Critical Reviews in Food Science and Nutrition

Wang, Luanfeng; Ren, Bo; Wu, Shufeng; Song, Haizhao; Xiong, Ling; Wang, Fang; Shen, Xinchun

doi: 10.1080/10408398.2024.2369946pmid: 38920093

Abstract Limosillactobacillus reuteri (L. reuteri), a type of Lactobacillus spp., stands out as the most extensively researched probiotic. Its remarkable intestinal adhesion has led to widespread applications in both the food and medical sectors. Notably, recent research highlights the probiotic efficacy of L. reuteri sourced from breast milk, particularly in influencing social behavior and mitigating atopic dermatitis. In this review, our emphasis is on surveying recent literature regarding the promotion of host’s health by L. reuteri. We aim to provide a concise summary of the latest regulatory effects and potential mechanisms attributed to L. reuteri in the realms of metabolism, brain- and immune-related functions. The mechanism through which L. reuteri promotes host health by modulating the intestinal microenvironment primarily involves promoting intestinal epithelial renewal, bolstering intestinal barrier function, regulating gut microbiota and its metabolites, and suppressing inflammation and immune responses. Additionally, this review delves into new technologies, identifies shortcomings, and addresses challenges in current L. reuteri research. Finally, the application prospects of L. reuteri are provided. Therefore, a better understanding of the role and mechanisms of L. reuteri will contribute significantly to the development of new probiotic functional foods and enable precise, targeted interventions for various diseases.

Lin, Yuandong; Cheng, Jun-Hu; Ma, Ji; Zhou, Chenyue; Sun, Da-Wen

doi: 10.1080/10408398.2024.2376113pmid: 39015031

Abstract Food quality and safety problems caused by inefficient control in the food chain have significant implications for human health, social stability, and economic progress and optical sensor arrays (OSAs) can effectively address these challenges. This review aims to summarize the recent applications of nanomaterials-based OSA for food quality and safety visual monitoring, including colourimetric sensor array (CSA) and fluorescent sensor array (FSA). First, the fundamental properties of various advanced nanomaterials, mainly including metal nanoparticles (MNPs) and nanoclusters (MNCs), quantum dots (QDs), upconversion nanoparticles (UCNPs), and others, were described. Besides, the diverse machine learning (ML) and deep learning (DL) methods of high-dimensional data obtained from the responses between different sensing elements and analytes were presented. Moreover, the recent and representative applications in pesticide residues, heavy metal ions, bacterial contamination, antioxidants, flavor matters, and food freshness detection were comprehensively summarized. Finally, the challenges and future perspectives for nanomaterials-based OSAs are discussed. It is believed that with the advancements in artificial intelligence (AI) techniques and integrated technology, nanomaterials-based OSAs are expected to be an intelligent, effective, and rapid tool for food quality assessment and safety control.

Huang, Zhan; Wells, Jerry M.; Fogliano, Vincenzo; Capuano, Edoardo

doi: 10.1080/10408398.2024.2369947pmid: 38950607

Abstract In recent years, the role of microbial tryptophan (Trp) catabolism in host-microbiota crosstalk has become a major area of scientific interest. Microbiota-derived Trp catabolites positively contribute to intestinal and systemic homeostasis by acting as ligands of aryl hydrocarbon receptor and pregnane X receptor, and as signaling molecules in microbial communities. Accumulating evidence suggests that microbial Trp catabolism could be therapeutic targets in treating human diseases. A number of bacteria and metabolic pathways have been identified to be responsible for the conversion of Trp in the intestine. Interestingly, many Trp-degrading bacteria can benefit from the supplementation of specific dietary fibers and polyphenols, which in turn increase the microbial production of beneficial Trp catabolites. Thus, this review aims to highlight the emerging role of diets and food components, i.e., food matrix, fiber, and polyphenol, in modulating the microbial catabolism of Trp and discuss the opportunities for potential therapeutic interventions via specifically designed diets targeting the Trp-microbiome axis.

Huang, Huange; Wang, Qiang; Tan, Jianxin; Zeng, Chunxiang; Wang, Junying; Huang, Jingwei; Hu, Yichen; Wu, Qi; Wu, Xiaoyong; Liu, Changying; Ye, Xueling; Fan, Yu; Sun, Wenjun; Guo, Zhanbin; Peng, Lianxin; Zou, Liang;

Chen, Xiaoyu; Zhu, Ling; Zhang, Hui; Wu, Gangcheng; Cheng, Lilin; Zhang, Yayuan

doi: 10.1080/10408398.2024.2370487pmid: 38920118

Abstract As compared with exogenous components, non-starch components (NSCS), such as proteins, lipids, non-starch polysaccharides (NSPs), and polyphenols, inherently present in cereals, are more effective at inhibiting starch digestibility. Existing research has mostly focused on complex systems but overlooked the analysis of the in-situ role of the NSCS. This study reviews the crucial mechanisms by which endogenous NSCS inhibit starch digestion, emphasizing the spatial distribution-function relationship. Starch granules are filled with pores/channels-associated proteins and lipids, embedding in the protein matrix, and maintained by endosperm cell walls. The potential starch digestion inhibition of endogenous NSCS is achieved by altering starch gelatinization, molecular structure, digestive enzyme activity, and accessibility. Starch gelatinization is constrained by endogenous NSCS, particularly cell wall NSPs and matrix proteins. The stability of the starch crystal structure is enhanced by the proteins and lipids distributed in the starch granule pores and channels. Endogenous polyphenols greatly inhibit digestive enzymes and participate in the cross-linking of NSPs in the cell wall space, which together constitute a physical barrier that hinders amylase diffusion. Additionally, the spatial entanglement of NSCS and starch under heat and non-heat processing conditions reduces starch accessibility. This review provides novel evidence for the health benefits of whole cereals.

Yang, Zhao; Zhang, Shijie; Ying, Lu; Zhang, Wenjing; Chen, Xiaoyang; Liang, Youfeng; Chen, Ruolan; Yao, Keying; Li, Chunhui; Yu, Changyuan; Jamilian, Parmida; Zarezadeh, Meysam; Kord-Varkaneh, Hamed; Wang, Jianfeng; Li, Hanmin

Hofmann, Laurie C.; Strauss, Sylvia; Shpigel, Muki; Guttman, Lior; Stengel, Dagmar B.; Rebours, Céline; Gjorgovska, Natasha; Turan, Gamze; Balina, Karina; Zammit, Gabrielle; Adams, Jessica M. M.; Ahsan, Umair; Bartolo, Angela G.; Bolton, John J.; Domingues, Rosário; Dürrani, Ömerhan; Eroldogan, Orhan Tufan; Freitas, Andreia; Golberg, Alexander;

Laveriano-Santos, Emily P.; Luque-Corredera, Carlos; Trius-Soler, Marta; Lozano-Castellón, Julian; Dominguez-López, Inés; Castro-Barquero, Sara; Vallverdú-Queralt, Anna; Lamuela-Raventós, Rosa M.; Pérez, Maria

doi: 10.1080/10408398.2024.2371939pmid: 38952149

Abstract The enterolignans, enterolactone and enterodiol, the main metabolites produced from plant lignans by the gut microbiota, have enhanced bioavailability and activity compared to their precursors, with beneficial effects on metabolic and cardiovascular health. Although extensively studied, the biosynthesis, cardiometabolic effects, and other therapeutic implications of mammalian lignans are still incompletely understood. The aim of this review is to provide a comprehensive overview of these phytoestrogen metabolites based on up-to-date information reported in studies from a wide range of disciplines. Established and novel synthetic strategies are described, as are the various lignan precursors, their dietary sources, and a proposed metabolic pathway for their conversion to enterolignans. The methodologies used for enterolignan analysis and the available data on pharmacokinetics and bioavailability are summarized and their cardiometabolic bioactivity is explored in detail. The special focus given to research on the health benefits of microbial-derived lignan metabolites underscores the critical role of lignan-rich diets in promoting cardiovascular health.

Girotto, Otávio Simões; Furlan, Otávio Oliveira; Moretti Junior, Renato Cesar; Goulart, Ricardo de Alvares; Baldi Junior, Edgar; Barbalho-Lamas, Caroline; Fornari Laurindo, Lucas; Barbalho, Sandra M.

doi: 10.1080/10408398.2024.2372690

Verma, Digvijay; Vashisht, Pranav; Pahariya, Prachi; Adu Poku, Felicia; Kohli, Punit; Sharma, Amandeep; Albiol Tapia, Marta; Choudhary, Ruplal

doi: 10.1080/10408398.2024.2373383pmid: 38973295

Abstract With the increased environmental concerns and health awareness among consumers, there has been a notable interest in plant-based dairy alternatives. The plant-based yogurt market has experienced rapid expansion in recent years. Due to challenges related to cultivation, higher cost of production and lower protein content researchers have explored the viability of pulse-based yogurt which has arisen as an economically and nutritionally abundant solution. This review aims to examine the feasibility of utilizing pulse protein for yogurt production. The nutritional, antinutritional, and functional characteristics of various pulses were discussed in detail, alongside the modifications in these properties during the various stages of yogurt manufacturing. The review also sheds light on pivotal findings from existing literature and outlines challenges associated with the production of pulse-based yogurt. Pulses have emerged as promising base materials for yogurt manufacturing due to their favorable nutritional and functional characteristics. Further, the fermentation process can effectively reduce antinutritional components and enhance digestibility. Nonetheless, variations in sensorial and rheological properties were noted when different types of pulses were employed. This issue can be addressed by employing suitable combinations to achieve the desired properties in pulse-based yogurt.