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12 May 2022
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Published:
12 May 2022
A review on food oral tribology
Min ZHONG(
)
)
Keywords:
food oral tribology, in vitro friction tests, lubrication behavior, Stribeck curve, sensory perception, food development and detection
Cite this article:
XU W, YU S, ZHONG M.
A review on food oral tribology.
Friction,
2022, 10(12): 1927-1966.
https://doi.org/10.1007/s40544-022-0594-9
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Food entering the oral cavity undergoes a series of complex processing behaviors. It is subjected to compression and shearing by the teeth, tongue, and palate to reduce its size and mix with saliva until it is swallowed. The oral processing behaviors are thought to be closely related to both food and oral frictional properties. Much effort has been made in recent decades about food oral tribology to explore this complicated lubrication behavior. Understanding the lubrication mechanism of food in the mouth is important for improving the consumption experience and developing the novel food. This paper provides a new perspective on the effects of composition, texture, structure, and saliva-food component interactions on lubrication properties of different foods, the relationship between sensory perception and oral frictional behavior, and the mechanism and pattern of lubrication categorized by common food types. The roles of tribology in the improvement of food taste, the search for healthier ingredient substitutes, functional foods, and the development of green foods are analyzed. Conceptual and numerical prediction models among physical properties, sensory perception, and frictional behavior of food are discussed. Studies of simulating oral processing, such as the selection of friction pair materials, physical modification of contact surfaces, addition of saliva, different modes of motion, and contact forms are concluded and classified. The progress of commercial friction apparatus as well as customized friction devices applied to the food sector in recent years are described. The characteristics, performances, and applications of these tribological instruments are analyzed and compared. In addition, the results achieved by oral tribology in identifying adulterated foods and ensuring food safety are presented. Finally, some suggestions are put forward for the current challenges and future development of food oral tribology.
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A review on food oral tribology
Min ZHONG(
)
)
Abstract
Food entering the oral cavity undergoes a series of complex processing behaviors. It is subjected to compression and shearing by the teeth, tongue, and palate to reduce its size and mix with saliva until it is swallowed. The oral processing behaviors are thought to be closely related to both food and oral frictional properties. Much effort has been made in recent decades about food oral tribology to explore this complicated lubrication behavior. Understanding the lubrication mechanism of food in the mouth is important for improving the consumption experience and developing the novel food. This paper provides a new perspective on the effects of composition, texture, structure, and saliva-food component interactions on lubrication properties of different foods, the relationship between sensory perception and oral frictional behavior, and the mechanism and pattern of lubrication categorized by common food types. The roles of tribology in the improvement of food taste, the search for healthier ingredient substitutes, functional foods, and the development of green foods are analyzed. Conceptual and numerical prediction models among physical properties, sensory perception, and frictional behavior of food are discussed. Studies of simulating oral processing, such as the selection of friction pair materials, physical modification of contact surfaces, addition of saliva, different modes of motion, and contact forms are concluded and classified. The progress of commercial friction apparatus as well as customized friction devices applied to the food sector in recent years are described. The characteristics, performances, and applications of these tribological instruments are analyzed and compared. In addition, the results achieved by oral tribology in identifying adulterated foods and ensuring food safety are presented. Finally, some suggestions are put forward for the current challenges and future development of food oral tribology.
Keywords:
food oral tribology, in vitro friction tests, lubrication behavior, Stribeck curve, sensory perception, food development and detection
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Publication history
Received: 03 September 2021
Revised: 22 November 2021
Accepted: 08 January 2022
Published:
12 May 2022
Issue date: December 2022
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© The author(s) 2022.
Acknowledgements
This work was supported by the National Natural Science Foundation of China (No. 51965039).
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