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Prebiotic (nutrition)

February 16, 2024

Not to be confused with Probiotics, microorganisms typically found in fermented foods.

Prebiotics are compounds in food that foster growth or activity of beneficial microorganisms such as bacteria and fungi.[1] The most common environment considered is the gastrointestinal tract, where prebiotics can alter the composition of organisms in the gut microbiome.

Dietary prebiotics are typically nondigestible fiber compounds that pass undigested through the upper part of the gastrointestinal tract and help growth or activity of advantageous bacteria in the colon by acting as substrates for them.[1] They were first identified and named by Marcel Roberfroid in 1995.[1][2] Depending on the jurisdiction, they may have regulatory scrutiny as food additives for the health claims made for marketing purposes. Common prebiotics used in food manufacturing include beta-glucan from oats, resistant starch from grains and beans, and inulin from chicory root.

Definition edit

The definition of prebiotics and the food ingredients that can fall under this classification, has evolved since its first definition in 1995.[3] In its earliest definition, the term prebiotics was used to refer to non-digestible food ingredients that were beneficial to the host through their selective stimulation of specific bacteria within the colon.[3][4] Further research has suggested that selective stimulation has not been scientifically demonstrated.[5] As a result of research suggesting that prebiotics could impact microorganisms outside of the colon, in 2016 the International Scientific Association for Probiotics and Prebiotics (ISAPP) produced the following definition of prebiotics: a substrate that is selectively used by a host microorganism to produce a health benefit.[3] In 2021, The Global Prebiotic Association (GPA) defined a prebiotic as a product or ingredient that is utilized in the microbiota producing a health or performance benefit.[6]

Compounds that can be classified as prebiotics must also meet the following criteria:[3][4][6]

  • non-digestible and resistant to breakdown by stomach acid and enzymes in the human gastrointestinal tract
  • fermented by microorganisms on or in the body
  • stimulating growth and activity of beneficial bacteria

Thus, consumption of prebiotics may facilitate the health of the host.[7] Based on the previous classifications, plant-derived carbohydrate compounds called oligosaccharides as well as resistant starch are the main source of prebiotics that have been identified.[8][4][9][10] Specifically, fructans and galactans are two oligosaccharide sources which have been found to stimulate the activity and growth of beneficial bacterial colonies in the gut.[7][3] Fructans are a category of carbohydrate consisting of fructooligosaccharides (FOS) and inulins, while galactans consist of galactooligosaccharides.[3] Resistant starch has been shown to shift the intestinal bacteria, as well as improve biomarkers for numerous health conditions.[11][12][13] Other dietary fibers also fit the definition of prebiotics, such as pectin,[14] beta-glucans,[15] and xylooligosaccharides.[16]

The European Food Safety Authority (EFSA), the regulatory agency for product labeling, differentiates between "prebiotic" and "dietary fiber", stating that "a cause and effect relationship has not been established between the consumption of the food constituents which are the subject of the health claims and a beneficial physiological effect related to increasing numbers of gastrointestinal microbiota".[17] Consequently, under EFSA rules individual ingredients cannot be labeled as prebiotics, but only as dietary fiber and with no implication of health benefits.[17]

Function edit

When the prebiotic concept was first introduced in 1995, the primary focus was on the effects that prebiotics confer on Bifidobacteria and Lactobacillus.[3][4][18] With improved mechanistic techniques in recent years, the current prebiotic targets have expanded to a wider range of microbes, including Roseburia spp., Eubacterium spp., Akkermansia spp., Christensenella spp., Propionibacterium spp. and Faecalibacterium spp.[19] These bacteria have been highlighted as key probiotics and beneficial gut bacteria as they may have several beneficial effects on the host in terms of improving digestion (including but not limited to enhancing mineral absorption)[20] and the effectiveness and intrinsic strength of the immune system.[21] Both Bifidobacteria and Lactobacillus have been shown to have differing prebiotic specificity and to selectively ferment prebiotic fiber based on the enzymes characteristic of the bacterial population.[22] Thus, Lactobacilli prefer inulin and fructooligosaccharides, while Bifidobacteria display specificity for inulin, fructooligosaccharides, xylooligosaccharides and galactooligosaccharides.[22] Studies have also shown that prebiotics, besides helping growth of beneficial gut bacteria, can also inhibit detrimental and potentially pathogenic microbes in the gut,[9][4] such as clostridia.[4]

Mechanism of action edit

Fermentation is the main mechanism of action by which prebiotics are used by beneficial bacteria in the colon.[7][4] Both Bifidobacteria and Lactobacillus are bacterial populations which use saccharolytic metabolism to break down substrates.[4] The bifidobacterial genome contains many genes that encode for carbohydrate-modifying enzymes as well as genes that encode for carbohydrate uptake proteins. The presence of these genes indicates that Bifidobacteria contain specific metabolic pathways specialized for the fermentation and metabolism of plant-derived oligosaccharides, or prebiotics. These pathways in Bifidobacteria ultimately produce short chain fatty acids,[4][7] which have diverse physiological roles in body functions.[23][3]

Sources edit

Prebiotic sources must be proven to confer a benefit to the host in order to be classified as a prebiotic.[3] Fermentable carbohydrates derived from fructans and xylans are one well documented example of prebiotics.[3] Resistant starch from starchy foods are also well documented prebiotics and have historically been the highest source of prebiotics in the diet, as 4-10% of starch in mixed diets has been shown to reach the large intestine.[24] One study reported that individuals consuming a traditional diet in Africa consumed 38 grams of resistant starch/day.[25]

Endogenous edit

An endogenous source of prebiotics in humans is human breast milk, which contains oligosaccharides structurally similar to galactooligosaccharides, referred to as human milk oligosaccharides.[26][9][22][3] Human milk oligosaccharides were found to increase the Bifidobacteria bacterial population in breastfed infants, and to strengthen the infant immune system.[3][9] Furthermore, human milk oligosaccharides help establish a healthy intestinal microbiota composition in newborns.[3]

Exogenous edit

Indigestible carbohydrate compounds classified as prebiotics are a type of fermentable fiber, and thus can be classified as dietary fiber.[4] However, not all dietary fiber can be classified as a prebiotic source.[4] In addition to the food sources highlighted in the following table, raw oats,[18] unrefined barley,[18] yacón,[18] and whole grain breakfast cereals[4] are also classified as prebiotic fiber sources. The predominant type of prebiotic fiber may vary according to the food. For instance, oats and barley have high amounts of beta-glucans, fruit and berries contain pectins, seeds contain gums, onions and Jerusalem artichokes are rich in inulin and oligofructose, and bananas and legumes contain resistant starch.[27]

Top 10 Foods Containing Prebiotics
Food Prebiotic Fiber Content by Weight
Raw, Dry Chicory Root 64.6%
Raw, Dry Jerusalem Artichoke 31.5%
Raw, Dry Dandelion Greens 24.3%
Raw, Dry Garlic 17.5%
Raw, Dry Leek 11.7%
Raw, Dry Onion 8.6%
Raw Asparagus 5%
Raw Wheat bran 5%
Whole Wheat flour, Cooked 4.8%
Raw Banana 1%
Source:[28]

While there is no broad consensus on an ideal daily serving of prebiotics, recommendations typically range from 4 to 8 grams (0.14–0.28 oz) for general digestive health support, to 15 grams (0.53 oz) or more for those with active digestive disorders. Given an average 6 grams (0.21 oz) serving, below are the amounts of prebiotic foods required to achieve a daily serving of prebiotic fiber:

Food Amount of food to achieve 6 g serving of fructans
Raw Chicory Root 9.3 g (0.33 oz)
Raw Jerusalem Artichoke 19 g (0.67 oz)
Raw Dandelion Greens 24.7 g (0.87 oz)
Raw Garlic 34.3 g (1.21 oz)
Raw Leek 51.3 g (1.81 oz)
Raw Onion 69.8 g (2.46 oz)
Cooked Onion 120 g (4.2 oz)
Raw Asparagus 120 g (4.2 oz)
Raw Wheat Bran 120 g (4.2 oz)
Whole Wheat Flour, Cooked 125 g (4.4 oz)
Raw Banana 600 g (1.3 lb)
Source[28]

Research edit

Preliminary research has demonstrated potential effects on calcium and other mineral absorption,[29] immune system effectiveness,[30][31] bowel acidity, reduction of colorectal cancer risk,[32] inflammatory bowel disease (Crohn's disease or ulcerative colitis),[33] hypertension[34] and defecation frequency.[35] Prebiotics may be effective in decreasing the number of infectious episodes needing antibiotics and the total number of infections in children aged 0–24 months.[31][36]

No good evidence shows that prebiotics are effective in preventing or treating allergies.[37]

While research demonstrates that prebiotics lead to increased production of short-chain fatty acids (SCFA),[38] more research is required to establish a direct causal connection. Prebiotics may be beneficial to inflammatory bowel disease or Crohn's disease through production of SCFA as nourishment for colonic walls, and mitigation of ulcerative colitis symptoms.[39]

The sudden addition of substantial quantities of prebiotics to the diet may result in an increase in fermentation, leading to increased gas production, bloating or bowel movement.[40] Production of SCFA and fermentation quality are reduced during long-term diets of low fiber intake.[41] Until bacterial flora are gradually established to rehabilitate or restore intestinal bacteria, nutrient absorption may be impaired and colonic transit time temporarily increased with a rapid addition of higher prebiotic intake.[40][42]

Genetic modification edit

Genetically modified plants have been created in research labs with upregulated inulin production.[43][44]

See also edit

References edit

  1. ^ a b c Hutkins RW; Krumbeck JA; Bindels LB; Cani PD; Fahey G Jr.; Goh YJ; Hamaker B; Martens EC; Mills DA; Rastal RA; Vaughan E; Sanders ME (2016). "Prebiotics: why definitions matter". Curr Opin Biotechnol. 37: 1–7. doi:10.1016/j.copbio.2015.09.001. PMC 4744122. PMID 26431716.
  2. ^ Gibson GR, Roberfroid MB (June 1995). "Dietary modulation of the human colonic microbiota: introducing the concept of prebiotics". J. Nutr. 125 (6): 1401–12. doi:10.1093/jn/125.6.1401. PMID 7782892.
  3. ^ a b c d e f g h i j k l m Gibson GR, Hutkins R, Sanders ME, Prescott SL, Reimer RA, Salminen SJ, et al. (August 2017). "Expert consensus document: The International Scientific Association for Probiotics and Prebiotics (ISAPP) consensus statement on the definition and scope of prebiotics" (PDF). Nature Reviews. Gastroenterology & Hepatology. 14 (8): 491–502. doi:10.1038/nrgastro.2017.75. PMID 28611480. S2CID 11827223.
  4. ^ a b c d e f g h i j k l Slavin J (April 2013). "Fiber and prebiotics: mechanisms and health benefits". Nutrients. 5 (4): 1417–35. doi:10.3390/nu5041417. PMC 3705355. PMID 23609775.
  5. ^ Bindels, Laure B.; Delzenne, Nathalie M.; Cani, Patrice D.; Walter, Jens (2015). "Towards a more comprehensive concept for prebiotics". Nature Reviews Gastroenterology & Hepatology. 12 (5): 303–310. doi:10.1038/nrgastro.2015.47. PMID 25824997. S2CID 637779.
  6. ^ a b "Learn more about prebiotics". Global Prebiotic Association.
  7. ^ a b c d Lamsal BP (August 2012). "Production, health aspects and potential food uses of dairy prebiotic galactooligosaccharides". Journal of the Science of Food and Agriculture. 92 (10): 2020–28. doi:10.1002/jsfa.5712. PMID 22538800.
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  19. ^ Cunningham, Marla; Azcarate-Peril, M. Andrea; Barnard, Alan; Benoit, Valerie; Grimaldi, Roberta; Guyonnet, Denis; Holscher, Hannah D.; Hunter, Kirsty; Manarung, Sarmauli; Obis, David; Petrova, Mariya I.; Steinert, Robert E.; Swanson, Kelly S.; van Sinderen, Douwe; Vulevic, Jelena; Gibson, Glenn R. (2021). "Shaping the future of probiotics and prebiotics". Trends in Microbiology. 29 (8): 667–685. doi:10.1016/j.tim.2021.01.003. PMID 33551269. S2CID 231864275.
  20. ^ Coxam V (November 2007). "Current data with inulin-type fructans and calcium, targeting bone health in adults". The Journal of Nutrition. 137 (11 Suppl): 2527S–33S. doi:10.1093/jn/137.11.2527S. PMID 17951497.
  21. ^ Seifert S, Watzl B (November 2007). "Inulin and oligofructose: review of experimental data on immune modulation". The Journal of Nutrition. 137 (11 Suppl): 2563S–67S. doi:10.1093/jn/137.11.2563S. PMID 17951503.
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  24. ^ Cassidy, A.; Bingham, S.A.; Cummings, J.H. (1994). "Starch intake and colorectal cancer risk: an international comparison". Br J Cancer. 69 (5): 937–942. doi:10.1038/bjc.1994.181. PMC 1968884. PMID 8180027.
  25. ^ O'Keefe, Stephen J.D.; et al. (2015). "Fat, fibre and cancer risk in African Americans and rural Africans". Nat Commun. 6: 6342. Bibcode:2015NatCo...6.6342O. doi:10.1038/ncomms7342. PMC 4415091. PMID 25919227.
  26. ^ Enam F, Mansell TJ (October 2019). "Prebiotics: tools to manipulate the gut microbiome and metabolome". Journal of Industrial Microbiology & Biotechnology. 46 (9–10): 1445–59. doi:10.1007/s10295-019-02203-4. PMID 31201649. S2CID 189819499.
  27. ^ "Definitions of fiber". Micronutrient Information Center, Linus Pauling Institute, Oregon State University, Corvallis, OR. 1 April 2012. Retrieved 27 February 2019.
  28. ^ a b Moshfegh AJ, Friday JE, Goldman JP, Ahuja JK (July 1999). "Presence of inulin and oligofructose in the diets of Americans". Journal of Nutrition. 129 (7 Suppl): 1407S–11S. doi:10.1093/jn/129.7.1407S. PMID 10395608.
  29. ^ Scholz-Ahrens KE, Schrezenmeir J (November 2007). "Inulin and oligofructose and mineral metabolism: the evidence from animal trials". J. Nutr. 137 (11 Suppl): 2513S–23S. doi:10.1093/jn/137.11.2513S. PMID 17951495.
  30. ^ Lomax AR, Calder PC (March 2009). "Prebiotics, immune function, infection and inflammation: a review of the evidence". Br J Nutr. 101 (5): 633–58. doi:10.1017/S0007114508055608. PMID 18814803.
  31. ^ a b Lohner S, Küllenberg D, Antes G, Decsi T, Meerpohl JJ (2014). "Prebiotics in healthy infants and children for prevention of acute infectious diseases: a systematic review and meta-analysis". Nutr Rev. 72 (8): 523–31. doi:10.1111/nure.12117. PMID 24903007.
  32. ^ Geier MS, Butler RN, Howarth GS (October 2006). "Probiotics, prebiotics and synbiotics: a role in chemoprevention for colorectal cancer?". Cancer Biol. Ther. 5 (10): 1265–69. doi:10.4161/cbt.5.10.3296. PMID 16969130.
  33. ^ Hedin C, Whelan K, Lindsay JO (August 2007). "Evidence for the use of probiotics and prebiotics in inflammatory bowel disease: a review of clinical trials". Proceedings of the Nutrition Society. 66 (3): 307–15. doi:10.1017/S0029665107005563. PMID 17637082.
  34. ^ Yeo SK, Ooi LG, Lim TJ, Liong MT (2009). "Antihypertensive properties of plant-based prebiotics". Int J Mol Sci. 10 (8): 3517–30. doi:10.3390/ijms10083517. PMC 2812835. PMID 20111692.
  35. ^ Roberfroid M, et al. (2010). "Prebiotic effects: metabolic and health benefits". Br J Nutr. 104 (Suppl 2): S1–63. doi:10.1017/S0007114510003363. PMID 20920376.
  36. ^ Koen Venema, Ana Paula do Carmo, ed. (2015). Probiotics and prebiotics : current research and future trends. Norfolk, UK: Caister Academic Press. ISBN 978-1-910190-10-4. OCLC 916950998.
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  40. ^ a b Marteau P, Seksik P (2004). "Tolerance of probiotics and prebiotics". J Clin Gastroenterol. 38 (Suppl 6): S67–69. doi:10.1097/01.mcg.0000128929.37156.a7. PMID 15220662.
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  42. ^ Givson GR, Willems A, Reading S, Collins MD (1996). "Fermentation of non-digestible oligosaccharides by human colonic bacteria". Proceedings of the Nutrition Society. 55 (3): 899–912. doi:10.1079/PNS19960087. PMID 9004332.
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Further reading edit

  • Frank W. Jackson, PREbiotics, Not Probiotics. 2013, Jacksong GI Medical. ISBN 978-0991102709.

External links edit

 
Wikimedia Commons has media related to Prebiotics.
  • International Scientific Association for Probiotics and Prebiotics

February 16, 2024
prebiotic, nutrition, confused, with, probiotics, microorganisms, typically, found, fermented, foods, prebiotics, compounds, food, that, foster, growth, activity, beneficial, microorganisms, such, bacteria, fungi, most, common, environment, considered, gastroi. Not to be confused with Probiotics microorganisms typically found in fermented foods Prebiotics are compounds in food that foster growth or activity of beneficial microorganisms such as bacteria and fungi 1 The most common environment considered is the gastrointestinal tract where prebiotics can alter the composition of organisms in the gut microbiome Dietary prebiotics are typically nondigestible fiber compounds that pass undigested through the upper part of the gastrointestinal tract and help growth or activity of advantageous bacteria in the colon by acting as substrates for them 1 They were first identified and named by Marcel Roberfroid in 1995 1 2 Depending on the jurisdiction they may have regulatory scrutiny as food additives for the health claims made for marketing purposes Common prebiotics used in food manufacturing include beta glucan from oats resistant starch from grains and beans and inulin from chicory root Contents 1 Definition 2 Function 2 1 Mechanism of action 3 Sources 3 1 Endogenous 3 2 Exogenous 4 Research 4 1 Genetic modification 5 See also 6 References 7 Further reading 8 External linksDefinition editThe definition of prebiotics and the food ingredients that can fall under this classification has evolved since its first definition in 1995 3 In its earliest definition the term prebiotics was used to refer to non digestible food ingredients that were beneficial to the host through their selective stimulation of specific bacteria within the colon 3 4 Further research has suggested that selective stimulation has not been scientifically demonstrated 5 As a result of research suggesting that prebiotics could impact microorganisms outside of the colon in 2016 the International Scientific Association for Probiotics and Prebiotics ISAPP produced the following definition of prebiotics a substrate that is selectively used by a host microorganism to produce a health benefit 3 In 2021 The Global Prebiotic Association GPA defined a prebiotic as a product or ingredient that is utilized in the microbiota producing a health or performance benefit 6 Compounds that can be classified as prebiotics must also meet the following criteria 3 4 6 non digestible and resistant to breakdown by stomach acid and enzymes in the human gastrointestinal tract fermented by microorganisms on or in the body stimulating growth and activity of beneficial bacteriaThus consumption of prebiotics may facilitate the health of the host 7 Based on the previous classifications plant derived carbohydrate compounds called oligosaccharides as well as resistant starch are the main source of prebiotics that have been identified 8 4 9 10 Specifically fructans and galactans are two oligosaccharide sources which have been found to stimulate the activity and growth of beneficial bacterial colonies in the gut 7 3 Fructans are a category of carbohydrate consisting of fructooligosaccharides FOS and inulins while galactans consist of galactooligosaccharides 3 Resistant starch has been shown to shift the intestinal bacteria as well as improve biomarkers for numerous health conditions 11 12 13 Other dietary fibers also fit the definition of prebiotics such as pectin 14 beta glucans 15 and xylooligosaccharides 16 The European Food Safety Authority EFSA the regulatory agency for product labeling differentiates between prebiotic and dietary fiber stating that a cause and effect relationship has not been established between the consumption of the food constituents which are the subject of the health claims and a beneficial physiological effect related to increasing numbers of gastrointestinal microbiota 17 Consequently under EFSA rules individual ingredients cannot be labeled as prebiotics but only as dietary fiber and with no implication of health benefits 17 Function editWhen the prebiotic concept was first introduced in 1995 the primary focus was on the effects that prebiotics confer on Bifidobacteria and Lactobacillus 3 4 18 With improved mechanistic techniques in recent years the current prebiotic targets have expanded to a wider range of microbes including Roseburia spp Eubacterium spp Akkermansia spp Christensenella spp Propionibacterium spp and Faecalibacterium spp 19 These bacteria have been highlighted as key probiotics and beneficial gut bacteria as they may have several beneficial effects on the host in terms of improving digestion including but not limited to enhancing mineral absorption 20 and the effectiveness and intrinsic strength of the immune system 21 Both Bifidobacteria and Lactobacillus have been shown to have differing prebiotic specificity and to selectively ferment prebiotic fiber based on the enzymes characteristic of the bacterial population 22 Thus Lactobacilli prefer inulin and fructooligosaccharides while Bifidobacteria display specificity for inulin fructooligosaccharides xylooligosaccharides and galactooligosaccharides 22 Studies have also shown that prebiotics besides helping growth of beneficial gut bacteria can also inhibit detrimental and potentially pathogenic microbes in the gut 9 4 such as clostridia 4 Mechanism of action edit Fermentation is the main mechanism of action by which prebiotics are used by beneficial bacteria in the colon 7 4 Both Bifidobacteria and Lactobacillus are bacterial populations which use saccharolytic metabolism to break down substrates 4 The bifidobacterial genome contains many genes that encode for carbohydrate modifying enzymes as well as genes that encode for carbohydrate uptake proteins The presence of these genes indicates that Bifidobacteria contain specific metabolic pathways specialized for the fermentation and metabolism of plant derived oligosaccharides or prebiotics These pathways in Bifidobacteria ultimately produce short chain fatty acids 4 7 which have diverse physiological roles in body functions 23 3 Sources editPrebiotic sources must be proven to confer a benefit to the host in order to be classified as a prebiotic 3 Fermentable carbohydrates derived from fructans and xylans are one well documented example of prebiotics 3 Resistant starch from starchy foods are also well documented prebiotics and have historically been the highest source of prebiotics in the diet as 4 10 of starch in mixed diets has been shown to reach the large intestine 24 One study reported that individuals consuming a traditional diet in Africa consumed 38 grams of resistant starch day 25 Endogenous edit An endogenous source of prebiotics in humans is human breast milk which contains oligosaccharides structurally similar to galactooligosaccharides referred to as human milk oligosaccharides 26 9 22 3 Human milk oligosaccharides were found to increase the Bifidobacteria bacterial population in breastfed infants and to strengthen the infant immune system 3 9 Furthermore human milk oligosaccharides help establish a healthy intestinal microbiota composition in newborns 3 Exogenous edit Indigestible carbohydrate compounds classified as prebiotics are a type of fermentable fiber and thus can be classified as dietary fiber 4 However not all dietary fiber can be classified as a prebiotic source 4 In addition to the food sources highlighted in the following table raw oats 18 unrefined barley 18 yacon 18 and whole grain breakfast cereals 4 are also classified as prebiotic fiber sources The predominant type of prebiotic fiber may vary according to the food For instance oats and barley have high amounts of beta glucans fruit and berries contain pectins seeds contain gums onions and Jerusalem artichokes are rich in inulin and oligofructose and bananas and legumes contain resistant starch 27 Top 10 Foods Containing PrebioticsFood Prebiotic Fiber Content by WeightRaw Dry Chicory Root 64 6 Raw Dry Jerusalem Artichoke 31 5 Raw Dry Dandelion Greens 24 3 Raw Dry Garlic 17 5 Raw Dry Leek 11 7 Raw Dry Onion 8 6 Raw Asparagus 5 Raw Wheat bran 5 Whole Wheat flour Cooked 4 8 Raw Banana 1 Source 28 While there is no broad consensus on an ideal daily serving of prebiotics recommendations typically range from 4 to 8 grams 0 14 0 28 oz for general digestive health support to 15 grams 0 53 oz or more for those with active digestive disorders Given an average 6 grams 0 21 oz serving below are the amounts of prebiotic foods required to achieve a daily serving of prebiotic fiber Food Amount of food to achieve 6 g serving of fructansRaw Chicory Root 9 3 g 0 33 oz Raw Jerusalem Artichoke 19 g 0 67 oz Raw Dandelion Greens 24 7 g 0 87 oz Raw Garlic 34 3 g 1 21 oz Raw Leek 51 3 g 1 81 oz Raw Onion 69 8 g 2 46 oz Cooked Onion 120 g 4 2 oz Raw Asparagus 120 g 4 2 oz Raw Wheat Bran 120 g 4 2 oz Whole Wheat Flour Cooked 125 g 4 4 oz Raw Banana 600 g 1 3 lb Source 28 Research editPreliminary research has demonstrated potential effects on calcium and other mineral absorption 29 immune system effectiveness 30 31 bowel acidity reduction of colorectal cancer risk 32 inflammatory bowel disease Crohn s disease or ulcerative colitis 33 hypertension 34 and defecation frequency 35 Prebiotics may be effective in decreasing the number of infectious episodes needing antibiotics and the total number of infections in children aged 0 24 months 31 36 No good evidence shows that prebiotics are effective in preventing or treating allergies 37 While research demonstrates that prebiotics lead to increased production of short chain fatty acids SCFA 38 more research is required to establish a direct causal connection Prebiotics may be beneficial to inflammatory bowel disease or Crohn s disease through production of SCFA as nourishment for colonic walls and mitigation of ulcerative colitis symptoms 39 The sudden addition of substantial quantities of prebiotics to the diet may result in an increase in fermentation leading to increased gas production bloating or bowel movement 40 Production of SCFA and fermentation quality are reduced during long term diets of low fiber intake 41 Until bacterial flora are gradually established to rehabilitate or restore intestinal bacteria nutrient absorption may be impaired and colonic transit time temporarily increased with a rapid addition of higher prebiotic intake 40 42 Genetic modification edit Genetically modified plants have been created in research labs with upregulated inulin production 43 44 See also editAntibiotic Antimicrobial substance active against bacteria Mannan Oligosaccharide based nutritional supplements MOS Polysaccharides formed from mannosePages displaying short descriptions of redirect targets Prebiotic scores Measure of effects of prebioticsPages displaying short descriptions of redirect targets Probiotic Microorganisms said to provide health benefits when consumed Psychobiotic Microorganisms giving mental health effects Resistant starch Dietary fiber Synbiotics Nutritional supplementsReferences edit a b c Hutkins RW Krumbeck JA Bindels LB Cani PD Fahey G Jr Goh YJ Hamaker B Martens EC Mills DA Rastal RA Vaughan E Sanders ME 2016 Prebiotics why definitions matter Curr Opin Biotechnol 37 1 7 doi 10 1016 j copbio 2015 09 001 PMC 4744122 PMID 26431716 Gibson GR Roberfroid MB June 1995 Dietary modulation of the human colonic microbiota introducing the concept of prebiotics J Nutr 125 6 1401 12 doi 10 1093 jn 125 6 1401 PMID 7782892 a b c d e f g h i j k l m Gibson GR Hutkins R Sanders ME Prescott SL Reimer RA Salminen SJ et al August 2017 Expert consensus document The International Scientific Association for Probiotics and Prebiotics ISAPP consensus statement on the definition and scope of prebiotics PDF Nature Reviews Gastroenterology amp Hepatology 14 8 491 502 doi 10 1038 nrgastro 2017 75 PMID 28611480 S2CID 11827223 a b c d e f g h i j k l Slavin J April 2013 Fiber and prebiotics mechanisms and health benefits Nutrients 5 4 1417 35 doi 10 3390 nu5041417 PMC 3705355 PMID 23609775 Bindels Laure B Delzenne Nathalie M Cani Patrice D Walter Jens 2015 Towards a more comprehensive concept for prebiotics Nature Reviews Gastroenterology amp Hepatology 12 5 303 310 doi 10 1038 nrgastro 2015 47 PMID 25824997 S2CID 637779 a b Learn more about prebiotics Global Prebiotic Association a b c d Lamsal BP August 2012 Production health aspects and potential food uses of dairy prebiotic galactooligosaccharides Journal of the Science of Food and Agriculture 92 10 2020 28 doi 10 1002 jsfa 5712 PMID 22538800 Zaman SA Sarbini SR 7 July 2015 The potential of resistant starch as a prebiotic PDF Critical Reviews in Biotechnology 36 3 578 84 doi 10 3109 07388551 2014 993590 PMID 25582732 S2CID 25974073 a b c d CK Rajendran SR Okolie CL Udenigwe CC Mason B 1 October 2017 Structural features underlying prebiotic activity of conventional and potential prebiotic oligosaccharides in food and health Journal of Food Biochemistry 41 5 e12389 doi 10 1111 jfbc 12389 ISSN 1745 4514 Bird A Conlon M Christophersen C Topping D 2010 Resistant starch large bowel fermentation and a broader perspective of prebiotics and probiotics Beneficial Microbes 1 4 423 431 doi 10 3920 BM2010 0041 PMID 21831780 Portincasa Piero Bonfrate Leonilde Vacca Mirco de Angelis Maria Farella Ilaria Lanza Elisa Khalil Mohamad Wang David Q H Sperandio Markus Di Ciaula Agostino 2022 Gut Microbiota and short chain fatty acids implications in glucose homeostasis Int J Mol Sci 23 3 1105 doi 10 3390 ijms23031105 PMC 8835596 PMID 35163038 Warman Dwina Juliana Jia Huijuan Kato Hisanori 2022 The potential roles of probiotics resistant starch and resistant proteins in ameliorating inflammation during aging Inflammaging Nutrients 14 4 747 doi 10 3390 nu14040747 PMC 8879781 PMID 35215397 Li Cheng Hu Yiming 2022 New definition of resistant starch types from the Gut Microbiota perspectives a review Critical Reviews in Food Science and Nutrition 1 11 doi 10 1080 10408398 2022 2031101 PMID 35075962 S2CID 246277434 Gomez B Gullon B Remoroza C Schols HA Parajo JC Alonso JL October 2014 Purification characterization and prebiotic properties of pectic oligosaccharides from orange peel wastes Journal of Agricultural and Food Chemistry 62 40 9769 82 doi 10 1021 jf503475b PMID 25207862 Arena MP Caggianiello G Fiocco D Russo P Torelli M Spano G Capozzi V February 2014 Barley b glucans containing food enhances probiotic performances of beneficial bacteria International Journal of Molecular Sciences 15 2 3025 39 doi 10 3390 ijms15023025 PMC 3958897 PMID 24562330 Linares Pasten JA Aronsson A Karlsson EN 2017 Structural Considerations on the Use of Endo Xylanases for the Production of prebiotic Xylooligosaccharides from Biomass Current Protein amp Peptide Science 19 1 48 67 doi 10 2174 1389203717666160923155209 PMC 5738707 PMID 27670134 a b Delcour JA Aman P Courtin CM Hamaker BR Verbeke K January 2016 Prebiotics Fermentable Dietary Fiber and Health Claims Advances in Nutrition 7 1 1 4 doi 10 3945 an 115 010546 PMC 4717894 PMID 26773010 a b c d Pandey KR Naik SR Vakil BV December 2015 Probiotics prebiotics and synbiotics a review Journal of Food Science and Technology 52 12 7577 87 doi 10 1007 s13197 015 1921 1 PMC 4648921 PMID 26604335 Cunningham Marla Azcarate Peril M Andrea Barnard Alan Benoit Valerie Grimaldi Roberta Guyonnet Denis Holscher Hannah D Hunter Kirsty Manarung Sarmauli Obis David Petrova Mariya I Steinert Robert E Swanson Kelly S van Sinderen Douwe Vulevic Jelena Gibson Glenn R 2021 Shaping the future of probiotics and prebiotics Trends in Microbiology 29 8 667 685 doi 10 1016 j tim 2021 01 003 PMID 33551269 S2CID 231864275 Coxam V November 2007 Current data with inulin type fructans and calcium targeting bone health in adults The Journal of Nutrition 137 11 Suppl 2527S 33S doi 10 1093 jn 137 11 2527S PMID 17951497 Seifert S Watzl B November 2007 Inulin and oligofructose review of experimental data on immune modulation The Journal of Nutrition 137 11 Suppl 2563S 67S doi 10 1093 jn 137 11 2563S PMID 17951503 a b c Wilson B Whelan K March 2017 Prebiotic inulin type fructans and galacto oligosaccharides 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189819499 Definitions of fiber Micronutrient Information Center Linus Pauling Institute Oregon State University Corvallis OR 1 April 2012 Retrieved 27 February 2019 a b Moshfegh AJ Friday JE Goldman JP Ahuja JK July 1999 Presence of inulin and oligofructose in the diets of Americans Journal of Nutrition 129 7 Suppl 1407S 11S doi 10 1093 jn 129 7 1407S PMID 10395608 Scholz Ahrens KE Schrezenmeir J November 2007 Inulin and oligofructose and mineral metabolism the evidence from animal trials J Nutr 137 11 Suppl 2513S 23S doi 10 1093 jn 137 11 2513S PMID 17951495 Lomax AR Calder PC March 2009 Prebiotics immune function infection and inflammation a review of the evidence Br J Nutr 101 5 633 58 doi 10 1017 S0007114508055608 PMID 18814803 a b Lohner S Kullenberg D Antes G Decsi T Meerpohl JJ 2014 Prebiotics in healthy infants and children for prevention of acute infectious diseases a systematic review and meta analysis Nutr Rev 72 8 523 31 doi 10 1111 nure 12117 PMID 24903007 Geier MS Butler 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1136 gut 38 6 870 PMC 1383195 PMID 8984026 Givson GR Willems A Reading S Collins MD 1996 Fermentation of non digestible oligosaccharides by human colonic bacteria Proceedings of the Nutrition Society 55 3 899 912 doi 10 1079 PNS19960087 PMID 9004332 Ritsema T Smeekens SC 2003 Engineering fructan metabolism in plants J Plant Physiol 160 7 811 20 doi 10 1078 0176 1617 01029 PMID 12940548 Weyens G Ritsema T Van Dun K Meyer D Lommel M Lathouwers J Rosquin I Denys P Tossens A Nijs M Turk S Gerrits N Bink S Walraven B Lefebvre M Smeekens S 2004 Production of tailor made fructans in sugar beet by expression of onion fructosyltransferase genes Plant Biotechnol J 2 4 321 27 doi 10 1111 j 1467 7652 2004 00074 x hdl 1874 11465 PMID 17134393 S2CID 42177275 Further reading editFrank W Jackson PREbiotics Not Probiotics 2013 Jacksong GI Medical ISBN 978 0991102709 External links edit nbsp Wikimedia Commons has media related to Prebiotics International Scientific Association for Probiotics and Prebiotics Retrieved from https en wikipedia org w index php title Prebiotic nutrition amp oldid 1191869325, wikipedia, wiki, book, books, library,

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