Replacing Animal Fat with Gels of Psyllium Fiber and Combined Linseed Oil–Psyllium Fiber in Salamis: Impacts on Technological, Nutritional, Oxidative, and Sensory Properties

This study produced two gels: one solely using psyllium fiber (GP) and another combining this fiber with linseed oil (GL+P). Both gels replaced 15% and 30% of the animal fat content of salamis. The objective was to evaluate the impact of this lipid reformulation on the technological, nutritional, ox...
Ausführliche Beschreibung

Gespeichert in:

Autor*in:	Marcos Roberto Casarin Jovanovichs [verfasserIn] Mariana Basso Pinton [verfasserIn] Leticia Pereira Correa [verfasserIn] Douglas Pedro [verfasserIn] Carlos Augusto Mallmann [verfasserIn] Roger Wagner [verfasserIn] Alexandre José Cichoski [verfasserIn] José Manuel Lorenzo [verfasserIn] Alfredo Jorge Costa Teixeira [verfasserIn] Paulo Cezar Bastianello Campagnol [verfasserIn] Bibiana Alves dos Santos [verfasserIn]

Format:	E-Artikel
Sprache:	Englisch

Erschienen:	2023

Schlagwörter:	lipid reformulation bioactive compounds lipid oxidation volatile compounds sensory profile

Übergeordnetes Werk:	In: Foods - MDPI AG, 2013, 12(2023), 13, p 2439
Übergeordnetes Werk:	volume:12 ; year:2023 ; number:13, p 2439

Links:	Link aufrufen Link aufrufen Link aufrufen Journal toc

DOI / URN:	10.3390/foods12132439

Katalog-ID:	DOAJ094017530

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language	English
source	In Foods 12(2023), 13, p 2439 volume:12 year:2023 number:13, p 2439
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authorswithroles_txt_mv	Marcos Roberto Casarin Jovanovichs @@aut@@ Mariana Basso Pinton @@aut@@ Leticia Pereira Correa @@aut@@ Douglas Pedro @@aut@@ Carlos Augusto Mallmann @@aut@@ Roger Wagner @@aut@@ Alexandre José Cichoski @@aut@@ José Manuel Lorenzo @@aut@@ Alfredo Jorge Costa Teixeira @@aut@@ Paulo Cezar Bastianello Campagnol @@aut@@ Bibiana Alves dos Santos @@aut@@
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callnumber-first	T - Technology
author	Marcos Roberto Casarin Jovanovichs
spellingShingle	Marcos Roberto Casarin Jovanovichs misc TP1-1185 misc lipid reformulation misc bioactive compounds misc lipid oxidation misc volatile compounds misc sensory profile misc Chemical technology Replacing Animal Fat with Gels of Psyllium Fiber and Combined Linseed Oil–Psyllium Fiber in Salamis: Impacts on Technological, Nutritional, Oxidative, and Sensory Properties
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topic_title	TP1-1185 Replacing Animal Fat with Gels of Psyllium Fiber and Combined Linseed Oil–Psyllium Fiber in Salamis: Impacts on Technological, Nutritional, Oxidative, and Sensory Properties lipid reformulation bioactive compounds lipid oxidation volatile compounds sensory profile
topic	misc TP1-1185 misc lipid reformulation misc bioactive compounds misc lipid oxidation misc volatile compounds misc sensory profile misc Chemical technology
topic_unstemmed	misc TP1-1185 misc lipid reformulation misc bioactive compounds misc lipid oxidation misc volatile compounds misc sensory profile misc Chemical technology
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title	Replacing Animal Fat with Gels of Psyllium Fiber and Combined Linseed Oil–Psyllium Fiber in Salamis: Impacts on Technological, Nutritional, Oxidative, and Sensory Properties
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title_full	Replacing Animal Fat with Gels of Psyllium Fiber and Combined Linseed Oil–Psyllium Fiber in Salamis: Impacts on Technological, Nutritional, Oxidative, and Sensory Properties
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author_browse	Marcos Roberto Casarin Jovanovichs Mariana Basso Pinton Leticia Pereira Correa Douglas Pedro Carlos Augusto Mallmann Roger Wagner Alexandre José Cichoski José Manuel Lorenzo Alfredo Jorge Costa Teixeira Paulo Cezar Bastianello Campagnol Bibiana Alves dos Santos
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title_sort	replacing animal fat with gels of psyllium fiber and combined linseed oil–psyllium fiber in salamis: impacts on technological, nutritional, oxidative, and sensory properties
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title_auth	Replacing Animal Fat with Gels of Psyllium Fiber and Combined Linseed Oil–Psyllium Fiber in Salamis: Impacts on Technological, Nutritional, Oxidative, and Sensory Properties
abstract	This study produced two gels: one solely using psyllium fiber (GP) and another combining this fiber with linseed oil (GL+P). Both gels replaced 15% and 30% of the animal fat content of salamis. The objective was to evaluate the impact of this lipid reformulation on the technological, nutritional, oxidative, and sensory properties of the salamis. The lipid reformulation did not alter the evolution of pH and lactic acid bacteria during processing. The addition of GL+P did not interfere with the product’s drying process. However, replacing 30% of animal fat with the GP resulted in greater weight loss and a lower final Aw value. The lipid reformulation minimally affected the color of the salamis but significantly enhanced their nutritional profile. This improvement was marked by a decrease in fat content and an increase in protein. Specifically, in the samples with GL+P, there was a rise in linolenic acid content and a reduction in the n-6/n-3 PUFA ratio. Adding GP did not affect the salamis’ oxidative stability and sensory profile. However, substituting 30% of the animal fat with GL+P increased the TBARS values, and volatile compounds derived from lipid oxidation hampered the products’ sensory profiles. A reduction in these negative effects was observed when replacing 15% of the fat with GL+P, suggesting this to be the ideal dosage for balancing the nutritional benefits with maintaining the product’s oxidative stability.
abstractGer	This study produced two gels: one solely using psyllium fiber (GP) and another combining this fiber with linseed oil (GL+P). Both gels replaced 15% and 30% of the animal fat content of salamis. The objective was to evaluate the impact of this lipid reformulation on the technological, nutritional, oxidative, and sensory properties of the salamis. The lipid reformulation did not alter the evolution of pH and lactic acid bacteria during processing. The addition of GL+P did not interfere with the product’s drying process. However, replacing 30% of animal fat with the GP resulted in greater weight loss and a lower final Aw value. The lipid reformulation minimally affected the color of the salamis but significantly enhanced their nutritional profile. This improvement was marked by a decrease in fat content and an increase in protein. Specifically, in the samples with GL+P, there was a rise in linolenic acid content and a reduction in the n-6/n-3 PUFA ratio. Adding GP did not affect the salamis’ oxidative stability and sensory profile. However, substituting 30% of the animal fat with GL+P increased the TBARS values, and volatile compounds derived from lipid oxidation hampered the products’ sensory profiles. A reduction in these negative effects was observed when replacing 15% of the fat with GL+P, suggesting this to be the ideal dosage for balancing the nutritional benefits with maintaining the product’s oxidative stability.
abstract_unstemmed	This study produced two gels: one solely using psyllium fiber (GP) and another combining this fiber with linseed oil (GL+P). Both gels replaced 15% and 30% of the animal fat content of salamis. The objective was to evaluate the impact of this lipid reformulation on the technological, nutritional, oxidative, and sensory properties of the salamis. The lipid reformulation did not alter the evolution of pH and lactic acid bacteria during processing. The addition of GL+P did not interfere with the product’s drying process. However, replacing 30% of animal fat with the GP resulted in greater weight loss and a lower final Aw value. The lipid reformulation minimally affected the color of the salamis but significantly enhanced their nutritional profile. This improvement was marked by a decrease in fat content and an increase in protein. Specifically, in the samples with GL+P, there was a rise in linolenic acid content and a reduction in the n-6/n-3 PUFA ratio. Adding GP did not affect the salamis’ oxidative stability and sensory profile. However, substituting 30% of the animal fat with GL+P increased the TBARS values, and volatile compounds derived from lipid oxidation hampered the products’ sensory profiles. A reduction in these negative effects was observed when replacing 15% of the fat with GL+P, suggesting this to be the ideal dosage for balancing the nutritional benefits with maintaining the product’s oxidative stability.
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title_short	Replacing Animal Fat with Gels of Psyllium Fiber and Combined Linseed Oil–Psyllium Fiber in Salamis: Impacts on Technological, Nutritional, Oxidative, and Sensory Properties
url	https://doi.org/10.3390/foods12132439 https://doaj.org/article/bd68bca2033f49f9b2f1c4775e15e421 https://www.mdpi.com/2304-8158/12/13/2439 https://doaj.org/toc/2304-8158
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author2	Mariana Basso Pinton Leticia Pereira Correa Douglas Pedro Carlos Augusto Mallmann Roger Wagner Alexandre José Cichoski José Manuel Lorenzo Alfredo Jorge Costa Teixeira Paulo Cezar Bastianello Campagnol Bibiana Alves dos Santos
author2Str	Mariana Basso Pinton Leticia Pereira Correa Douglas Pedro Carlos Augusto Mallmann Roger Wagner Alexandre José Cichoski José Manuel Lorenzo Alfredo Jorge Costa Teixeira Paulo Cezar Bastianello Campagnol Bibiana Alves dos Santos
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up_date	2024-07-03T20:46:27.118Z
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Replacing Animal Fat with Gels of Psyllium Fiber and Combined Linseed Oil–Psyllium Fiber in Salamis: Impacts on Technological, Nutritional, Oxidative, and Sensory Properties

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