In vitro physicochemical, phytochemical and functional properties of fiber rich fractions derived from by-products of six fruits

Saikia, Snigdha; Mahanta, Charu Lata

doi:10.1007/s13197-015-2120-9

Cited by 36 publications

(17 citation statements)

References 26 publications

(24 reference statements)

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“…Saikia and Mahanta (2016) reported a water holding capacity of grape peels of 7.56 g/g, an oil holding capacity of 10.64 g/g, and a swelling of 9.40 mL/g, higher values being obtained for mandarin peels and lower for cellulose. High hydration properties of DFs are related to an improved fecal bulking process, whereas a good oil absorption capacity leads to a reduced fat absorption in intestine and an enhanced excretion, which may conduct to lower cholesterol values (Oladiran, 2018;Saikia & Mahanta, 2016). The grinding process affects the functional properties of fibers.…”

Section: Grape Byproducts Chemical Compositionmentioning

confidence: 99%

“…Water binding capacity of fibers is important for both physiological and technological points of view and is given by the hydroxyl groups (Maurya, Pandey, Rai, Porwal, & Rai, 2015;Oladiran , 2018). The hydration characteristics of fibers can be evaluated trough the water retention, swelling, and absorption capacities, the affinity for water depending on the number for hydroxyl groups and by default on the fiber source (Oladiran , 2018; Saikia & Mahanta, 2016). Water holding capacity of fibers is related to their processing, particle size, and physicochemical structure (Maurya et al, 2015;Zhao et al, 2015;Zhu, Du, & Li, 2014).…”

Section: Grape Byproducts Chemical Compositionmentioning

confidence: 99%

“…The oil retention capacity of fibers is of technological importance and it is influenced by the insoluble fibers content, particle size, overall charge density, hydrophilic nature, and dehydration method (Maurya et al, 2015;Zhao et al, 2015). Saikia and Mahanta (2016) reported a water holding capacity of grape peels of 7.56 g/g, an oil holding capacity of 10.64 g/g, and a swelling of 9.40 mL/g, higher values being obtained for mandarin peels and lower for cellulose. High hydration properties of DFs are related to an improved fecal bulking process, whereas a good oil absorption capacity leads to a reduced fat absorption in intestine and an enhanced excretion, which may conduct to lower cholesterol values (Oladiran, 2018;Saikia & Mahanta, 2016).…”

Section: Grape Byproducts Chemical Compositionmentioning

confidence: 99%

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Potential of grape byproducts as functional ingredients in baked goods and pasta

Iuga

Mironeasa

2020

Comp Rev Food Sci Food Safe

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Wine making industry generates high quantities of valuable byproducts that can be used to enhance foods in order to diminish the environmental impact and to obtain more economic benefits. Grape byproducts are rich in phenolic compounds and dietary fiber, which make them suitable to improve the nutritional value of bakery, pastry, and pasta products. The viscoelastic behavior of dough and the textural and the sensory characteristics of baked goods and pasta containing grape byproducts depend on the addition level and particle size. Thus, an optimal dose of a finer grape byproducts flour must be found in order to minimize the negative effects such as low loaf volume and undesirable sensory and textural characteristics they may have on the final product quality. In the same time, an enrichment of the nutritional and functional value of the product by increasing the fiber and antioxidant compounds contents is desired. The aim of this review was to summarize the effects of the chemical components of grape byproducts on the nutritional, functional, rheological, textural, physical, and sensory characteristics of the baked goods and pasta. Further researches about the impact of foods enriched with grape byproducts on the human health, about molecular interactions between components, and about the effects of grape pomace compounds on the shelf life of baked goods and pasta are recommended.

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Section: Grape Byproducts Chemical Compositionmentioning

confidence: 99%

Section: Grape Byproducts Chemical Compositionmentioning

confidence: 99%

Section: Grape Byproducts Chemical Compositionmentioning

confidence: 99%

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Potential of grape byproducts as functional ingredients in baked goods and pasta

Iuga

Mironeasa

2020

Comp Rev Food Sci Food Safe

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“…Additional sources will be exploited gradually; for example, there is a report of spent residue from cumin as a potential source of dietary fiber [22]. The dietary fibers obtained from different sources differ in total dietary fiber content, SDF content, physicochemical properties, and physiological properties [23].…”

Section: Definition and Classificationmentioning

confidence: 99%

Modification and Application of Dietary Fiber in Foods

Yang

Wang

et al. 2017

Journal of Chemistry

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Dietary fiber plays an important role in human health. The modification and application of dietary fiber in foods is reviewed with respect to definition and classification and methods for measurement, extraction, and modification of dietary fiber. The supplementation of dietary fiber for flour, meat, and dairy products is also reviewed. Finally, the benefits and risks of increasing consumption of dietary fiber are discussed.

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“…Previous research by our group (among many others) has consistently highlighted that non‐starch polysaccharide structure and source greatly impacts its effects on the digestive processes involved in the human gut . The impact of processing on the physicochemical properties of starch has been considered in much greater detail than other dietary polysaccharides, likely as a result of the high proportion of starch in many food products.…”

Section: Introductionmentioning

confidence: 99%

Starch digestion in the upper gastrointestinal tract of humans

Gill¹,

Wilcox

Pearson

et al. 2018

Starch Stärke

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Starch provides a large proportion of the dietary energy consumed worldwide. The breakdown of dietary starch is driven by α-amylase produced by the salivary glands and pancreatic acini and is completed by a range of brushborder bound enzymes. This enzymatic digestion is aided by mechanical and secretory actions of the gastrointestinal tract. The absorption of the resultant glucose in the small intestine is primarily driven by two separate transport proteins À SGLT1 and GLUT2. The control of processes that govern starch digestion is complex and still not fully understood, although it appears that the human gut has the ability to sense both glucose and non-sweet glucose oligomers. Recent work has also suggested that variations in the genes encoding for α-amylase also appear to be associated with health outcomes. The authors consider the physiological factors that govern starch digestion and absorption, consider other dietary factors that may impact on this process and attempt to highlight the limitations in current knowledge to help focus future research needs in relation to starch digestion the upper gastrointestinal tract.

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In vitro physicochemical, phytochemical and functional properties of fiber rich fractions derived from by-products of six fruits

Cited by 36 publications

References 26 publications

Potential of grape byproducts as functional ingredients in baked goods and pasta

Potential of grape byproducts as functional ingredients in baked goods and pasta

Modification and Application of Dietary Fiber in Foods

Starch digestion in the upper gastrointestinal tract of humans

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