Time-Delayed Cold Gelation of Low-Ester Pectin and Gluten with CaCO<sub>3</sub> to Facilitate Manufacture of Raw-Fermented Vegan Sausage Analogs

Time-Delayed Cold Gelation of Low-Ester Pectin and Gluten with CaCO<sub>3</sub> to Facilitate Manufacture of Raw-Fermented Vegan Sausage Analogs

To advance the development of protein-rich plant-based foods, a novel binder system for vegan sausage alternatives without the requirement of heat application was investigated. This enables long-term ripening of plant-based analogs similar to traditional fermented meat or dairy products, allowing fo...

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Bibliographic Details
Main Authors: Maurice Koenig, Kai Ahlborn, Kurt Herrmann, Myriam Loeffler, Jochen Weiss
Format: Article
Language:English
Published: MDPI AG 2025-07-01
Series:Applied Sciences
Subjects:
meat analogs
plant-based sausage
hydrocolloids
fermentation
texture
Online Access:https://www.mdpi.com/2076-3417/15/15/8510
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Summary:To advance the development of protein-rich plant-based foods, a novel binder system for vegan sausage alternatives without the requirement of heat application was investigated. This enables long-term ripening of plant-based analogs similar to traditional fermented meat or dairy products, allowing for refined flavor and texture development. This was achieved by using a poorly water-soluble calcium source (calcium carbonate) to introduce calcium ions into a low-ester pectin—gluten matrix susceptible to crosslinking via divalent ions. The gelling reaction of pectin–gluten dispersions with Ca<sup>2+</sup> ions was time-delayed due to the gradual production of lactic acid during fermentation. Firm, sliceable matrices were formed, in which particulate substances such as texturized proteins and solid vegetable fat could be integrated, hence forming an unheated raw-fermented plant-based salami-type sausage model matrix which remained safe for consumption over 21 days of ripening. Gluten as well as pectin had a significant influence on the functional properties of the matrices, especially water holding capacity (increasing with higher pectin or gluten content), hardness (increasing with higher pectin or gluten content), tensile strength (increasing with higher pectin or gluten content) and cohesiveness (decreasing with higher pectin or gluten content). A combination of three simultaneously occurring effects was observed, modulating the properties of the matrices, namely, (a) an increase in gel strength due to increased pectin concentration forming more brittle gels, (b) an increase in gel strength with increasing gluten content forming more elastic gels and (c) interactions of low-ester pectin with the gluten network, with pectin addition causing increased aggregation of gluten, leading to strengthened networks.
ISSN:2076-3417

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