Effects of Inulin and Oligofructose levels on survival of probiotic bacteria and sensory properties in synbiotic Doogh

فتحی آچاچلوئی, بهرام; احمدی, سعید

doi:10.22034/fr.2025.66802.1963

Effects of Inulin and Oligofructose levels on survival of probiotic bacteria and sensory properties in synbiotic Doogh

نوع مقاله : مقاله پژوهشی

نویسندگان

¹ گروه علوم و مهندسی صنایع غذایی، دانشکده کشاورزی و منابع طبیعی، دانشگاه محقق اردبیلی، اردبیل، ایران

² گروه علوم و مهندسی صنایع غذایی، دانشگاه آزاد واحد سراب، سراب، ایران

10.22034/fr.2025.66802.1963

چکیده

کلیدواژه‌ها

موضوعات

علوم و صنایع غذایی

عنوان مقاله [English]

Effects of Inulin and Oligofructose levels on survival of probiotic bacteria and sensory properties in synbiotic Doogh

نویسندگان [English]

Bahram Fathi-Achachlouei ¹
Saeid Ahmadi ²

¹ Department of Food Sciences and Technology, Faculty of Agriculture and Natural Resources, University of Mohaghegh Ardabili, Ardabil, Iran

² Department of Food Sciences and Technology, Azad University of Sarab, Sarab, Iran.

چکیده [English]

Abstract
The use of probiotic Doogh as one of the probiotic dairy products has become popular in Iran. Afterwards, adding probiotic bacteria and maintain their viability in Doogh can contribute in promoting consumers health. The purpose of current research was to deliberate the influences of inulin (1%, 2% and 3%w/w), oligofructose (1%, 2% and 3%w/w) and inulin- oligofructose (at a levels of 1-1%, 2-2% and 3-3% w/w) as a prebiotic components in comparison to control sample (without prebiotic) along with bacteria incorporated with Bifidobacterium lactis and Lactobacillus acidophilus as starter (1%) to manufacture synbiotic Doogh and to evaluate the physicochemical and sensorial properties, and the viable numbers of probiotic bacteria in the Doogh within storage period. SNF, Bif. lactis and L. acidophilus bacteria count and sensorial characteristics (taste and flavor attributes) were statistically (at the 95% level) different across the treatments. Further, Doogh containing 1% inulin and 1% oligofructose, were associated to the maximal and minimal viability of L. acidophilus on 21th storage day, respectively. Doogh including 2% inulin and control also, were related to the maximal and minimal viability of Bif. lactis, respectively. Overall, the results showed that using inulin and oligofructose could be produced a synbiotic Doogh containing probiotic bacteria with improved survival as a functional dairy drink.
Abstract
The use of probiotic Doogh as one of the probiotic dairy products has become popular in Iran. Afterwards, adding probiotic bacteria and maintain their viability in Doogh can contribute in promoting consumers health. The purpose of current research was to deliberate the influences of inulin (1%, 2% and 3%w/w), oligofructose (1%, 2% and 3%w/w) and inulin- oligofructose (at a levels of 1-1%, 2-2% and 3-3% w/w) as a prebiotic components in comparison to control sample (without prebiotic) along with bacteria incorporated with Bifidobacterium lactis and Lactobacillus acidophilus as starter (1%) to manufacture synbiotic Doogh and to evaluate the physicochemical and sensorial properties, and the viable numbers of probiotic bacteria in the Doogh within storage period. SNF, Bif. lactis and L. acidophilus bacteria count and sensorial characteristics (taste and flavor attributes) were statistically (at the 95% level) different across the treatments. Further, Doogh containing 1% inulin and 1% oligofructose, were associated to the maximal and minimal viability of L. acidophilus on 21th storage day, respectively. Doogh including 2% inulin and control also, were related to the maximal and minimal viability of Bif. lactis, respectively. Overall, the results showed that using inulin and oligofructose could be produced a synbiotic Doogh containing probiotic bacteria with improved survival as a functional dairy drink.
Abstract
The use of probiotic Doogh as one of the probiotic dairy products has become popular in Iran. Afterwards, adding probiotic bacteria and maintain their viability in Doogh can contribute in promoting consumers health. The purpose of current research was to deliberate the influences of inulin (1%, 2% and 3%w/w), oligofructose (1%, 2% and 3%w/w) and inulin- oligofructose (at a levels of 1-1%, 2-2% and 3-3% w/w) as a prebiotic components in comparison to control sample (without prebiotic) along with bacteria incorporated with Bifidobacterium lactis and Lactobacillus acidophilus as starter (1%) to manufacture synbiotic Doogh and to evaluate the physicochemical and sensorial properties, and the viable numbers of probiotic bacteria in the Doogh within storage period. SNF, Bif. lactis and L. acidophilus bacteria count and sensorial characteristics (taste and flavor attributes) were statistically (at the 95% level) different across the treatments. Further, Doogh containing 1% inulin and 1% oligofructose, were associated to the maximal and minimal viability of L. acidophilus on 21th storage day, respectively. Doogh including 2% inulin and control also, were related to the maximal and minimal viability of Bif. lactis, respectively. Overall, the results showed that using inulin and oligofructose could be produced a synbiotic Doogh containing probiotic bacteria with improved survival as a functional dairy drink.
Abstract
The use of probiotic Doogh as one of the probiotic dairy products has become popular in Iran. Afterwards, adding probiotic bacteria and maintain their viability in Doogh can contribute in promoting consumers health. The purpose of current research was to deliberate the influences of inulin (1%, 2% and 3%w/w), oligofructose (1%, 2% and 3%w/w) and inulin- oligofructose (at a levels of 1-1%, 2-2% and 3-3% w/w) as a prebiotic components in comparison to control sample (without prebiotic) along with bacteria incorporated with Bifidobacterium lactis and Lactobacillus acidophilus as starter (1%) to manufacture synbiotic Doogh and to evaluate the physicochemical and sensorial properties, and the viable numbers of probiotic bacteria in the Doogh within storage period. SNF, Bif. lactis and L. acidophilus bacteria count and sensorial characteristics (taste and flavor attributes) were statistically (at the 95% level) different across the treatments. Further, Doogh containing 1% inulin and 1% oligofructose, were associated to the maximal and minimal viability of L. acidophilus on 21th storage day, respectively. Doogh including 2% inulin and control also, were related to the maximal and minimal viability of Bif. lactis, respectively. Overall, the results showed that using inulin and oligofructose could be produced a synbiotic Doogh containing probiotic bacteria with improved survival as a functional dairy drink.
Abstract
The use of probiotic Doogh as one of the probiotic dairy products has become popular in Iran. Afterwards, adding probiotic bacteria and maintain their viability in Doogh can contribute in promoting consumers health. The purpose of current research was to deliberate the influences of inulin (1%, 2% and 3%w/w), oligofructose (1%, 2% and 3%w/w) and inulin- oligofructose (at a levels of 1-1%, 2-2% and 3-3% w/w) as a prebiotic components in comparison to control sample (without prebiotic) along with bacteria incorporated with Bifidobacterium lactis and Lactobacillus acidophilus as starter (1%) to manufacture synbiotic Doogh and to evaluate the physicochemical and sensorial properties, and the viable numbers of probiotic bacteria in the Doogh within storage period. SNF, Bif. lactis and L. acidophilus bacteria count and sensorial characteristics (taste and flavor attributes) were statistically (at the 95% level) different across the treatments. Further, Doogh containing 1% inulin and 1% oligofructose, were associated to the maximal and minimal viability of L. acidophilus on 21th storage day, respectively. Doogh including 2% inulin and control also, were related to the maximal and minimal viability of Bif. lactis, respectively. Overall, the results showed that using inulin and oligofructose could be produced a synbiotic Doogh containing probiotic bacteria with improved survival as a functional dairy drink.
Abstract
The use of probiotic Doogh as one of the probiotic dairy products has become popular in Iran. Afterwards, adding probiotic bacteria and maintain their viability in Doogh can contribute in promoting consumers health. The purpose of current research was to deliberate the influences of inulin (1%, 2% and 3%w/w), oligofructose (1%, 2% and 3%w/w) and inulin- oligofructose (at a levels of 1-1%, 2-2% and 3-3% w/w) as a prebiotic components in comparison to control sample (without prebiotic) along with bacteria incorporated with Bifidobacterium lactis and Lactobacillus acidophilus as starter (1%) to manufacture synbiotic Doogh and to evaluate the physicochemical and sensorial properties, and the viable numbers of probiotic bacteria in the Doogh within storage period. SNF, Bif. lactis and L. acidophilus bacteria count and sensorial characteristics (taste and flavor attributes) were statistically (at the 95% level) different across the treatments. Further, Doogh containing 1% inulin and 1% oligofructose, were associated to the maximal and minimal viability of L. acidophilus on 21th storage day, respectively. Doogh including 2% inulin and control also, were related to the maximal and minimal viability of Bif. lactis, respectively. Overall, the results showed that using inulin and oligofructose could be produced a synbiotic Doogh containing probiotic bacteria with improved survival as a functional dairy drink.
Abstract
The use of probiotic Doogh as one of the probiotic dairy products has become popular in Iran. Afterwards, adding probiotic bacteria and maintain their viability in Doogh can contribute in promoting consumers health. The purpose of current research was to deliberate the influences of inulin (1%, 2% and 3%w/w), oligofructose (1%, 2% and 3%w/w) and inulin- oligofructose (at a levels of 1-1%, 2-2% and 3-3% w/w) as a prebiotic components in comparison to control sample (without prebiotic) along with bacteria incorporated with Bifidobacterium lactis and Lactobacillus acidophilus as starter (1%) to manufacture synbiotic Doogh and to evaluate the physicochemical and sensorial properties, and the viable numbers of probiotic bacteria in the Doogh within storage period. SNF, Bif. lactis and L. acidophilus bacteria count and sensorial characteristics (taste and flavor attributes) were statistically (at the 95% level) different across the treatments. Further, Doogh containing 1% inulin and 1% oligofructose, were associated to the maximal and minimal viability of L. acidophilus on 21th storage day, respectively. Doogh including 2% inulin and control also, were related to the maximal and minimal viability of Bif. lactis, respectively. Overall, the results showed that using inulin and oligofructose could be produced a synbiotic Doogh containing probiotic bacteria with improved survival as a functional dairy drink.
Abstract
The use of probiotic Doogh as one of the probiotic dairy products has become popular in Iran. Afterwards, adding probiotic bacteria and maintain their viability in Doogh can contribute in promoting consumers health. The purpose of current research was to deliberate the influences of inulin (1%, 2% and 3%w/w), oligofructose (1%, 2% and 3%w/w) and inulin- oligofructose (at a levels of 1-1%, 2-2% and 3-3% w/w) as a prebiotic components in comparison to control sample (without prebiotic) along with bacteria incorporated with Bifidobacterium lactis and Lactobacillus acidophilus as starter (1%) to manufacture synbiotic Doogh and to evaluate the physicochemical and sensorial properties, and the viable numbers of probiotic bacteria in the Doogh within storage period. SNF, Bif. lactis and L. acidophilus bacteria count and sensorial characteristics (taste and flavor attributes) were statistically (at the 95% level) different across the treatments. Further, Doogh containing 1% inulin and 1% oligofructose, were associated to the maximal and minimal viability of L. acidophilus on 21th storage day, respectively. Doogh including 2% inulin and control also, were related to the maximal and minimal viability of Bif. lactis, respectively. Overall, the results showed that using inulin and oligofructose could be produced a synbiotic Doogh containing probiotic bacteria with improved survival as a functional dairy drink.

کلیدواژه‌ها [English]

Keywords: Doogh
Inulin
Oligofructose
Probiotic bacteria

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Effects of Inulin and Oligofructose levels on survival of probiotic bacteria and sensory properties in synbiotic Doogh

Effects of Inulin and Oligofructose levels on survival of probiotic bacteria and sensory properties in synbiotic Doogh

مراجع

دوره 35، شماره 3
مهر 1404
صفحه 1-11

فایل ها

هم رسانی

ارجاع به این مقاله

آمار

Effects of Inulin and Oligofructose levels on survival of probiotic bacteria and sensory properties in synbiotic Doogh

Effects of Inulin and Oligofructose levels on survival of probiotic bacteria and sensory properties in synbiotic Doogh

مراجع

دوره 35، شماره 3مهر 1404صفحه 1-11

فایل ها

هم رسانی

ارجاع به این مقاله

آمار

دوره 35، شماره 3
مهر 1404
صفحه 1-11