Align resistant starch structures from plant-based foods with human gut microbiome for personalized health promotion

Resistant starch (RS) is beneficial for human health through its interactions with gut microbiota. However, the alignment between RS structures with gut microbiota profile and consequentially health benefits remain elusive. This review summarizes current understanding of RS complex structures and th...

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Published inCritical reviews in food science and nutrition Vol. 63; no. 15; pp. 2509 - 2520
Main Authors Li, Cheng, Hu, Yiming
Format Journal Article
LanguageEnglish
Published United States Taylor & Francis 11.06.2023
Taylor & Francis Ltd
Subjects
Algorithms
artificial intelligence
Bacteria
Customization
Digestive system
Feces
food science
Gastrointestinal Microbiome
Gastrointestinal tract
Gut microbiota
Health promotion
human health
Humans
in vitro fecal fermentation
Intestinal microflora
intestinal microorganisms
Intestine
Machine learning
Microbiomes
Microbiota
Microorganisms
nutrition
Plant-based foods
Resistant Starch
short-chain fatty acids
Small intestine
Starch
Starch - chemistry
Resistant starch
in vitro fecal fermentation
short-chain fatty acids
gut microbiota
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Abstract Resistant starch (RS) is beneficial for human health through its interactions with gut microbiota. However, the alignment between RS structures with gut microbiota profile and consequentially health benefits remain elusive. This review summarizes current understanding of RS complex structures and their interactions with the gut microbiota, aiming to highlight the possibility of manipulating RS structures for a targeted and predictable gut microbiota shift for human health in a personalized way. Current definition of RS types is strongly associated with starch digestion behaviors in small intestine, which does not precisely reflect their interactions with human gut microbiota. Distinct alterations of gut microbiota could be associated with the same RS type. The principles to describe the specificity of different RS structural characteristics in terms of aligning with human gut microbiota shift was proposed in this review, which could result in new definitions of RS types from the microbial perspectives. To consider the highly variable personal features, a machine-learning algorithm to integrate different personalized factors and better understand the complex interaction between RS and gut microbiota and its effects on individual health was explained. This review contains important information to bring interactions between RS and gut microbiota to translational practice.
AbstractList Resistant starch (RS) is beneficial for human health through its interactions with gut microbiota. However, the alignment between RS structures with gut microbiota profile and consequentially health benefits remain elusive. This review summarizes current understanding of RS complex structures and their interactions with the gut microbiota, aiming to highlight the possibility of manipulating RS structures for a targeted and predictable gut microbiota shift for human health in a personalized way. Current definition of RS types is strongly associated with starch digestion behaviors in small intestine, which does not precisely reflect their interactions with human gut microbiota. Distinct alterations of gut microbiota could be associated with the same RS type. The principles to describe the specificity of different RS structural characteristics in terms of aligning with human gut microbiota shift was proposed in this review, which could result in new definitions of RS types from the microbial perspectives. To consider the highly variable personal features, a machine-learning algorithm to integrate different personalized factors and better understand the complex interaction between RS and gut microbiota and its effects on individual health was explained. This review contains important information to bring interactions between RS and gut microbiota to translational practice.
Resistant starch (RS) is beneficial for human health through its interactions with gut microbiota. However, the alignment between RS structures with gut microbiota profile and consequentially health benefits remain elusive. This review summarizes current understanding of RS complex structures and their interactions with the gut microbiota, aiming to highlight the possibility of manipulating RS structures for a targeted and predictable gut microbiota shift for human health in a personalized way. Current definition of RS types is strongly associated with starch digestion behaviors in small intestine, which does not precisely reflect their interactions with human gut microbiota. Distinct alterations of gut microbiota could be associated with the same RS type. The principles to describe the specificity of different RS structural characteristics in terms of aligning with human gut microbiota shift was proposed in this review, which could result in new definitions of RS types from the microbial perspectives. To consider the highly variable personal features, a machine-learning algorithm to integrate different personalized factors and better understand the complex interaction between RS and gut microbiota and its effects on individual health was explained. This review contains important information to bring interactions between RS and gut microbiota to translational practice.Resistant starch (RS) is beneficial for human health through its interactions with gut microbiota. However, the alignment between RS structures with gut microbiota profile and consequentially health benefits remain elusive. This review summarizes current understanding of RS complex structures and their interactions with the gut microbiota, aiming to highlight the possibility of manipulating RS structures for a targeted and predictable gut microbiota shift for human health in a personalized way. Current definition of RS types is strongly associated with starch digestion behaviors in small intestine, which does not precisely reflect their interactions with human gut microbiota. Distinct alterations of gut microbiota could be associated with the same RS type. The principles to describe the specificity of different RS structural characteristics in terms of aligning with human gut microbiota shift was proposed in this review, which could result in new definitions of RS types from the microbial perspectives. To consider the highly variable personal features, a machine-learning algorithm to integrate different personalized factors and better understand the complex interaction between RS and gut microbiota and its effects on individual health was explained. This review contains important information to bring interactions between RS and gut microbiota to translational practice.
Author Hu, Yiming
Li, Cheng
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  organization: Department of Pathology, Zhongshan Hospital, Fudan University
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in vitro fecal fermentation
short-chain fatty acids
gut microbiota
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Snippet Resistant starch (RS) is beneficial for human health through its interactions with gut microbiota. However, the alignment between RS structures with gut...
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SubjectTerms Algorithms
artificial intelligence
Bacteria
Customization
Digestive system
Feces
food science
Gastrointestinal Microbiome
Gastrointestinal tract
Gut microbiota
Health promotion
human health
Humans
in vitro fecal fermentation
Intestinal microflora
intestinal microorganisms
Intestine
Machine learning
Microbiomes
Microbiota
Microorganisms
nutrition
Plant-based foods
Resistant Starch
short-chain fatty acids
Small intestine
Starch
Starch - chemistry
Title Align resistant starch structures from plant-based foods with human gut microbiome for personalized health promotion
URI https://www.tandfonline.com/doi/abs/10.1080/10408398.2021.1976722
https://www.ncbi.nlm.nih.gov/pubmed/34515592
https://www.proquest.com/docview/2811359386
https://www.proquest.com/docview/2572215872
https://www.proquest.com/docview/2834222669
Volume 63
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