TY - JOUR
T1 - How high hydrostatic pressure treatment modifies the physicochemical and nutritional attributes of polysaccharides?
AU - Rostamabadi, Hadis
AU - Can Karaca, Asli
AU - Nowacka, Małgorzata
AU - Mulla, Mehrajfatema Z.
AU - Al-attar, Hasan
AU - Rathnakumar, Kaavya
AU - Gultekin Subasi, Busra
AU - Sehrawat, Rachna
AU - Kheto, Ankan
AU - Falsafi, Seid Reza
N1 - Publisher Copyright:
© 2022 Elsevier Ltd
PY - 2023/4
Y1 - 2023/4
N2 - Polysaccharides, as natural, biodegradable, biocompatible, non-allergen, and non-toxic polymers, have been utilized as potent ingredients in various food and pharmaceutical applications owing to their outstanding aptitude in stabilizing emulsions/foams as well as generating gels/films/viscous dispersions. However, apart from these unique attributes, the widespread application of polysaccharides has been challenged by some obstacles resulted from their low thermal/shear resistibility, retrogradability as well as diminished gel/paste transparency. Hitherto, to tackle these shortcomings various enzymatic, chemical, and physical modification approaches have been developed. Taking advantages from being both a physical and non-thermal approach, High hydrostatic pressure (HHP) has been a promising tool for introducing novel applications to the realm of food. HHP is a compelling approach capable of manipulating structure and physicochemical attributes of polysaccharides comparable to the conventional thermal/chemical methods. It also demonstrated a prodigious potential in enhancing the nutritional attributes of modified components either through preserving the thermo-sensitive ingredients or enhancing the resistant starch content of starches. Accordingly, the application of HHP for manipulating chemical, physical, technofunctional and nutritional characteristics of various polysaccharides has been the focus of numerous researches. The basic theory of HHP as well as its influence on different physicochemical/nutritional attributes of polysaccharides are reviewed in this study, in detail.
AB - Polysaccharides, as natural, biodegradable, biocompatible, non-allergen, and non-toxic polymers, have been utilized as potent ingredients in various food and pharmaceutical applications owing to their outstanding aptitude in stabilizing emulsions/foams as well as generating gels/films/viscous dispersions. However, apart from these unique attributes, the widespread application of polysaccharides has been challenged by some obstacles resulted from their low thermal/shear resistibility, retrogradability as well as diminished gel/paste transparency. Hitherto, to tackle these shortcomings various enzymatic, chemical, and physical modification approaches have been developed. Taking advantages from being both a physical and non-thermal approach, High hydrostatic pressure (HHP) has been a promising tool for introducing novel applications to the realm of food. HHP is a compelling approach capable of manipulating structure and physicochemical attributes of polysaccharides comparable to the conventional thermal/chemical methods. It also demonstrated a prodigious potential in enhancing the nutritional attributes of modified components either through preserving the thermo-sensitive ingredients or enhancing the resistant starch content of starches. Accordingly, the application of HHP for manipulating chemical, physical, technofunctional and nutritional characteristics of various polysaccharides has been the focus of numerous researches. The basic theory of HHP as well as its influence on different physicochemical/nutritional attributes of polysaccharides are reviewed in this study, in detail.
KW - Biopolymers
KW - Carbohydrates
KW - High pressure processing
KW - Non-thermal processing
KW - Physical modification
KW - Technofunctional characteristics
UR - http://www.scopus.com/inward/record.url?scp=85143706191&partnerID=8YFLogxK
U2 - 10.1016/j.foodhyd.2022.108375
DO - 10.1016/j.foodhyd.2022.108375
M3 - Review article
AN - SCOPUS:85143706191
SN - 0268-005X
VL - 137
JO - Food Hydrocolloids
JF - Food Hydrocolloids
M1 - 108375
ER -