{"title":"The Role of Food Structure in the Biophysics of Digestion: The Remarkable Coevolution of the Casein Micelle","authors":"Michael A. Rogers","doi":"10.1007/s11483-024-09882-2","DOIUrl":null,"url":null,"abstract":"<div><p>There is more to nutrition than food composition, and the biophysics of food structures, from the nanoscale to microscale, regulates and controls the release of macro- and micro-nutrients, bioactives and phytochemicals. As diets shift from whole foods to including more ultra-processed foods (UPFs) or UPFs designed to mimic whole foods (plant-based milk, cheese and cellular meat), research must focus not only on the sensory and organoleptic appeal but also on the postprandial responses, satiety and on satiation. For example, plant-based milk and cheese are visually similar to their dairy equivalent, yet they lack highly phosphorylated casein micelle calcium nanoclusters. The coevolution of the casein micelle highlights the role structure plays in digestion as chymosin preferentially cleaves κ-casein at the 105-106 phe-met bond, which destabilizes the micelle surface and curdles milk into solid cheese, altering subsequent digestive kinetics, postprandial response and satiety. Food structures designed to slow digestion and their postprandial response are reinventing ingredient isolate, emphasizing the inclusion of intact plant cells in UPFs. With every intended trait imparted to the food, unintended consequences may alter satiety, food choice and postprandial responses and must constantly be reevaluated.</p></div>","PeriodicalId":564,"journal":{"name":"Food Biophysics","volume":"19 4","pages":"845 - 851"},"PeriodicalIF":2.8000,"publicationDate":"2024-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Food Biophysics","FirstCategoryId":"97","ListUrlMain":"https://link.springer.com/article/10.1007/s11483-024-09882-2","RegionNum":4,"RegionCategory":"农林科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"FOOD SCIENCE & TECHNOLOGY","Score":null,"Total":0}
引用次数: 0
Abstract
There is more to nutrition than food composition, and the biophysics of food structures, from the nanoscale to microscale, regulates and controls the release of macro- and micro-nutrients, bioactives and phytochemicals. As diets shift from whole foods to including more ultra-processed foods (UPFs) or UPFs designed to mimic whole foods (plant-based milk, cheese and cellular meat), research must focus not only on the sensory and organoleptic appeal but also on the postprandial responses, satiety and on satiation. For example, plant-based milk and cheese are visually similar to their dairy equivalent, yet they lack highly phosphorylated casein micelle calcium nanoclusters. The coevolution of the casein micelle highlights the role structure plays in digestion as chymosin preferentially cleaves κ-casein at the 105-106 phe-met bond, which destabilizes the micelle surface and curdles milk into solid cheese, altering subsequent digestive kinetics, postprandial response and satiety. Food structures designed to slow digestion and their postprandial response are reinventing ingredient isolate, emphasizing the inclusion of intact plant cells in UPFs. With every intended trait imparted to the food, unintended consequences may alter satiety, food choice and postprandial responses and must constantly be reevaluated.
期刊介绍:
Biophysical studies of foods and agricultural products involve research at the interface of chemistry, biology, and engineering, as well as the new interdisciplinary areas of materials science and nanotechnology. Such studies include but are certainly not limited to research in the following areas: the structure of food molecules, biopolymers, and biomaterials on the molecular, microscopic, and mesoscopic scales; the molecular basis of structure generation and maintenance in specific foods, feeds, food processing operations, and agricultural products; the mechanisms of microbial growth, death and antimicrobial action; structure/function relationships in food and agricultural biopolymers; novel biophysical techniques (spectroscopic, microscopic, thermal, rheological, etc.) for structural and dynamical characterization of food and agricultural materials and products; the properties of amorphous biomaterials and their influence on chemical reaction rate, microbial growth, or sensory properties; and molecular mechanisms of taste and smell.
A hallmark of such research is a dependence on various methods of instrumental analysis that provide information on the molecular level, on various physical and chemical theories used to understand the interrelations among biological molecules, and an attempt to relate macroscopic chemical and physical properties and biological functions to the molecular structure and microscopic organization of the biological material.