to compare the secondary metabolite profile of two maize varieties germinated under controlled optimal conditions.
Methods:
To achieve this, the Atp-Y variety was soaked for 25.12 h at 25.54˚C in the presence of 0.5238% plant ash, germinated for 144.37 h, and matured for 37.65 h. For the Coca-sr variety, the grains were soaked for 1.608 h at 36.63˚C in the presence of 1.1093% plant ash. Germination and ripening took 144.37 h and 27.07 h, respectively. The compounds were extracted in methanol (HPLC grade) before being injected into a gas chromatography-mass spectrometry (GC-MS) equipped with an Rtx-5MS column for metabolite profiling.
Results:
These analyses showed that variety and optimum germination conditions influenced the secondary metabolite profile. This profiling identified 15 and 12 compounds in the Atp-Y and Coca-sr varieties, respectively. Of these compounds, 8 were identified in both varieties. The groups of compounds identified were fatty acids, esters, ketones, phenols, polyols, alcohols, sterols, and unclassified substances. Fatty acids were the most abundant, with proportions of 90.93% and 91.08% Atp-Y and Coca-sr, respectively. Within this group of compounds, (Z,Z)-9,12-octadecadienoic acid was the most abundant (46.58% for Atp-Y and 53.84% for Coca-sr), followed by (E)-9-octadecenoic acid (30.39% for Atp-Y and 25.09% for Coca-sr). 2-Methoxy-4-vinylphenol, a phenolic compound, was identified and quantified at 0.28% only in the Coca-sr variety, while the only polyol, 1,4-anhydro-D-mannitol, was identified in the Atp-Y variety.
Conclusions:
In view of these results, we would suggest using the Atp-Y variety to benefit from a wide range of compounds, but also to respect the malting conditions in order to benefit from the different compounds.
Aim:
The germination of maize leads to many physiological changes in the plant. These changes are responsible for the appearance, disappearance, and variation in concentration of numerous compounds, including secondary metabolites. The aim of this study was to compare the secondary metabolite profile of two maize varieties germinated under controlled optimal conditions.
Methods:
To achieve this, the Atp-Y variety was soaked for 25.12 h at 25.54˚C in the presence of 0.5238% plant ash, germinated for 144.37 h, and matured for 37.65 h. For the Coca-sr variety, the grains were soaked for 1.608 h at 36.63˚C in the presence of 1.1093% plant ash. Germination and ripening took 144.37 h and 27.07 h, respectively. The compounds were extracted in methanol (HPLC grade) before being injected into a gas chromatography-mass spectrometry (GC-MS) equipped with an Rtx-5MS column for metabolite profiling.
Results:
These analyses showed that variety and optimum germination conditions influenced the secondary metabolite profile. This profiling identified 15 and 12 compounds in the Atp-Y and Coca-sr varieties, respectively. Of these compounds, 8 were identified in both varieties. The groups of compounds identified were fatty acids, esters, ketones, phenols, polyols, alcohols, sterols, and unclassified substances. Fatty acids were the most abundant, with proportions of 90.93% and 91.08% Atp-Y and Coca-sr, respectively. Within this group of compounds, (Z,Z)-9,12-octadecadienoic acid was the most abundant (46.58% for Atp-Y and 53.84% for Coca-sr), followed by (E)-9-octadecenoic acid (30.39% for Atp-Y and 25.09% for Coca-sr). 2-Methoxy-4-vinylphenol, a phenolic compound, was identified and quantified at 0.28% only in the Coca-sr variety, while the only polyol, 1,4-anhydro-D-mannitol, was identified in the Atp-Y variety.
Conclusions:
In view of these results, we would suggest using the Atp-Y variety to benefit from a wide range of compounds, but also to respect the malting conditions in order to benefit from the different compounds.
DOI: https://doi.org/10.37349/eff.2025.101087
Aim:
The present work aims to propose an alternative analytical protocol for assessing the thermal stability of plant protection products between 90°C and 240°C. In that view, this work seeks to identify any degradation products that may be overlooked during regulatory hydrolysis studies. Thus, we evaluate if a new regulatory approach is necessary and how this could be done by academic research. This requires working under similar conditions.
Methods:
A comprehensive analytical workflow was designed and implemented for ten active substances to study and investigate their overall degradation behaviour and volatilisation. The results were then compared with those reported in the regulatory studies.
Results:
The ratio of detected degradation products to active substances ranged from 0.5% to 50%. Volatilization products were identified for all compounds analyzed using TGA-GC-MS. This confirmed the pattern of degradation followed by volatilisation, except for tetraconazole, which volatilises before degradation. Some of the detected compounds were not reported at all in regulatory studies, or were detected at higher concentrations, such as IN-EQW78 and 500M07.
Conclusions:
This study confirmed the feasibility of conducting thermodegradation studies without relying on radiolabelled substances. It also identified two overlooked products and emphasised the importance of conducting studies exceeding 120°C.
Aim:
The present work aims to propose an alternative analytical protocol for assessing the thermal stability of plant protection products between 90°C and 240°C. In that view, this work seeks to identify any degradation products that may be overlooked during regulatory hydrolysis studies. Thus, we evaluate if a new regulatory approach is necessary and how this could be done by academic research. This requires working under similar conditions.
Methods:
A comprehensive analytical workflow was designed and implemented for ten active substances to study and investigate their overall degradation behaviour and volatilisation. The results were then compared with those reported in the regulatory studies.
Results:
The ratio of detected degradation products to active substances ranged from 0.5% to 50%. Volatilization products were identified for all compounds analyzed using TGA-GC-MS. This confirmed the pattern of degradation followed by volatilisation, except for tetraconazole, which volatilises before degradation. Some of the detected compounds were not reported at all in regulatory studies, or were detected at higher concentrations, such as IN-EQW78 and 500M07.
Conclusions:
This study confirmed the feasibility of conducting thermodegradation studies without relying on radiolabelled substances. It also identified two overlooked products and emphasised the importance of conducting studies exceeding 120°C.
DOI: https://doi.org/10.37349/eff.2025.101086
Bioactive compounds are secondary metabolites widely studied for their benefits to human health. They are distributed in various fruit, vegetable, and plant peels. The application of sustainable techniques for the extraction of these compounds is being implemented, assisted extraction by solid-state fermentation is a sustainable and effective alternative for the recovery of bioactive compounds by using agro-industrial waste as a raw material for extraction, this being a green process, easy for implementation, and it has low water and energy consumption. This research presents the biological properties of some of the most used bioactive compounds in the industry, as well as the advantages and factors that influence solid-state fermentation and the different processes for their recovery and/or production. The production of bioactive compounds using both continuous and discontinuous processes come with unique advantages and challenges. The choices between these methods depend on specific production objectives, scalability needs, and the availability of resources. As a result, ongoing advancements are refining these methods, enabling more sustainable and efficient production of bioactive compounds.
Bioactive compounds are secondary metabolites widely studied for their benefits to human health. They are distributed in various fruit, vegetable, and plant peels. The application of sustainable techniques for the extraction of these compounds is being implemented, assisted extraction by solid-state fermentation is a sustainable and effective alternative for the recovery of bioactive compounds by using agro-industrial waste as a raw material for extraction, this being a green process, easy for implementation, and it has low water and energy consumption. This research presents the biological properties of some of the most used bioactive compounds in the industry, as well as the advantages and factors that influence solid-state fermentation and the different processes for their recovery and/or production. The production of bioactive compounds using both continuous and discontinuous processes come with unique advantages and challenges. The choices between these methods depend on specific production objectives, scalability needs, and the availability of resources. As a result, ongoing advancements are refining these methods, enabling more sustainable and efficient production of bioactive compounds.
DOI: https://doi.org/10.37349/eff.2025.101085
Aim:
Worldwide, postharvest losses of tomato (Solanum lycopersicon cv. Roma) are around 50% due to physical and biological factors being this crop, one of the most important horticultural products with extensive fresh consumption. In this work, the effects of coatings of whey protein and candelilla wax with and without polyphenols from tarbush on the extension of the shelf life and postharvest quality of tomatoes were evaluated.
Methods:
An optimized suspension of protein-candelilla wax-glycerol (CC treatment) was applied as an edible coating to green mature tomatoes stored at room temperature (mature stage 2). The same suspension was supplemented with polyphenols from tarbush at 500 ppm (CP treatment). Tomato fruits without edible coating were used as a control treatment (SC). Various quality parameters were evaluated [color, weight loss, firmness, pH, titratable acidity and
Results:
Tomatoes with the CC treatment showed the best shelf life extension results [color, weight loss, firmness, pH, titratable acidity, and
Conclusions:
Using CC treatment, the ripening process can be significantly delayed, and the postharvest life quality of tomatoes at room temperature in the breaker stage can be extended up to this time without any spoilage.
Aim:
Worldwide, postharvest losses of tomato (Solanum lycopersicon cv. Roma) are around 50% due to physical and biological factors being this crop, one of the most important horticultural products with extensive fresh consumption. In this work, the effects of coatings of whey protein and candelilla wax with and without polyphenols from tarbush on the extension of the shelf life and postharvest quality of tomatoes were evaluated.
Methods:
An optimized suspension of protein-candelilla wax-glycerol (CC treatment) was applied as an edible coating to green mature tomatoes stored at room temperature (mature stage 2). The same suspension was supplemented with polyphenols from tarbush at 500 ppm (CP treatment). Tomato fruits without edible coating were used as a control treatment (SC). Various quality parameters were evaluated [color, weight loss, firmness, pH, titratable acidity and
Results:
Tomatoes with the CC treatment showed the best shelf life extension results [color, weight loss, firmness, pH, titratable acidity, and
Conclusions:
Using CC treatment, the ripening process can be significantly delayed, and the postharvest life quality of tomatoes at room temperature in the breaker stage can be extended up to this time without any spoilage.
DOI: https://doi.org/10.37349/eff.2025.101084
Among the most common medical problems experienced by older adults (over 60 years) are diabetes, Parkinson’s disease (PD), and erectile dysfunction (ED). The potential use of Mucuna pruriens in treating type 2 diabetes (T2D), PD, and ED is being investigated. Literature searches were conducted using the PubMed, MEDLINE, and Mendeley databases (1990–2023). Key words related to Mucuna pruriens, PD, diabetes, and EDs were used. An analysis of 26 preclinical and clinical trials suggested that Mucuna pruriens may be used to treat PD, diabetes, and ED. This study revealed a correlation between diabetes, Parkinson’s, and ED, with metabolic disorders being the common cause. Mucuna pruriens-based therapeutics could be a positive source of leva-dopa (LD) medications. It is well tolerated and beneficial for brain function and overall health. Evidence suggests that it has positive effects on libido, testosterone levels, and PD. It is important to note that PD and ED are linked by multiple mechanisms. In many clinical trials (in humans and animals), Mucuna pruriens were found to be effective at treating ED, PD, and diabetes. It is further necessary to conduct additional scientific studies to confirm the molecular mechanisms and biomarkers that link Mucuna pruriens phytochemicals with PD, ED, and diabetes.
Among the most common medical problems experienced by older adults (over 60 years) are diabetes, Parkinson’s disease (PD), and erectile dysfunction (ED). The potential use of Mucuna pruriens in treating type 2 diabetes (T2D), PD, and ED is being investigated. Literature searches were conducted using the PubMed, MEDLINE, and Mendeley databases (1990–2023). Key words related to Mucuna pruriens, PD, diabetes, and EDs were used. An analysis of 26 preclinical and clinical trials suggested that Mucuna pruriens may be used to treat PD, diabetes, and ED. This study revealed a correlation between diabetes, Parkinson’s, and ED, with metabolic disorders being the common cause. Mucuna pruriens-based therapeutics could be a positive source of leva-dopa (LD) medications. It is well tolerated and beneficial for brain function and overall health. Evidence suggests that it has positive effects on libido, testosterone levels, and PD. It is important to note that PD and ED are linked by multiple mechanisms. In many clinical trials (in humans and animals), Mucuna pruriens were found to be effective at treating ED, PD, and diabetes. It is further necessary to conduct additional scientific studies to confirm the molecular mechanisms and biomarkers that link Mucuna pruriens phytochemicals with PD, ED, and diabetes.
DOI: https://doi.org/10.37349/eff.2025.101083
This article belongs to the special issue Natural Products in Health and Disease
Agriculture is pivotal in securing global food security and sustainability, especially in pressing challenges such as climate change, population growth, and resource depletion. This review examines the interconnections between agriculture, food security, and sustainability, focusing on current challenges, innovations, and strategies to address these critical issues. The global demand for food is projected to increase substantially, necessitating agricultural systems that boost productivity and ensure environmental sustainability. However, conventional farming practices have exacerbated soil degradation, water scarcity, and greenhouse gas emissions, posing significant threats to long-term food security. This review aims to evaluate the role of sustainable agricultural practices in enhancing food security while mitigating environmental impacts. It also identifies existing gaps in farming systems and explores innovative solutions to promote resilient and sustainable food systems. A comprehensive review of peer-reviewed literature, policy documents, and global agricultural reports was conducted. The analysis focuses on key themes such as sustainable farming practices, the impacts of climate change on agriculture, advancements in agrotechnology, and the socio-economic dimensions of food security. Synthesized findings provide actionable insights into best practices and emerging trends. Sustainable agriculture offers a viable pathway to address the dual challenges of food security and environmental conservation. Precision farming, agroecology, and regenerative agriculture enhance productivity while preserving resources and reducing ecological footprints. Integrating advanced technologies, including artificial intelligence and genetic innovations, can optimize agricultural efficiency. However, global food security requires coordinated efforts among governments, the private sector, and local communities to implement equitable resource distribution and climate-resilient policies. Future research should prioritize scalable, region-specific solutions that align with sustainability principles to ensure a secure and resilient global food system.
Agriculture is pivotal in securing global food security and sustainability, especially in pressing challenges such as climate change, population growth, and resource depletion. This review examines the interconnections between agriculture, food security, and sustainability, focusing on current challenges, innovations, and strategies to address these critical issues. The global demand for food is projected to increase substantially, necessitating agricultural systems that boost productivity and ensure environmental sustainability. However, conventional farming practices have exacerbated soil degradation, water scarcity, and greenhouse gas emissions, posing significant threats to long-term food security. This review aims to evaluate the role of sustainable agricultural practices in enhancing food security while mitigating environmental impacts. It also identifies existing gaps in farming systems and explores innovative solutions to promote resilient and sustainable food systems. A comprehensive review of peer-reviewed literature, policy documents, and global agricultural reports was conducted. The analysis focuses on key themes such as sustainable farming practices, the impacts of climate change on agriculture, advancements in agrotechnology, and the socio-economic dimensions of food security. Synthesized findings provide actionable insights into best practices and emerging trends. Sustainable agriculture offers a viable pathway to address the dual challenges of food security and environmental conservation. Precision farming, agroecology, and regenerative agriculture enhance productivity while preserving resources and reducing ecological footprints. Integrating advanced technologies, including artificial intelligence and genetic innovations, can optimize agricultural efficiency. However, global food security requires coordinated efforts among governments, the private sector, and local communities to implement equitable resource distribution and climate-resilient policies. Future research should prioritize scalable, region-specific solutions that align with sustainability principles to ensure a secure and resilient global food system.
DOI: https://doi.org/10.37349/eff.2025.101082
The study investigated the role of probiotics and prebiotics in treating COVID-19. It focuses on their mechanisms of action in modulating the immune system and mitigating the disease’s impact. The research focused on the significance of the gut-lung axis and the potential benefits of probiotics and prebiotics against COVID-19. The research identified several findings: probiotics have shown potential in reducing the severity of COVID-19 symptoms and improving patient outcomes. The gut microbiota plays a critical role in the body’s immune response to COVID-19, with probiotics aiding in restoring its balance. Both can modulate the immune system, reducing the inflammatory response associated with COVID-19. While there is evidence supporting the benefits of probiotics and prebiotics, limitations exist due to the lack of studies on their use to improve COVID-19 outcomes. The originality of the study is focused on the gut-lung axis and the review of probiotics and prebiotics as potential therapies for COVID-19. By analyzing recent literature, the research contributes to understanding the interactions between diet, gut health, and respiratory infections. It also shows the need for further studies to determine the efficacy of COVID-19, toward new directions for research in the emerging field.
The study investigated the role of probiotics and prebiotics in treating COVID-19. It focuses on their mechanisms of action in modulating the immune system and mitigating the disease’s impact. The research focused on the significance of the gut-lung axis and the potential benefits of probiotics and prebiotics against COVID-19. The research identified several findings: probiotics have shown potential in reducing the severity of COVID-19 symptoms and improving patient outcomes. The gut microbiota plays a critical role in the body’s immune response to COVID-19, with probiotics aiding in restoring its balance. Both can modulate the immune system, reducing the inflammatory response associated with COVID-19. While there is evidence supporting the benefits of probiotics and prebiotics, limitations exist due to the lack of studies on their use to improve COVID-19 outcomes. The originality of the study is focused on the gut-lung axis and the review of probiotics and prebiotics as potential therapies for COVID-19. By analyzing recent literature, the research contributes to understanding the interactions between diet, gut health, and respiratory infections. It also shows the need for further studies to determine the efficacy of COVID-19, toward new directions for research in the emerging field.
DOI: https://doi.org/10.37349/eff.2025.101081
Aim:
Single tests have been used for the sensory evaluation of food. Although food color is the first perception used to determine acceptability, this study was performed to enhance the reliability of evaluations of the visual palatability of the crumb of bread (bread crumb) by reducing ambiguity in the tests.
Methods:
The optimal illumination color temperature to enhance the visual palatability of white bread crumb was determined by sensory evaluation using photographs with 13 participants in the main test and 27 participants in the retest, and correlations with visual palatability were assessed using coefficients of determination (R2).
Results:
Illumination color temperature showed a linear relation with the visual palatability of photographs of the crumb, while the light source with the lowest color temperature was associated with lower palatability scores compared to those with a slightly higher color temperature, as shown by duplicate tests. Ultraviolet (UV) illumination was also added as a purple and blue light source, and the linear correlation between visual palatability and visual firmness showed a high R2. Sensory evaluation measurement using a projector, instead of paper-based measurement, was also examined as a simpler method without the need for paper. The correlations with sensory scores showed correspondence between these measurements.
Conclusions:
High sensory scores for visual palatability were associated with lower visual firmness scores, even with the addition of data obtained under UV light. In addition, sensory evaluation measurement using a projector was confirmed to be useful. Finally, the optimal light source for the crumb of white bread was TL83. While warmer illumination has conventionally been preferred to enhance consumer food acceptance, the results presented here highlight the need for a detailed analysis of the effects of illumination color temperature on visual palatability.
Aim:
Single tests have been used for the sensory evaluation of food. Although food color is the first perception used to determine acceptability, this study was performed to enhance the reliability of evaluations of the visual palatability of the crumb of bread (bread crumb) by reducing ambiguity in the tests.
Methods:
The optimal illumination color temperature to enhance the visual palatability of white bread crumb was determined by sensory evaluation using photographs with 13 participants in the main test and 27 participants in the retest, and correlations with visual palatability were assessed using coefficients of determination (R2).
Results:
Illumination color temperature showed a linear relation with the visual palatability of photographs of the crumb, while the light source with the lowest color temperature was associated with lower palatability scores compared to those with a slightly higher color temperature, as shown by duplicate tests. Ultraviolet (UV) illumination was also added as a purple and blue light source, and the linear correlation between visual palatability and visual firmness showed a high R2. Sensory evaluation measurement using a projector, instead of paper-based measurement, was also examined as a simpler method without the need for paper. The correlations with sensory scores showed correspondence between these measurements.
Conclusions:
High sensory scores for visual palatability were associated with lower visual firmness scores, even with the addition of data obtained under UV light. In addition, sensory evaluation measurement using a projector was confirmed to be useful. Finally, the optimal light source for the crumb of white bread was TL83. While warmer illumination has conventionally been preferred to enhance consumer food acceptance, the results presented here highlight the need for a detailed analysis of the effects of illumination color temperature on visual palatability.
DOI: https://doi.org/10.37349/eff.2025.101080
Ketogenic diets are emerging dietary patterns that have demonstrated potential as therapeutic tools in a variety of symptoms and conditions, such as epileptic seizures, diabetes, obesity, cancer, migraines, and metabolic syndrome. This narrative review examines the therapeutic effects of ketogenic diets on physiological and mental health, including their role in modulating the gut microbiome. Ketogenic diets promote weight loss, enhance insulin sensitivity, and may lower dyslipidemia, which are crucial factors in preventing cardio-metabolic diseases. They also play a significant role in the composition and function of the gut microbiome, serving as a therapeutic approach to control autoimmune diseases, given their effectiveness in reducing pro-inflammatory cells. Conversely, a potential downside of these diets is the decrease in beneficial bacteria that have been positively associated with human health. Regarding mental health, ketogenic diets have the capability to stabilize neural networks, improve neuroplasticity, and exert direct benefits in brain bioenergetics, thereby potentially alleviating the symptoms related to several mental conditions, such as epilepsy, anxiety, depression, schizophrenia, bipolar disorder, autism spectrum disorder, and certain neurodegenerative diseases. However, more randomized, long-term studies are required to assess their efficacy, sustainability, and safety, including methodological rigor to strengthen findings on dietary impacts.
Ketogenic diets are emerging dietary patterns that have demonstrated potential as therapeutic tools in a variety of symptoms and conditions, such as epileptic seizures, diabetes, obesity, cancer, migraines, and metabolic syndrome. This narrative review examines the therapeutic effects of ketogenic diets on physiological and mental health, including their role in modulating the gut microbiome. Ketogenic diets promote weight loss, enhance insulin sensitivity, and may lower dyslipidemia, which are crucial factors in preventing cardio-metabolic diseases. They also play a significant role in the composition and function of the gut microbiome, serving as a therapeutic approach to control autoimmune diseases, given their effectiveness in reducing pro-inflammatory cells. Conversely, a potential downside of these diets is the decrease in beneficial bacteria that have been positively associated with human health. Regarding mental health, ketogenic diets have the capability to stabilize neural networks, improve neuroplasticity, and exert direct benefits in brain bioenergetics, thereby potentially alleviating the symptoms related to several mental conditions, such as epilepsy, anxiety, depression, schizophrenia, bipolar disorder, autism spectrum disorder, and certain neurodegenerative diseases. However, more randomized, long-term studies are required to assess their efficacy, sustainability, and safety, including methodological rigor to strengthen findings on dietary impacts.
DOI: https://doi.org/10.37349/eff.2025.101079
This article belongs to the special issue Ketogenic Diet as Medical Nutrition Therapy
Aim:
Livestock production plays a significant role in meeting global protein demands but is a major contributor to climate change. With the world population projected to reach 9 billion by 2050, identifying sustainable alternative protein sources has become more critical than ever. Edible insects offer an affordable protein option compared to beef, chicken, and fish, especially in many African and Asian cultures, where these conventional protein sources are considered relatively expensive. This study aimed to investigate the potential of mulberry silkworm pupae and African palm weevil larvae as alternative proteins to conventional protein sources for use in gluten-free wraps.
Methods:
Five gluten-free breakfast wraps were developed using oat flour and fillings made from beef, chicken, mackerel fish, palm weevil larvae, and silkworm pupae. The nutritional composition (amino acid and fatty acid profiles, micronutrient contents) and chemical, microbial, and sensory properties were determined using standard methods.
Results:
The wraps had protein contents ranging from 23.78% to 35.60%. Breakfast wrap with palm weevil larvae had slightly more fiber (4.01%) and carbohydrate (36.11%) contents and lower fat (10.22%) compared to the other wraps. It also had an impressive vitamin A content (528.96 μg RAE/100 g) and an exceptional amino acid profile. The insect wraps had more vitamin B12 (0.02 mg/g) contents than the conventional wraps. The fish-based version was the most preferred of all the wraps, with an overall acceptability score of 7.80. All developed products were within permissible limits for microbial quality.
Conclusions:
Edible insects, such as palm weevil larvae and silkworm pupae, could serve as an alternative source of protein in the production of gluten-free foods.
Aim:
Livestock production plays a significant role in meeting global protein demands but is a major contributor to climate change. With the world population projected to reach 9 billion by 2050, identifying sustainable alternative protein sources has become more critical than ever. Edible insects offer an affordable protein option compared to beef, chicken, and fish, especially in many African and Asian cultures, where these conventional protein sources are considered relatively expensive. This study aimed to investigate the potential of mulberry silkworm pupae and African palm weevil larvae as alternative proteins to conventional protein sources for use in gluten-free wraps.
Methods:
Five gluten-free breakfast wraps were developed using oat flour and fillings made from beef, chicken, mackerel fish, palm weevil larvae, and silkworm pupae. The nutritional composition (amino acid and fatty acid profiles, micronutrient contents) and chemical, microbial, and sensory properties were determined using standard methods.
Results:
The wraps had protein contents ranging from 23.78% to 35.60%. Breakfast wrap with palm weevil larvae had slightly more fiber (4.01%) and carbohydrate (36.11%) contents and lower fat (10.22%) compared to the other wraps. It also had an impressive vitamin A content (528.96 μg RAE/100 g) and an exceptional amino acid profile. The insect wraps had more vitamin B12 (0.02 mg/g) contents than the conventional wraps. The fish-based version was the most preferred of all the wraps, with an overall acceptability score of 7.80. All developed products were within permissible limits for microbial quality.
Conclusions:
Edible insects, such as palm weevil larvae and silkworm pupae, could serve as an alternative source of protein in the production of gluten-free foods.
DOI: https://doi.org/10.37349/eff.2025.101078
This article belongs to the special issue The food (r)evolution towards food quality/security and human nutrition
Aim:
Dried fruits are consumed by many people around the world as a convenient alternative to fresh fruits with a long shelf life. As well as dried fruits, the manufacturing of baked chips based on fruits having good nutrition and sensory properties represents an alternative to healthier food. The aim of this study is to determine the different chemical properties of dried fruits and fruit chips when they are being fried in ovens. Another aim was to evaluate the changes in total phenolic content (TPC), antioxidant activity, ascorbic acid and hydroxy methyl furfural (HMF) content of chips and dried forms.
Methods:
In this study, apple, pear, orange, and kiwi were dried in a convection oven at 100°–120°C. Moreover, apple-orange (A-O) and kiwi-pear (K-P) chips were produced in order to develop an alternative product. Dry matter, ash, TPC, ascorbic acid and HMF contents, pH, total acidity and antioxidant activity were determined in fresh, dried and chips samples. Sensory analysis was also carried out in the prepared fruit chips samples using the hedonic scale test.
Results:
The results revealed that dry matter and ash content increased in dried fruit and fruit chip samples. Drying caused a slight increase in pH and total acidity of all fruit samples. The ascorbic acid contents of kiwi and apple significantly decreased during the drying process. The drying process significantly impacted the total phenol content and antioxidant activity in dried slices. The dramatic increase of HMF was observed during oven-drying and chip production.
Conclusions:
Based on results, it can be concluded that drying and baking processes had variable effects on the chemical, sensory and bioactive properties of fruit samples. Sensory analysis revealed that A-O chips were more acceptable in terms of sensorial properties compared to K-P chips.
Aim:
Dried fruits are consumed by many people around the world as a convenient alternative to fresh fruits with a long shelf life. As well as dried fruits, the manufacturing of baked chips based on fruits having good nutrition and sensory properties represents an alternative to healthier food. The aim of this study is to determine the different chemical properties of dried fruits and fruit chips when they are being fried in ovens. Another aim was to evaluate the changes in total phenolic content (TPC), antioxidant activity, ascorbic acid and hydroxy methyl furfural (HMF) content of chips and dried forms.
Methods:
In this study, apple, pear, orange, and kiwi were dried in a convection oven at 100°–120°C. Moreover, apple-orange (A-O) and kiwi-pear (K-P) chips were produced in order to develop an alternative product. Dry matter, ash, TPC, ascorbic acid and HMF contents, pH, total acidity and antioxidant activity were determined in fresh, dried and chips samples. Sensory analysis was also carried out in the prepared fruit chips samples using the hedonic scale test.
Results:
The results revealed that dry matter and ash content increased in dried fruit and fruit chip samples. Drying caused a slight increase in pH and total acidity of all fruit samples. The ascorbic acid contents of kiwi and apple significantly decreased during the drying process. The drying process significantly impacted the total phenol content and antioxidant activity in dried slices. The dramatic increase of HMF was observed during oven-drying and chip production.
Conclusions:
Based on results, it can be concluded that drying and baking processes had variable effects on the chemical, sensory and bioactive properties of fruit samples. Sensory analysis revealed that A-O chips were more acceptable in terms of sensorial properties compared to K-P chips.
DOI: https://doi.org/10.37349/eff.2025.101077
Aim:
The increasing prevalence of type 2 diabetes has heightened the demand for low glycemic index food products, leading to the exploration of alternative baking ingredients. This study assesses the effects of bran-enriched flour blends on the sensory, physical, nutritional, and antioxidant properties and glycemic control of high-fiber biscuits.
Methods:
Wheat, corn, sorghum, and sweet potato were obtained from the market. Linear programming (LP) optimized fiber content to create four high-fiber flour blends assessed for functional properties [water absorption capacity (WAC), oil absorption capacity (OAC), foaming capacity (FC), and stability]. Four high-fiber biscuits were developed and evaluated for nutritional composition (ash, crude fibers, water, carbohydrates, proteins, fats, Zn, Fe, Mg, Na, Ca, and P), sensory attributes (color, aroma, texture, and taste), physical properties (thickness, diameter, weight, spread ratio, browning index; L, a, and b), antioxidant properties (DPPH and FRAP activities), glycemic response, and in vitro glucose-binding capacity.
Results:
The formulated flours exhibited water and oil absorption capacities ranging from 1.95% to 2.70%, with the highest oil absorption in formulated flour 3. FC and stability varied significantly, with the control showing the highest values. Swelling power ranged from 1.27 cm3/g to 2.03 cm3/g. High-fiber biscuits had higher fiber (6.06–12.44%), protein (9.48–11.31%), Fe (3.01–4.55 ppm), and Mg (34.37–78.05 ppm) content, and lower carbohydrate (50.88–59.57%) contents compared to the control. They also demonstrated enhanced antioxidant properties with higher phenolic content (201.91–503.18 mg GAE/100 g) and DPPH-scavenging activity (0.07–0.27 µg/mL). Sensory evaluation indicated general acceptance. Biscuits 2 and 3 maintained steady blood glucose levels over 90 min, with biscuit 3 showing the highest in vitro glucose binding capacity (43.4 ± 4.3%).
Conclusions:
Incorporating diverse bran and flour types improves biscuit quality, particularly in blends like F2 (wheat flour, corn bran, and sorghum bran) and F3 (wheat flour, corn bran, sweet potato flour, and sorghum bran), offering beneficial options for diabetics.
Aim:
The increasing prevalence of type 2 diabetes has heightened the demand for low glycemic index food products, leading to the exploration of alternative baking ingredients. This study assesses the effects of bran-enriched flour blends on the sensory, physical, nutritional, and antioxidant properties and glycemic control of high-fiber biscuits.
Methods:
Wheat, corn, sorghum, and sweet potato were obtained from the market. Linear programming (LP) optimized fiber content to create four high-fiber flour blends assessed for functional properties [water absorption capacity (WAC), oil absorption capacity (OAC), foaming capacity (FC), and stability]. Four high-fiber biscuits were developed and evaluated for nutritional composition (ash, crude fibers, water, carbohydrates, proteins, fats, Zn, Fe, Mg, Na, Ca, and P), sensory attributes (color, aroma, texture, and taste), physical properties (thickness, diameter, weight, spread ratio, browning index; L, a, and b), antioxidant properties (DPPH and FRAP activities), glycemic response, and in vitro glucose-binding capacity.
Results:
The formulated flours exhibited water and oil absorption capacities ranging from 1.95% to 2.70%, with the highest oil absorption in formulated flour 3. FC and stability varied significantly, with the control showing the highest values. Swelling power ranged from 1.27 cm3/g to 2.03 cm3/g. High-fiber biscuits had higher fiber (6.06–12.44%), protein (9.48–11.31%), Fe (3.01–4.55 ppm), and Mg (34.37–78.05 ppm) content, and lower carbohydrate (50.88–59.57%) contents compared to the control. They also demonstrated enhanced antioxidant properties with higher phenolic content (201.91–503.18 mg GAE/100 g) and DPPH-scavenging activity (0.07–0.27 µg/mL). Sensory evaluation indicated general acceptance. Biscuits 2 and 3 maintained steady blood glucose levels over 90 min, with biscuit 3 showing the highest in vitro glucose binding capacity (43.4 ± 4.3%).
Conclusions:
Incorporating diverse bran and flour types improves biscuit quality, particularly in blends like F2 (wheat flour, corn bran, and sorghum bran) and F3 (wheat flour, corn bran, sweet potato flour, and sorghum bran), offering beneficial options for diabetics.
DOI: https://doi.org/10.37349/eff.2025.101076
This article belongs to the special issue The food (r)evolution towards food quality/security and human nutrition
Aim:
The study investigates the probiotic potential of exopolysaccharide (EPS)-producing lactic acid bacteria (LAB) isolated from yoghurt samples. It assesses their antimicrobial efficacy against foodborne pathogens, particularly Escherichia coli and Staphylococcus aureus. The objective is to identify LAB strains that can be used as natural preservatives and health-promoting probiotics in functional foods.
Methods:
Yoghurt samples were collected from household local markets in Rawalpindi, Pakistan. LAB was isolated and identified using selective media, Gram staining, and biochemical tests. EPS production was quantified using the phenol-sulfuric acid method. Probiotic properties, including antimicrobial activity against E. coli and S. aureus, were evaluated using the disc diffusion method. Strains producing the highest EPS were biochemically characterised using the API Strep system.
Results:
Of 29 LAB isolates, 12 were identified as significant EPS producers, with Streptococcus thermophilus, Lactococcus lactis, and Limosilactobacillus fermentum demonstrating the highest EPS production (up to 62 µg/mL). These strains exhibited strong antimicrobial activity against E. coli and S. aureus, with inhibition zones ranging from 2 mm to 32.1 mm. The results confirmed the dual functionality of these strains as both texture enhancers and natural preservatives in food products.
Conclusions:
The EPS-producing LAB strains, particularly S. thermophilus, L. lactis, and L. fermentum, showed significant potential as probiotics and natural preservatives. Their antimicrobial activity and ability to enhance food texture suggest their applicability in the food industry to promote health and improve food safety. Further research should explore their stability in different food matrices for commercial use.
Aim:
The study investigates the probiotic potential of exopolysaccharide (EPS)-producing lactic acid bacteria (LAB) isolated from yoghurt samples. It assesses their antimicrobial efficacy against foodborne pathogens, particularly Escherichia coli and Staphylococcus aureus. The objective is to identify LAB strains that can be used as natural preservatives and health-promoting probiotics in functional foods.
Methods:
Yoghurt samples were collected from household local markets in Rawalpindi, Pakistan. LAB was isolated and identified using selective media, Gram staining, and biochemical tests. EPS production was quantified using the phenol-sulfuric acid method. Probiotic properties, including antimicrobial activity against E. coli and S. aureus, were evaluated using the disc diffusion method. Strains producing the highest EPS were biochemically characterised using the API Strep system.
Results:
Of 29 LAB isolates, 12 were identified as significant EPS producers, with Streptococcus thermophilus, Lactococcus lactis, and Limosilactobacillus fermentum demonstrating the highest EPS production (up to 62 µg/mL). These strains exhibited strong antimicrobial activity against E. coli and S. aureus, with inhibition zones ranging from 2 mm to 32.1 mm. The results confirmed the dual functionality of these strains as both texture enhancers and natural preservatives in food products.
Conclusions:
The EPS-producing LAB strains, particularly S. thermophilus, L. lactis, and L. fermentum, showed significant potential as probiotics and natural preservatives. Their antimicrobial activity and ability to enhance food texture suggest their applicability in the food industry to promote health and improve food safety. Further research should explore their stability in different food matrices for commercial use.
DOI: https://doi.org/10.37349/eff.2025.101075
Aim:
This research was conducted on the hypothesis that refined sugars negatively affect health, require high energy for production, generate significant carbon emissions, and produce environmental waste. Additionally, by-products such as molasses and pulp, which are often underutilized, can be repurposed as value-added products for human consumption. This research focuses on a new, long-shelf-life product derived from sugar beet. The developed product retains nutrients such as protein, fiber, vitamins, and minerals that are naturally present in sugar beet.
Methods:
The new method proposes using the entire beet as an unrefined alternative to refined sugar. The processing steps include cleaning, cooking, peeling, shredding, drying, and grinding. Various cooking methods were tested, and the optimum conditions were found to be 4.5 hours at 165°C. To prevent oxidation of peeled beets, a 0.5% citric acid solution was applied for 15 min at 25°C prior to cooking. Drying was performed in a convection oven with pans at 95°C for 7.5 hours.
Results:
The final product had a moisture content of 2.9% and a water activity level of 0.302. The product contained 78.6% total sugars, 12.9% fiber, and 3.45% protein, and was classified as an unrefined sweetener rich in both protein and fiber. Compared to the typical yield of 120 g of refined sugar from 1 kg of beets, this new method produces 219 g of product by utilizing fibers, proteins, and other nutrients, along with by-products such as molasses and pulp.
Conclusions:
Due to its high fiber and protein content, the new product has a low glycemic index. Compared to conventional beet sugar production, the proposed method reduces energy consumption and carbon emissions by 40% per unit of product. The new input obtained has a high potential to be used as a source of sugar and fiber in bakery and confectionery products. It is a more sustainable process than refined sugar.
Aim:
This research was conducted on the hypothesis that refined sugars negatively affect health, require high energy for production, generate significant carbon emissions, and produce environmental waste. Additionally, by-products such as molasses and pulp, which are often underutilized, can be repurposed as value-added products for human consumption. This research focuses on a new, long-shelf-life product derived from sugar beet. The developed product retains nutrients such as protein, fiber, vitamins, and minerals that are naturally present in sugar beet.
Methods:
The new method proposes using the entire beet as an unrefined alternative to refined sugar. The processing steps include cleaning, cooking, peeling, shredding, drying, and grinding. Various cooking methods were tested, and the optimum conditions were found to be 4.5 hours at 165°C. To prevent oxidation of peeled beets, a 0.5% citric acid solution was applied for 15 min at 25°C prior to cooking. Drying was performed in a convection oven with pans at 95°C for 7.5 hours.
Results:
The final product had a moisture content of 2.9% and a water activity level of 0.302. The product contained 78.6% total sugars, 12.9% fiber, and 3.45% protein, and was classified as an unrefined sweetener rich in both protein and fiber. Compared to the typical yield of 120 g of refined sugar from 1 kg of beets, this new method produces 219 g of product by utilizing fibers, proteins, and other nutrients, along with by-products such as molasses and pulp.
Conclusions:
Due to its high fiber and protein content, the new product has a low glycemic index. Compared to conventional beet sugar production, the proposed method reduces energy consumption and carbon emissions by 40% per unit of product. The new input obtained has a high potential to be used as a source of sugar and fiber in bakery and confectionery products. It is a more sustainable process than refined sugar.
DOI: https://doi.org/10.37349/eff.2025.101074
The ketogenic diet (KD) is a nutritional model that includes high fat, moderate protein, and low carbohydrate (less than 50 g). The “KD ratio” is used to determine the amount of macronutrients in the diet. In classical KD with the ratio of 3:1 or 4:1, 85–90% of the energy is provided from dietary fat. In addition to classical KD, the modified Atkins diet, low glycemic index therapy, and medium-chain triglyceride diet have also been used, and in some studies, ketosis has been achieved with exogenous ketone supplements. KD has long been recognized as a successful dietary approach in the treatment of refractory epilepsy. It is known that KD may also be effective in other neurological diseases such as Alzheimer’s disease, Parkinson’s disease, multiple sclerosis, and migraine through various mechanisms such as providing an alternative energy source for neurons, reducing inflammation and oxidative stress, stimulating neurotransmitter synthesis and regulation of microbiota, etc. However, existing evidence is insufficient to make definitive conclusions about the effect of the KD on neurological diseases other than epilepsy due to the short intervention time, the small sample size, and the heterogeneity in the study methods. Considering factors such as genetics, endocrine differences, timing, and diet composition, it is important to apply and follow precision nutrition programs to increase the benefits of KD and reduce its side effects. In this review, the mechanisms of the KD on neurological diseases, recent evidence on the use of the KD in neurological diseases other than epilepsy, the limitations and difficulties in the literature on the KD, and the contraindications of the KD were discussed in detail.
The ketogenic diet (KD) is a nutritional model that includes high fat, moderate protein, and low carbohydrate (less than 50 g). The “KD ratio” is used to determine the amount of macronutrients in the diet. In classical KD with the ratio of 3:1 or 4:1, 85–90% of the energy is provided from dietary fat. In addition to classical KD, the modified Atkins diet, low glycemic index therapy, and medium-chain triglyceride diet have also been used, and in some studies, ketosis has been achieved with exogenous ketone supplements. KD has long been recognized as a successful dietary approach in the treatment of refractory epilepsy. It is known that KD may also be effective in other neurological diseases such as Alzheimer’s disease, Parkinson’s disease, multiple sclerosis, and migraine through various mechanisms such as providing an alternative energy source for neurons, reducing inflammation and oxidative stress, stimulating neurotransmitter synthesis and regulation of microbiota, etc. However, existing evidence is insufficient to make definitive conclusions about the effect of the KD on neurological diseases other than epilepsy due to the short intervention time, the small sample size, and the heterogeneity in the study methods. Considering factors such as genetics, endocrine differences, timing, and diet composition, it is important to apply and follow precision nutrition programs to increase the benefits of KD and reduce its side effects. In this review, the mechanisms of the KD on neurological diseases, recent evidence on the use of the KD in neurological diseases other than epilepsy, the limitations and difficulties in the literature on the KD, and the contraindications of the KD were discussed in detail.
DOI: https://doi.org/10.37349/eff.2025.101073
This article belongs to the special issue Ketogenic Diet as Medical Nutrition Therapy
Aim:
To investigate the effects of allitol on the cecal microbiota profile of high-fat diet-induced obese rats to obtain basic data and to predict the pathway of butyric acid production from allitol using bioinformatic techniques. Moreover, this study examined whether the anti-obesity effect of allitol was due to butyric acid produced by gut microbiota.
Methods:
Sixteen male Wistar rats were divided into two groups: control (C) and 5% allitol-supplemented (A). The rats were provided free access to the experimental diets for 11 weeks. Following the feeding period, the body weight, body fat, cecal short-chain fatty acids, and cecal microbiota profiles were determined.
Results:
Body fat percentage was significantly lower in Group A than in Group C. Group A had a significantly higher abundance of the phylum Bacteroidota than Group C, whereas there were no differences in the abundance of Bacillota, Actinomycetota, and Pseudomonadota. Changes in the microbiota indicated a significant increase in the abundance of 10 genera and a significant decrease in the abundance of 14 genera in Group A compared to Group C. The cecal butyric acid content was significantly higher in Group A than in Group C. Functional analysis of PICRUSt2 showed that many enzymes belonging to the metabolic pathway that produces butyric acid from allitol are induced. However, the cecal bacteria involved in the anti-obesity effect differed from those involved in butyric acid production.
Conclusions:
This study demonstrated several compositional changes in the cecal microbiota and an increase in butyric acid production following dietary allitol supplementation. The anti-obesity effect of allitol was confirmed; however, it was suggested that the butyric acid produced by the intestinal bacteria may not be responsible for this effect.
Aim:
To investigate the effects of allitol on the cecal microbiota profile of high-fat diet-induced obese rats to obtain basic data and to predict the pathway of butyric acid production from allitol using bioinformatic techniques. Moreover, this study examined whether the anti-obesity effect of allitol was due to butyric acid produced by gut microbiota.
Methods:
Sixteen male Wistar rats were divided into two groups: control (C) and 5% allitol-supplemented (A). The rats were provided free access to the experimental diets for 11 weeks. Following the feeding period, the body weight, body fat, cecal short-chain fatty acids, and cecal microbiota profiles were determined.
Results:
Body fat percentage was significantly lower in Group A than in Group C. Group A had a significantly higher abundance of the phylum Bacteroidota than Group C, whereas there were no differences in the abundance of Bacillota, Actinomycetota, and Pseudomonadota. Changes in the microbiota indicated a significant increase in the abundance of 10 genera and a significant decrease in the abundance of 14 genera in Group A compared to Group C. The cecal butyric acid content was significantly higher in Group A than in Group C. Functional analysis of PICRUSt2 showed that many enzymes belonging to the metabolic pathway that produces butyric acid from allitol are induced. However, the cecal bacteria involved in the anti-obesity effect differed from those involved in butyric acid production.
Conclusions:
This study demonstrated several compositional changes in the cecal microbiota and an increase in butyric acid production following dietary allitol supplementation. The anti-obesity effect of allitol was confirmed; however, it was suggested that the butyric acid produced by the intestinal bacteria may not be responsible for this effect.
DOI: https://doi.org/10.37349/eff.2025.101072
Research infrastructures (RIs) are central to European Union (EU) policies for defragmentation of the research and innovation in all fields of science and technology providing resources, expertise, and services to address societal challenges and support evidence-based policymaking. The commentary stresses on how METROFOOD-RI, a geographically distributed RI, aims at advancing metrology in the agri-food sector with a particular emphasis on food/feed and nutrition fields. Structured according to Hub & Nodes model, METROFOOD-RI integrates physical and electronic infrastructures to provide FAIR (Findable, Accessible, Interoperable, Reusable) data and tools. Its activities span a comprehensive service chart covering research, information and communication technologies (ICT), and data, advisory, and educational services, as well as integrated service pipelines targeting transparency in the food chain, emerging food risks, innovative processing, and circular bioeconomy approaches. By leveraging metrology, METROFOOD-RI aims at harmonizing standards and fostering cross-border collaboration, whereas equally supports a multidisciplinary approach to tackling challenges in food systems and nutrition. The commentary highlights how this RI can contribute to the European research area priorities and United Nations sustainability goals.
Research infrastructures (RIs) are central to European Union (EU) policies for defragmentation of the research and innovation in all fields of science and technology providing resources, expertise, and services to address societal challenges and support evidence-based policymaking. The commentary stresses on how METROFOOD-RI, a geographically distributed RI, aims at advancing metrology in the agri-food sector with a particular emphasis on food/feed and nutrition fields. Structured according to Hub & Nodes model, METROFOOD-RI integrates physical and electronic infrastructures to provide FAIR (Findable, Accessible, Interoperable, Reusable) data and tools. Its activities span a comprehensive service chart covering research, information and communication technologies (ICT), and data, advisory, and educational services, as well as integrated service pipelines targeting transparency in the food chain, emerging food risks, innovative processing, and circular bioeconomy approaches. By leveraging metrology, METROFOOD-RI aims at harmonizing standards and fostering cross-border collaboration, whereas equally supports a multidisciplinary approach to tackling challenges in food systems and nutrition. The commentary highlights how this RI can contribute to the European research area priorities and United Nations sustainability goals.
DOI: https://doi.org/10.37349/eff.2025.101071
This article belongs to the special issue Metrological Aspects in the Analysis of Nutrients, Functional Compounds, Additives and Contaminants in Food and Feed
Native to East Asia and predominantly cultivated in regions such as the Ningxia Hui and Xinjiang Uyghur Autonomous Regions of China, Lycium barbarum (L. barbarum), commonly known as goji berry, has a long history in traditional medicine and is gaining recognition in contemporary health research. This review provides a comprehensive exploration of its botanical characteristics, pharmacokinetics, and safety, alongside a critical evaluation of human clinical studies investigating its therapeutic potential. Key health benefits include immune modulation, antioxidative effects, mental health support, ocular health preservation, and metabolic and cardiovascular regulation. Furthermore, its role in addressing age-related macular degeneration and chronic conditions such as cancer and metabolic syndrome is highlighted. The bioactivity of L. barbarum is attributed to its rich composition of polysaccharides, carotenoids, flavonoids, and other bioactive compounds, which exhibit anti-inflammatory, neuroprotective, and metabolic-regulating properties. This review also examines the safety profile of L. barbarum, considering its side effects, toxicity, potential contamination, and interactions with medications, emphasising the importance of balancing its health-promoting properties with cautious consumption. Despite promising findings, gaps in the evidence base, including the need for larger, long-term, and rigorously controlled trials, remain significant barriers to clinical translation. By integrating traditional medicinal knowledge with modern scientific insights, this review underscores L. barbarum’s potential as a functional food and therapeutic agent. Its unique pharmacological properties and broad applicability position it as a valuable tool for health promotion and disease prevention, while highlighting areas requiring further research to optimise its safe and effective use.
Native to East Asia and predominantly cultivated in regions such as the Ningxia Hui and Xinjiang Uyghur Autonomous Regions of China, Lycium barbarum (L. barbarum), commonly known as goji berry, has a long history in traditional medicine and is gaining recognition in contemporary health research. This review provides a comprehensive exploration of its botanical characteristics, pharmacokinetics, and safety, alongside a critical evaluation of human clinical studies investigating its therapeutic potential. Key health benefits include immune modulation, antioxidative effects, mental health support, ocular health preservation, and metabolic and cardiovascular regulation. Furthermore, its role in addressing age-related macular degeneration and chronic conditions such as cancer and metabolic syndrome is highlighted. The bioactivity of L. barbarum is attributed to its rich composition of polysaccharides, carotenoids, flavonoids, and other bioactive compounds, which exhibit anti-inflammatory, neuroprotective, and metabolic-regulating properties. This review also examines the safety profile of L. barbarum, considering its side effects, toxicity, potential contamination, and interactions with medications, emphasising the importance of balancing its health-promoting properties with cautious consumption. Despite promising findings, gaps in the evidence base, including the need for larger, long-term, and rigorously controlled trials, remain significant barriers to clinical translation. By integrating traditional medicinal knowledge with modern scientific insights, this review underscores L. barbarum’s potential as a functional food and therapeutic agent. Its unique pharmacological properties and broad applicability position it as a valuable tool for health promotion and disease prevention, while highlighting areas requiring further research to optimise its safe and effective use.
DOI: https://doi.org/10.37349/eff.2025.101070
This article belongs to the special issue Natural Products in Health and Disease
