Fiber

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fiber

Contents

Dietary fiber

Dietary fiber is the type of compounds including lignin and complex carbohydrate (made up of many sugar molecules linked together) you can eat that is found in fruits, vegetables, legumes and whole grains 1, 2, 3, 4, 5, 6. The European Food Safety Authority (EFSA) defines dietary fiber as non-digestible carbohydrate plus lignin 7, 8, 9. The Codex Alimentarius in 2009 defined dietary fiber as “carbohydrate polymers with ten or more monomeric units which are not hydrolyzed by the endogenous enzymes in the small intestine of humans” 10, 11. But unlike other carbohydrates, dietary fiber is bound together in such a way that it cannot be easily digested in the small intestine. All dietary fibers are resistant to digestion in the small intestine, meaning they arrive intact in the large intestine 12. Although most fibers are carbohydrates, one important factor that determines their susceptibility to digestion by human enzymes is the chemical bonds between sugar molecules (glycosidic bonds) 13. Humans lack digestive enzymes capable of breaking apart (hydrolyzing) most beta-glycosidic bonds (the chemical bonds between sugar molecules), which explains why amylose, a glucose polymer (containing different types of sugar monomers) with alpha-1,4 glycosidic bonds, is digestible by human enzymes, while cellulose, a glucose polymer (glucose polysaccharide) with beta-1,4 glycosidic bonds, is indigestible 13. Dietary fiber adds bulk to your diet. Dietary fiber is an important part of a healthy diet and getting enough fiber is important for your overall health, including heart and digestive health 14, 15, 16, 17. Because high-fiber foods make you feel full faster, they can help with weight control. Fiber also aids in your digestion and helps prevent constipation. Dietary fiber is sometimes used for the treatment of diverticulosis, diabetes, and heart disease 18. Fiber-rich foods offer health benefits when eaten raw or cooked. Taking the peels off fruits and vegetables reduces the amount of fiber you get from the food.

The classification of dietary fibre also stems from water solubility. Broadly, there are 2 main types of dietary fibre: soluble and insoluble fiber. Both soluble and insoluble dietary fiber can make you feel full, which may lower your calorie (food) intake by helping you eat less and yet stay satisfied longer 19 , 20.

  1. Soluble dietary fiber attracts water and forms a thick gel-like substance in your stomach. This slows digestion. Soluble dietary fiber is found in oat bran, barley, nuts, seeds, beans, lentils, peas, and some fruits and vegetables. Soluble dietary fiber is broken down by bacteria in your large intestine and provides some calories. Soluble dietary fiber can interfere with the absorption of dietary fat and cholesterol. This, in turn, can help lower low-density lipoprotein (LDL or “bad”) cholesterol levels in your blood. Research has shown that soluble dietary fiber lowers cholesterol, which can help prevent heart disease. Soluble fiber can also slow digestion and the rate at which carbohydrates and other nutrients are absorbed into your bloodstream. This can help control your blood sugar (blood glucose) level by preventing rapid rises in blood glucose (sugar) following a meal.
  2. Insoluble dietary fiber does not dissolve in water and may pass through your gastrointestinal tract relatively intact and, therefore, is not a source of calories. Insoluble fiber appears to speed the passage of foods through your stomach and intestines and adds bulk to the stool. Insoluble dietary fiber is found in foods such as wheat bran, vegetables, and whole grains.

Most Americans (>90 percent of women and 97 percent of men) do not get the recommended amount of dietary fiber (25 to 32 g/day for adult women, 34 to 38 g/day for adult men or 14 g of dietary fiber per 1000 kcal consumed) because of under consumption of fruits, vegetables, and whole grains 2122, 20, 6. An analysis of the 2009-2010 US National Health and Nutrition Examination Survey (NHANES) data reported average dietary fiber intakes of 13.6 g/day in children and adolescents and 17 g/day in adults, well below recommended intake levels 23. Dietary fiber intake for adults living in European countries was 18 to 24 g per day for men and 16 to 20 g per day for women, with grain products (including bread) providing the largest source of dietary fibre 6. Comparison with data from the National Health and Nutrition Examination Survey (NHANES) showed that on average, dietary fiber intake in European countries was higher than in North America. Based on these data, it appears that within Europe and the US, dietary fiber intake is around one third below the recommended level.

Dietary fiber is considered a “dietary component of public health concern” in the Dietary Guidelines for Americans because low intakes are associated with potential health risks 24. The Dietary Guidelines for Americans recommendation for older children, adolescents, and adults is to eat 21 to 38 grams of fiber each day (or 14 g of dietary fiber per 1000 kcal consumed). The Dietary Guidelines for Americans recommend consuming a variety of foods that are good sources of dietary fiber, especially vegetables, fruits, beans, and grains 21. The guidelines also recommend consuming at least half of grains as whole grains and limiting the intake of refined grains and products made with refined grains 21.

Dietary fiber can reach the colon and influence intestinal physiology, and dietary fiber plays a role in regulating intestinal microbiota 25. Dietary fiber also possesses physiological functions including reduction of inflammatory response 26 and antioxidant 27. Accumulating evidence indicates that dietary fiber intake is beneficial in alleviating several chronic diseases such as high blood pressure 28, diabetes 29, 30, 31, hyperlipidemia 32 and cancer 33. Furthermore, dietary fiber has been demonstrated to have significant antiaging benefits, with people who consume high levels of dietary fiber living longer than their peers and having a reduced risk of disease or premature death 34.

Good sources of dietary fiber include legumes, nuts, whole grains, bran products, fruit, and nonstarchy vegetables. Legumes (e.g., dry beans and peas), nuts, seeds, and whole grains are generally more concentrated sources of fiber than fruit and vegetables 35. These higher fiber foods are currently underconsumed, contributing to only about 6% of total dietary fiber intake 23. Although refined grains are often perceived as being poor sources of fiber, they can provide as much fiber as either fruit or vegetables when comparable serving sizes are consumed 35. In addition, not all whole grains are good sources of fiber, yet they provide key micronutrients and phytochemicals that contribute to the health benefit associated with whole grain consumption 36.

All plant-based foods contain a mixture of soluble and insoluble fiber 35. Bran flaxseed, oat cereal, legumes, nuts, fruit, and vegetables are good sources of soluble viscous and nonviscous fiber. Wheat bran, brown rice, barley, cabbage, celery, and whole grains are rich sources of insoluble fiber. The total fiber content of some fiber-rich foods is presented in Table 3 below. Some strategies for increasing dietary fiber intake include increasing fruit and nonstarchy vegetable intake, increasing intake of legumes, eating whole-grain cereal or oatmeal for breakfast, substituting whole grains for refined grains, and substituting nuts or popcorn for less healthy snacks.

To ensure that you get enough fiber, eat a variety of foods, including:

  • Cereals
  • Dried beans and peas
  • Fruits
  • Vegetables
  • Whole grains

For breakfast, choose steel cut oats with nuts and berries instead of a low-fiber, refined cereal. At lunch, have a sandwich or wrap on a whole-grain tortilla or whole-grain bread and add veggies, such as lettuce and tomato, or serve with veggie soup. For a snack, have fresh veggies or whole-grain crackers with hummus. With dinner, try brown rice or whole-grain noodles instead of white rice or pasta made with white flour.

When increasing fiber in your diet, be sure to do it gradually over a period of a few weeks to avoid stomach distress and with plenty of fluids. Water helps fiber pass through your digestive system. As dietary fiber travels through the digestive tract, it is similar to a new sponge; it needs water to plump up and pass smoothly. If you consume more than your usual intake of fiber but not enough fluid, you may experience nausea or constipation. All fiber supplements should be taken with sufficient fluids. Most doctors recommend taking fiber supplements with at least 8 ounces (240 mL) of water and consuming a total of at least 64 ounces (~2 liters or 2 quarts) of fluid daily 37, 38.

Before you reach for the fiber supplements, consider this: Fiber is found naturally in nutritious foods. Studies have found the same benefits, such as a feeling of fullness, may not result from fiber supplements or from fiber-enriched foods. If you’re missing out on your daily amount of fiber, you may be lacking in other essential nutrients as well. Your fiber intake is a good gauge for overall diet quality. Try to reach your fiber goal with unprocessed foods so you get all the other benefits they provide as well.

Types of fibers

Although nutritional scientists and clinicians generally agree that a healthy diet should include plenty of fiber-rich foods, agreement on the actual definition of fiber has been more difficult to achieve. In the 1970s, dietary fiber was defined as leftovers of plant cells that are resistant to digestion by human enzymes 18. This definition includes a component of some plant cell walls called lignin, as well as indigestible carbohydrates found in plants. However, this definition omits indigestible carbohydrates derived from animal sources (e.g., chitin) and synthetic (e.g., fructooligosaccharides, polydextrose, wheat dextrin) and carbohydrates that are inaccessible to human digestive enzymes (e.g., resistant starch) 39. These compounds share many of the characteristics of fiber present in plant foods. In 2001 a panel of experts convened by the Institute of Medicine (National Academy of Medicine) developed definitions of fiber that made a distinction between dietary fiber as fiber that occurs naturally in plant foods and functional fiber which are man-made (synthetic) or isolated fibers that may be added to foods or used as dietary supplements 2. However, these distinctions are controversial, and there are other classification systems for dietary fiber.

Dietary fiber

Dietary fiber is an umbrella term for complex carbohydrate polymers with 10 or more monomeric units which are neither digested by the endogenous enzymes in the small intestine of humans nor absorbed; and have beneficial physiological effect; this term includes non-starch polysaccharides, oligosaccharides, lignin, resistant starch, and other plant components (i.e. gums, mucilages) 11. The European Food Safety Authority (EFSA) defines dietary fiber as “non-digestible carbohydrate plus lignin7, 8. The European Food Safety Authority (EFSA) provide a long list of substances that constitute dietary fiber, including non-starch polysaccharides, cellulose, pectins, hydrocolloids, fructo-oligosaccharides and ‘resistant starch’ 7, 8, 9.

Naturally occurring fiber often referred to as “intrinsic fiber” occurs in foods such as vegetables, whole grains, fruits, cereal bran, flaked cereal and flours. The fibers are also considered to be “intact fiber” because they have not been removed from the food. Foods containing these fibers have been shown to be beneficial to human health.

Lignin

Lignin is not a carbohydrate, rather, it is a polyphenolic compound with a complex three-dimensional structure that is found in the cell walls of woody plants and seeds 40.

Cellulose

Cellulose is a glucose polymer with beta-1,4 glycosidic bonds found in all plant cell walls 39.

Beta-glucans

Beta-glucans are glucose polymers (glucose polysaccharides) with a mixture of beta-1,4 glycosidic bonds and beta-1,3 glycosidic bonds. Beta-glucans are soluble fibers found in bacteria, yeast, fungi, and grains such as oat bran and barley are particularly rich in beta-glucans 41, 40.

Hemicelluloses

Hemicelluloses are a diverse group of sugar polymers (polysaccharides) containing different types of sugar monomers, including glucose, xylose, arabinose, mannose, galactose, rhamnose, or pentose. Glucomannan is a soluble fiber commonly derived from the Amorphophallus konjac root. Glucomannan is a hemicellulose containing about 60% of mannose and 40% of glucose bonded together by beta-1,4 glycosidic linkages. Like cellulose, hemicelluloses are found in plant cell walls.

Pectins

Pectins are linear sugar polymers (polysaccharides) made of 300 to 1,000 monosaccharides, primarily galacturonic acid residues linked together by alpha-1,4 glycosidic bonds 42. Pectins are soluble viscous fibers that are particularly abundant in berries and other fruit 2.

Gums

Gums are viscous sugar polymers (polysaccharides) often found in seeds 2. Guar gum extracted from guar beans is a galactomannan polysaccharide composed of mannose and galactose residues. Guar gum is used in the food industry for its thickening and stabilizing properties. The viscosity of guar gum is lost when guar gum is partially broken down (hydrolyzed) to derive partially hydrolyzed guar gum (PHGG).

Inulin and oligofructose

Inulin is a mixture of fructose chains that vary in length and often terminate with a glucose molecule 43. Oligofructose is a mixture of shorter fructose chains that may terminate in glucose or fructose. Inulin and oligofructose occur naturally in plants, such as onions and Jerusalem artichokes.

Resistant starch

Resistant starch is a form of starch that is resistant for human enzymatic digestion in the small intestine and can function as a prebiotic or dietary fiber in the large intestine. Resistant starch includes four forms: RS 1 “physically inaccessible”; RS 2 “ungelatinized”; RS 3 “retrograded”; RS 4 “chemically modified”; RS 5 “amylose-lipid complex”. Naturally occurring resistant starch is secluded in plant cell walls and is therefore inaccessible to human digestive enzymes 2. Bananas and legumes are sources of naturally occurring resistant starch. Resistant starch is fermented by bacteria in the large intestine (colon). Resistant starch may also be formed by food processing or by cooling and reheating.

Functional fiber

According to the Institute of Medicine’s definition, functional fiber “consists of isolated, nondigestible carbohydrates that have beneficial physiological effects in humans” 2. Functional fibers may be nondigestible carbohydrates that have been isolated or extracted from a natural plant or animal source, or they may be manufactured or synthesized. However, designation as a functional fiber by the Institute of Medicine requires the presentation of sufficient evidence of physiological benefit in humans. Man-made (synthetic) or isolated non-digestible fibers include: gum acacia (gum arabic), alginate, arabinoxylan, beta-glucan soluble fiber, cellulose, cross linked phosphorylated RS4, galactooligosaccharide, glucomannan, guar gum, high amylose starch (resistant starch 2), hydroxypropylmethylcellulose, inulin and inulin-type fructans, locust bean gum, mixed plant cell wall fibers (a broad category that includes fibers like sugar cane fiber and apple fiber, among many others), pectin, polydextrose, psyllium husk, and resistant maltodextrin/dextrin.

The U.S. Food and Drug Administration (FDA) has identified the following isolated or synthetic non-digestible carbohydrates as meeting the dietary fiber definition 38:

  • Acacia (gum arabic)
  • Alginate
  • Arabinoxylan
  • Beta-glucan soluble fiber
  • Cellulose
  • Cross linked phosphorylated RS4
  • Galactooligosaccharide
  • Glucomannan
  • Guar gum
  • High amylose starch (resistant starch 2)
  • Hydroxypropylmethylcellulose
  • Inulin and inulin-type fructans
  • Locust bean gum
  • Mixed plant cell wall fibers (a broad category that includes fibers like sugar cane fiber and apple fiber, among many others)
  • Pectin
  • Polydextrose
  • Psyllium husk
  • Resistant maltodextrin/dextrin

Fibers identified as potential functional fibers by the Institute of Medicine include:

  • Isolated or extracted forms of the dietary fibers listed above.
  • Psyllium: Psyllium refers to viscous, gel-forming mucilage, which is isolated from the outer coat (husk) of psyllium seeds — known in India as ispaghula husk — from the plant Plantago ovata or blond psyllium 2.
  • Chitin and chitosan: Chitin is a polysaccharide polymer extracted from the exoskeletons of crustaceans, such as crab and lobster 44. Chitin is a polymer of more than 5,000 acetylated glucosamine units linked by beta-1,4 glycosidic bonds. Deacetylated chitin also known as chitosan consists in unbranched chains of glucosamine 42.
  • Fructooligosaccharides: Fructooligosaccharides are short, synthetic fructose chains terminating with a glucose unit. Fructooligosaccharides are used as food additives 43.
  • Galactooligosaccharides: Galactooligosaccharides are produced through the enzymatic conversion of lactose and are classified as prebiotics (a non-digestible food ingredient that promotes the growth of beneficial microorganisms in the intestines) 45. Fibers that are fermentable and can stimulate the growth and/or activity of beneficial gut bacteria are called prebiotic fibers 46.
  • Polydextrose and polyols: Polydextrose and polyols are synthetic carbohydrates. Polydextrose is made of glucose and sorbitol (a sugar alcohol) and may be used as bulking agent in food. Polyols are non-sugar molecules containing multiple hydroxyl groups (-OH). Polydextrose and polyols are used as sugar substitutes in food 2.
  • Resistant dextrins: Resistant dextrins also called resistant maltodextrins are synthetic indigestible polysaccharides formed when starch is heated and treated with enzymes. Maltodextrins are used as food additives 2.

Total fiber

Total fiber is defined by the Institute of Medicine as “the sum of dietary fiber and functional fiber2.

Dietary fiber Other classification systems

Fibers can also be classified into 4 clinically meaningful categories according to their physiochemical properties, i.e., their solubility, viscosity, and fermentability 1:

Soluble, viscous/gel forming, readily fermented fibers

Beta-glucans (oats and barley) and raw guar gum

Soluble fibers dissolve in water, while insoluble fibers do not. Viscous fibers thicken in the presence of water, forming very viscous solutions or even visco-elastic gels. Fermentable fibers are readily broken down (metabolized) by the gut microbiota (i.e., bacteria that normally colonize the large intestine). Fermentation of fiber results in the formation of short-chain fatty acids (acetate, propionate, and butyrate) and gases 12. Short-chain fatty acids can be absorbed and broken down (metabolized) to produce energy. Interestingly, the preferred energy source for epithelial cells that line the large intestine (colonocytes) is butyrate. Fermentation of fiber is estimated to contribute up to 10% of daily energy intake 36. Fibers that are fermentable and can stimulate the growth and/or activity of beneficial gut bacteria are called prebiotic fibers 46. Fibers that are soluble, viscous, and fermentable have been shown to improve blood sugar (glycemic) control and to lower blood cholesterol concentration. However, their water-holding capacity is lost when they are fermented in the large intestine (colon) such that they have no laxative effect.

Soluble, viscous/gel forming, nonfermented fibers

Psyllium

Psyllium refers to viscous, gel-forming mucilage, which is isolated from the outer coat (husk) of psyllium seeds — known in India as ispaghula husk — from the plant Plantago ovata or blond psyllium 2. Psyllium can improve blood sugar (glycemic) control and lower blood cholesterol concentration. In addition, they retain their water-holding/gel-forming capacity in the large intestine since they are resistant to fermentation. As a consequence, psyllium can exert a stool-normalizing effect, preventing constipation or softening hard stool as well as firming loose/liquid stool in diarrhea and fecal incontinence.

Soluble, nonviscous, readily fermented fibers

Inulin, wheat dextrin, oligosaccharides, resistant starches

Although these fibers can dissolve in water, they cannot provide any health benefits associated with fiber viscosity. They are fully fermented and thus do not exert a laxative effect. They can nonetheless exert a prebiotic effect by influencing the composition of the gut microbiota. Test tube studies have shown inulin to selectively stimulate the proliferation of beneficial bacteria and limit the growth of potentially pathogenic bacteria 47. However, no health benefit is currently associated with this fiber-driven prebiotic effect.

Insoluble, poorly fermented fibers

Wheat bran, cellulose, lignin

These fibers do not dissolve in water, do not trap water, and are poorly fermented. Large or coarse fiber particles can have a laxative effect. They can irritate the large intestine mucosa and trigger the secretion of mucus and water, which increases the water content of stools. Small, insoluble fiber particles (e.g., finely ground wheat bran) have no laxative effect and can actually have a constipating effect by adding only to the dry stool mass.

Dietary fiber function

Dietary fiber adds bulk to your diet. Because it makes you feel full faster, it can help with weight control. Fiber aids digestion and helps prevent constipation. It is sometimes used for the treatment of diverticulosis, diabetes, and heart disease.

Dietary fiber health benefits

Dietary fiber contributes to health and wellness in a number of ways 6, 48, 19. First, dietary fiber aids in providing fullness after meals, which helps promote a healthy weight. Second, adequate fiber intake can help to lower cholesterol. Third, it helps prevent constipation and diverticular disease. And fourth, adequate fiber from food helps keep blood sugar levels within a healthy range.

Observational studies and intervention trials have also identified associations between high-fiber intakes and reductions in chronic disease risk. The U.S. Food and Drug Administration (FDA) approved specific health claims related to the cardioprotective effects of two soluble, gel-forming fibers only: beta-glucan and psyllium.

  • Metabolic disease: Improved insulin sensitivity (mainly insoluble fibres); reduced risk of developing type 2 diabetes (mainly insoluble cereal fibres and whole grains); improved glycemic status and lipid profiles (mainly soluble fibres); reduced body weight and abdominal adiposity 20
  • Heart attack, stroke, and cardiovascular disease: Fiber may help prevent heart disease by helping reduce cholesterol. Epidemiologic studies show that a diet high in fiber consumption from whole foods is strongly associated with a reduced risk of heart attack, stroke, and cardiovascular disease 49, 50.
  • Weight management: Fiber slows the speed at which food passes from the stomach to the rest of the digestive system – this can make us feel full longer. Foods that are higher in dietary fiber often are lower in calories as well. Consumption of dietary fiber has been associated with lower risk of obesity 51, 52.
  • Diabetes: Because fiber slows down how quickly food is broken down, it may help control blood sugar levels for people with diabetes by reducing blood sugar levels after meals.
  • Digestive issues: Fiber increases bulk in the intestinal tract and may help improve the frequency of bowel movements.

Improving regularity in bowel movements

Of all the beneficial effects of dietary fiber and the most widely known is the effect on gut motility and prevention of constipation. There are two mechanisms that support the laxative effects of certain fiber types: (i) large/coarse insoluble fiber (e.g., wheat bran) has an irritating effect on the colonic mucosa, which stimulates the secretion of water and mucus (unlike finely ground wheat bran that has a stool-hardening/constipating effect); and (ii) the presence of soluble viscous, gel-forming fiber (e.g., psyllium) helps stool to resist dehydration in the colon 53. Therefore, only fibers that remain relatively intact during the transit throughout the length of the colon (i.e., that resists bacterial fermentation) and are thus found in the stool can have a potential laxative effect.

In one randomized controlled double-blind trial on the effects of ‘vege-powder’ consisting of chicory, broccoli and whole grains on constipation alleviation in >90 participants, compared with the control group, those who received ‘vege-powder’ had significant improvements in symptoms of constipation including stool hardness, defecation frequency and straining to defecate at 2 and 4 weeks 54. Further evidence to support the clinical utility of dietary fiber as an effective treatment of constipation stems from a systematic review reported by Rao et al. 55. Evidence was sought for dietary fiber intake and restrictions in fermentable oligosaccharide, disaccharide, monosaccharide and polyol (FODMAP-restricted diet) in the management of chronic constipation and irritable bowel syndrome (IBS) 55. For chronic constipation, dietary fiber was beneficial in five of the seven studies examined, and all three of the studies of IBS-associated constipation 55. The FODMAP-restricted diet also appeared to improve overall IBS symptoms 55. Current evidence would appear to support the beneficial effects of dietary fiber on gut motility and as an effective management strategy for both the prevention and treatment of constipation.

A 2016 review of fiber interventions conducted by McRorie and Chey 56 examined the potential laxative effect of fermentable fiber; the main findings of this review are summarized in Table 1 below.

In summary, although the bulk of evidence comes primarily from studies in healthy subjects, supplementation with fermentable fibers appears unlikely to exert a laxative effect in people suffering from constipation (Table 1) 56. In contrast, a 2016 meta-analysis of seven randomized controlled trials identified psyllium and nonprebiotics as effectively able to increase stool frequency and improve stool consistency in participants affected by chronic idiopathic constipation 57.

Table 1. Laxative effect of fermentable fiber

FiberType of FiberNumber of StudiesDosesLaxative EffectsAdverse Effects
Beta-glucan, guar gum, xanthan gumSoluble, viscous, fermentable5 studies: all conducted in healthy participants; 3 studies with β-glucan and 2 studies (guar gum, xanthan gum)87-100 g/day (beta-glucan) and 15 g/day (guar gum, xanthan gum)• Stool hardening effect and minimal increase in stool output (β-glucan)
• No effect on stool output and stool consistency (guar gum, xanthan gum)		Not reported
InulinSoluble, nonviscous, fermentable11 studies: 3 studies in people with constipation and 8 studies in healthy people5-20 g/day• No effect on colonic transit time, stool consistency, stool water content, or stool outputAbdominal pain, bloating, flatulence, and borborygmus (1 study)
PolydextroseSoluble, nonviscous, fermentable6 studies: all conducted in healthy participants8-30 g/day• No effect on stool output, consistency, bowel movement frequency, or colonic transit timeFlatulence and borborygmus (1 study)
Resistant starch (incl. resistant dextrin)Soluble, nonviscous, fermentable6 studies: all conducted in healthy participants7.5-15 g/day• Stool hardening effect and reduction in stool output (2 studies)
• No effect on consistency, stool water content, stool output, or bowel movement frequency (4 studies)		Not reported
[Source 56 ]

Chronic idiopathic constipation

Only insoluble fibers and soluble viscous fibers that resist bacterial fermentation in the colon have a potential laxative effect 53. The prevalence of chronic constipation is higher among people with diabetes mellitus, in women during pregnancy and after delivery, or in older people. The management of constipation in these patients is usually similar to the management in the rest of the population, although the cause might be different. Bulk-forming laxatives, including psyllium, bran, and methylcellulose, are commonly recommended to improve stool regularity in patients with diabetes mellitus 58. However, there is no evidence that methylcellulose and bran are efficacious in patients with constipation (116). In these patients, psyllium is also recognized to improve glycemic control. There is a need for good quality, randomized, double-blind, controlled trials to examine the effect of fiber supplementation in the treatment of constipation in older adults in long-term care 59 or in pregnant women and new mothers 60, 61.

The American College of Gastroenterology recognizes the efficacy of soluble fiber in the treatment of chronic idiopathic constipation. It also recognizes that the evidence from observational studies is mixed, as constipation is associated with low-fiber diets in some, but not all, studies 62. The American College of Gastroenterology recommends a gradual increase in fiber intake, in particular to limit the potential adverse effects associated with the intake of insoluble fiber, i.e., bloating, distension, flatulence, and cramping 63.

Irritable bowel syndrome (IBS)

Irritable bowel syndrome (IBS) is a functional disorder of the intestines, characterized by episodes of abdominal pain or discomfort associated with altered gut mobility and changes in bowel habits (i.e., with constipation, diarrhea, or both) 64. Although the pathophysiology of IBS remains unclear, certain food components have been recognized as a cause for symptoms of IBS. Dietary restriction of highly fermentable, soluble, short-chain carbohydrates, identified as FODMAP (Fermentable Oligosaccharides, Disaccharides, Monosaccharides, and Polyols) and including some dietary fibers (e.g., fructans, galactooligosaccharides), has been found to relieve IBS symptoms, including abdominal pain/discomfort, abdominal bloating/distension, and flatulence 65. On the other hand, soluble, poorly fermentable, long-chain carbohydrate fiber types may improve the symptoms related to excessive gas production. Two meta-analyses of randomized controlled trials and cross-over studies found a beneficial effect of fiber that was limited to soluble fiber, primarily psyllium 66, 67. Accordingly, the American College of Gastroenterology recognizes that soluble fiber like psyllium can provide overall symptom relief in IBS, while insoluble fiber (e.g., wheat bran) can cause bloating and abdominal discomfort 63. More research is needed to document the effect of specific soluble fibers, considering physicochemical properties (viscosity and fermentability), doses, and duration of supplementation, and to provide stronger recommendations to individuals diagnosed with IBS 67. Future trials should also consider subjects with all of the IBS types, i.e., constipation-predominant, diarrhea-predominant, and mixed-diarrhea-and-constipation IBS.

Diverticular disease

Diverticular disease or diverticulosis is a rather common gastrointestinal condition in Western countries characterized by the formation of small pouches (diverticula) in the colon 68. Acute inflammation or infection of diverticula — known as diverticulitis — occurs in about 10%-25% of all symptomatic cases of diverticulosis and is caused by the irritation of the mucosa by fecalith obstructing diverticula. Complications of diverticulitis include abscesses, fistulas, obstruction, and perforation 69. The cause of diverticulosis is thought to be multifactorial, involving both genetic and environmental risk factors. Despite little supporting evidence, it has been proposed that low fiber intakes that characterize Western diets might contribute to increasing the risk of diverticulosis 69, 70. This low-fiber hypothesis is disputed. In particular, a 2012 cross-sectional study of 2,104 adults found higher odds of diverticula (assessed by colonoscopy) among participants in the highest versus lowest quartile of fiber intake, measured by food frequency questionnaires 71.

A 2017 review identified interventions — published over four decades — that examined the effect of dietary or supplemental fiber on the reduction of abdominal pain in patients suffering from symptomatic uncomplicated diverticular disease (SUDD), as well as on the risk of acute diverticulitis 72. However, a meta-analysis could not be conducted nor any conclusion provided regarding the efficacy of fiber in the treatment of symptomatic uncomplicated diverticular disease (SUDD) due to the very poor quality of the studies and their substantial heterogeneity in terms of study design and quantity and quality of fiber types used 72. Another recent review of the literature focused on the effect of fiber-restricted diets in the management of acute uncomplicated diverticulitis 73. Based on the review of three randomized controlled trials and two observational studies, the authors found a reduced length of hospital stay with non-restricted diets compared to restricted diets, but no difference regarding the incidence of treatment failure (i.e., the risk of no clinical improvement with therapy and the development of complications) and the risk of post-discharge reoccurrence of diverticulitis. While there appears to be no clinical benefit in restricting fiber intake in subjects with uncomplicated diverticulitis, the quality of the studies was once again deemed to be very low 73.

Despite the lack of high-quality evidence regarding the potential benefit of fiber in the management of diverticular disease, many national guidelines recommend the use of high-fiber diets in patients with symptomatic uncomplicated diverticular disease (SUDD) and for the prevention of diverticulitis 74, 75.

Hemorrhoids

A limited number of interventions have examined the effect of fiber supplementation in subjects with symptomatic hemorrhoids. A randomized controlled trial in 67 participants found that supplementation with psyllium (7 g/day for 6 weeks) improved stool consistency and regularity, reduced the use of laxatives, and increased the quality of life compared to a placebo 76. Another randomized controlled trial in 50 patients with hemorrhoidal prolapse (grades II-IV) and rectal bleeding showed that psyllium supplementation (11.6 g/day for 40 days) reduced the number of bleeding episodes and the number of congested hemorrhoidal cushions but had no effect on the degree of prolapse 77. Finally, a more recent uncontrolled intervention in 102 individuals with advanced hemorrhoids (grades II-IV) examined the effect of counseling patients to follow a therapy meant to improve defecatory habits and involving an increase of psyllium intake to 20 g/day-25 g/day. A follow-up for a median 40 months suggested that psyllium supplementation might help halt the progression of hemorrhoidal prolapse and reduce the number of bleeding episodes 78.

Diarrhea associated with enteral nutrition

Gastrointestinal disorders associated with enteral nutrition prolong the time to recovery. A 2015 meta-analysis of 14 intervention studies found that fiber-enriched enteral formulas and/or fiber supplements reduced the overall incidence of diarrhea in patients requiring enteral nutrition 79. There was no reduction in incidental diarrhea when the analysis was restricted to studies that used prebiotic fiber (i.e., fermentable fiber influencing microbiota composition). Subgroup analyses also showed a benefit of fiber in non-critically ill patients but not in critically ill patients 79.

Fecal incontinence

A prospective cohort study that followed nearly 60,000 older women for four years found that the highest versus lowest level of fiber intake (mean, 25 g/day versus 13.5 g/day) was associated with a 17% lower risk of developing fecal incontinence (defined here as an incontinence episode of liquid or solid stool at least once a month) 80. A limited number of studies have also examined whether fiber supplementation might help treat established fecal incontinence. In one placebo-controlled trial, 206 subjects suffering from fecal incontinence were randomized for 32 days to receive fibers with different degrees of fermentability: gum arabic (on average, 16.6 g/day; highly fermentable), sodium carboxymethylcellulose (16.2 g/day; partially fermentable), and psyllium (14.6 g/day; poorly fermentable) 81. The frequency of fecal incontinence increased with sodium carboxymethylcellulose but decreased with gum arabic and psyllium compared to placebo. Stool consistency and amount did not differ among groups 81. A randomized, cross-over trial in 80 community-dwelling participants with at least one fecal incontinence episode per week found that the reduction in fecal incontinence frequency and severity with psyllium supplementation was equivalent to that observed with antidiarrheal drug loperamide (Imodium) 82.

Lowering blood cholesterol

Some, but not all, fibers can improve blood lipid (fat) abnormalities observed in conditions like hyperlipidemia, overweight/obesity, type 2 diabetes mellitus, and metabolic syndrome. Only supplementation with highly viscous fibers (i.e., gel-forming soluble fibers), such as high molecular weight beta-glucan (found in oat bran), raw guar gum, and psyllium, has been shown to decrease total and low-density-lipoprotein (LDL or “bad”) cholesterol concentrations when compared to appropriate controls (e.g., fiber-free supplement, low-fiber supplement, or supplementation with insoluble fiber) 53. A 2009 meta-analysis that combined the results of 21 randomized controlled trials in 1,717 participants with high cholesterol (hypercholesterolemia) found dose- and time-dependent reductions in total and LDL (“bad”) cholesterol concentrations with psyllium supplementation (3.0-20.4 g/day for >2 weeks) 83. Additionally, results from two trials showed that, compared to statins alone, combining psyllium and statins resulted in larger reductions in LDL-cholesterol concentrations in individuals with high cholesterol (hypercholesterolemia) 84. Another more recent meta-analysis of 28 randomized controlled trials examined the cholesterol-lowering effect of psyllium fiber on LDL-cholesterol, non-HDL-cholesterol, and apolipoprotein B (apo B) 85 — non-HDL-cholesterol and apo B appear to better predict cardiovascular events than LDL-cholesterol 86. Supplementation with psyllium at a median dose of 10.2 g/day and for a median of eight weeks to participants with or without hypercholesterolemia reduced LDL-cholesterol by 0.33 mmol/L (28 trials; 1,924 participants), non-HDL-cholesterol by 0.39 mmol/L (27 trials; 1,899 participants), and apo B by 0.05 g/L (9 trials; 895 participants) 85.

Despite considerable differences across the studies, the cholesterol-lowering efficacy of other highly viscous fibers, including beta-glucans from oat or barley and glucomannan (a hemicellulose), was also reported in recent meta-analyses of trials conducted by one research team 87, 88. The cholesterol-lowering effect of soluble fibers, such as psyllium and beta-glucan, is directly linked to their high viscosity. Reduction of the gel-forming capacity of these fibers with pressure and/or heat during processing leads to the loss of their cholesterol lowering capacity 89. Accordingly, low-viscosity soluble fibers (e.g., gum arabic/acacia gum, methylcellulose, low molecular weight beta-glucan), nonviscous soluble fermentable fibers (e.g., inulin, fructooligosaccharides, wheat dextrin), and insoluble fibers (e.g., wheat bran) do not decrease serum cholesterol at physiologic levels 53.

Highly viscous fibers can trap bile that is released in the small intestine in response to a meal to assist the digestion and absorption of fatty acids. The main mechanism underlying the cholesterol-lowering effect of these fibers is linked to their ability to prevent the reabsorption of bile in the terminal ileum and facilitate its elimination in the stool. In order to maintain sufficient bile for digestion, liver cells (hepatocytes) must increase LDL-cholesterol clearance to synthesize more bile acids as cholesterol is a component of bile 53.

These findings led the U.S. Food and Drug Administration (FDA) to approve health claims in relation to the prevention of heart disease on labels of low cholesterol/saturated fat foods containing ≥0.75 g/serving of beta-glucan from whole oat or barley or ≥1.7 g/serving of psyllium 90.

Cardiovascular disease prevention

Prospective cohort studies have consistently reported associations between high intakes of fiber-rich foods and low risks of coronary heart disease (coronary artery disease) and total cardiovascular disease. Three large prospective cohort studies 91, 50, 92 found that dietary fiber intakes of approximately 14 g per 1,000 kcal of energy were associated with substantial (16-33%) decreases in the risk of coronary artery disease; these results are the basis for the Institute of Medicine’s Adequate Intake (AI) recommendation for fiber 2. A 2013 meta-analysis of 17 prospective cohort studies found each 7 g/day increase in total dietary fiber intake to be associated with a 9% decrease in risk of coronary or total cardiovascular events 93. The most recent meta-analysis that included 18 prospective studies, with a total of 672,408 participants, found a 7% lower risk of coronary heart disease and a 17% lower risk of coronary heart disease-related mortality with the highest versus lowest intakes of total dietary fiber 94. Subgroup analyses by type or source of dietary fiber showed evidence of inverse associations between cereal, fruit, or soluble fiber intake and the risk of coronary heart disease 94.

The U.S. Food and Drug Administration (FDA) has approved health claims like the following on the labels of foods containing at least 0.75 g/serving of beta-glucan soluble fiber: “Diets low in saturated fat and cholesterol that include at least 3 g/day of β-glucan soluble fiber from either whole oats or barley or a combination of both may reduce the risk of coronary heart disease” 90. Similarly, the FDA has approved health claims on the labels of foods containing at least 1.7 g/serving of psyllium: “Diets low in saturated fat and cholesterol that include at least 7 g/day of soluble fiber from psyllium seed husk may reduce the risk of heart disease” 90.

While the cholesterol-lowering effect of viscous/gel-forming soluble fibers is recognized as a major contributor to the cardioprotective effects of fiber, other mechanisms are likely to be involved. Findings from pooled analyses of prospective cohort studies found some evidence of an inverse association between the risks of coronary heart disease (coronary artery disease) and total cardiovascular disease and intakes of insoluble fiber 93, 94. In addition, a cross-sectional analysis of 2005-2010 National Health and Nutrition Examination Survey (NHANES) data found dietary fiber intake to be inversely associated with serum LDL (“bad”) cholesterol concentration, but also with blood pressure, body mass index (BMI), and serum insulin concentration 95. Beneficial effects of fiber-rich diets or isolated fiber consumption on blood glucose and insulin responses and on blood pressure may also likely contribute to observed reductions in coronary heart disease (coronary artery disease) risk.

Improving blood sugar control

The efficacy of fiber on blood sugar (glycemic) control is dependent on its viscosity. A 2017 review of 14 randomized controlled trials showed that none of the supplemented soluble, nonviscous, fermentable fibers examined (i.e., inulin, fructooligosaccharide, galactooligosaccharide, and oligofructose) could lead to reductions in after meal and/or fasting blood glucose concentrations 53. Supplementation with insoluble fiber also failed to improve blood sugar control in subjects with elevated fasting blood glucose concentrations 96. In contrast, the capacity of dietary viscous fiber 97, 98 and isolated viscous fibers 99, 100, 101, 102 to improve blood sugar control has been demonstrated in numerous controlled clinical trials conducted over three decades 53.

A 2015 review of psyllium showed evidence of reductions in after meal blood glucose concentration following a single meal in people with type 2 diabetes mellitus (6 studies) as well as in nondiabetic or normal glycemic subjects (11 studies) 103. Supplementation with psyllium also resulted in reductions in after meal blood insulin concentrations in subjects without type 2 diabetes (6 studies) but not in those with type 2 diabetes (3 studies). Longer-term studies of psyllium supplementation also found reductions in mean fasting glucose (4 studies) and mean glycated hemoglobin (HbA1c; 3 studies) in subjects with type 2 diabetes. Finally, while there was no effect of long-term exposure to psyllium on fasting glucose concentration in healthy individuals with euglycemia (14 studies), the glycemic benefit of psyllium was found to increase proportionally with the increase of baseline fasting glucose concentration 103.

The role of soluble viscous fibers on blood sugar control is related to their ability to increase chyme (the semifluid mass of partly digested food expelled by the stomach into the duodenum) viscosity, thereby slowing the degradation of complex nutrients and allowing the absorption of nutrients, including glucose, along the entire small intestine rather than in the upper small intestine. Absorption of nutrients in the distal ileum has been associated with a reduction in gastric emptying and intestinal transit — through a distal to proximal feedback mechanism — which in turn reduces hunger and food intake 53. Nutrient delivery in the distal ileum also triggers the release of short-lived glucagon-like peptide 1 (GLP-1) into the circulation. GLP-1 improves insulin secretion by pancreatic beta-cells in response to glucose absorption and is involved in the regulation of food intake at the central nervous system level 104.

Type 2 diabetes mellitus

A 2014 meta-analysis of prospective cohort studies (488,293 participants) found intakes of total fiber (12 studies), cereal fiber (10 studies), fruit fiber (8 studies), and insoluble fiber (3 studies) to be inversely associated with the risk of developing type 2 diabetes mellitus 105. A dose-response data analysis reported a nonlinear relationship between total fiber intake and diabetes risk, with evidence of risk reduction with total fiber intakes ≥25 g/day. A linear dose-response relationship between cereal fiber intake and diabetes risk indicated a 6% reduction in diabetes risk for each 2 g-increment in daily cereal fiber intake 105. There was no evidence of an inverse association between either vegetable fiber (9 studies) or soluble fiber (3 studies) and the risk of type 2 diabetes 105. Similar findings were reported in another meta-analysis of 18 prospective cohort studies in 617,968 participants 106. Higher versus lower intakes of total fiber were found to be associated with a 15% lower risk of type 2 diabetes (17 studies); the risk of type 2 diabetes was inversely related to the intake of cereal fiber (13 studies) and insoluble fiber (3 studies) but not related to the intake of fruit fiber (11 studies), vegetable fiber (11 studies), or soluble fiber (3 studies) 106. However, only randomized controlled interventions can establish whether there is a link of causality between an exposure (fiber intake) and an outcome (type 2 diabetes).

Whole-grain cereals contain insoluble fibers, including cellulose, hemicellulose, and lignin. To date, intervention studies examining the effect of cereal fiber supplementation on the risk of type 2 diabetes are limited 107. In a randomized controlled study of 61 adults with metabolic syndrome, the consumption of a diet based on several whole-grain cereal products for 12 weeks had no effect on fasting plasma concentrations of glucose, insulin, or lipids, or on measures of insulin resistance compared with a refined grain-based diet (47). There was only some weak evidence of an effect of whole-grain cereals on postprandial insulin response 108. A recent 24-month, randomized, double-blind, placebo-controlled trial examined the effect of daily supplementation with 15 g of primarily insoluble fiber on glycemic control in 180 adults with impaired glucose tolerance who were counselled to adopt more healthy lifestyle habits. Insoluble fiber supplementation failed to improve fasting glucose concentration, measures of insulin sensitivity, HbA1c concentration (a marker of glycemic control), as well as glucose and insulin responses after a glucose load compared to placebo 96. Although observational data suggest a protective association of cereal fiber against type 2 diabetes, the current evidence from intervention trials does not support a role for insoluble fiber in blood sugar control in individuals at risk of type 2 diabetes.

Fiber-related benefits on glucose homeostasis have been linked to the viscosity of certain soluble fibers (e.g., psyllium, beta-glucan, raw guar gum). Soluble viscous fibers in cereal, particularly beta-glucans, rather than insoluble fiber and soluble nonviscous fiber, are thus more likely to be involved in a protective effect of cereal intake against type 2 diabetes 109. Apart from fiber, other bioactive compounds in cereal, like magnesium, might contribute to improving blood sugar control in people with impaired glucose tolerance 110.

A 2004 meta-analysis that combined the results of 23 clinical trials in patients with type 1 or type 2 diabetes mellitus found that high-fiber diets (≥20 g/1,000 kcal) lowered postprandial blood glucose concentrations by 13%-21%, serum LDL cholesterol concentrations by 8%-16%, and serum triglyceride concentrations by 8%-13% when compared with low-fiber diets (<10 g/1,000 kcal) 111. Based on the evidence from this meta-analysis, the authors recommended a dietary fiber intake of 25-50 g/day (15-25 g/1,000 kcal) for individuals with diabetes, which is slightly higher than recommendations for the general public (14 g/1,000 kcal) 2. However, recommendations from the American Diabetes Association and the Academy of Nutrition and Dietetics to people with diabetes are similar to those prescribed for the population as a whole 112, 113.

The current position of the American Diabetes Association is to encourage people at risk of type 2 diabetes to achieve the daily Adequate Intake (AI) of 14 g/1,000 kcal for dietary fiber 114. Adherence to a Mediterranean-style diet (rich in fruit, vegetables, and whole grains), the composition of which intends to meet the adequate intake for fiber, has been associated with a lower risk of developing type 2 diabetes 115, 116. A 2015 meta-analysis of nine randomized controlled trials in a total of 1,178 participants with type 2 diabetes showed evidence of body weight loss and improvements in glycemic control and blood lipid profile with the consumption of a Mediterranean-style diet compared to a control diet 117.

Numerous controlled clinical trials have shown that supplementation with soluble viscous fibers improves markers of glycemic control in people who have type 2 diabetes mellitus. A meta-analysis of 28 trials in 1,394 adults with type 2 diabetes found reductions in HbA1c concentration (20 trials), fasting glucose concentration (28 trials), and insulin resistance (11 trials) with soluble viscous fiber supplementation (median doses of 10.5-15 g/day for 6-8 weeks) 118. Another meta-analysis of 35 trials showed that the effect of psyllium varied with baseline fasting glucose concentration: psyllium supplementation had no effect on markers of glycemic control in euglycemic participants but showed a modest benefit in subjects with impaired glucose tolerance, and a greater effect in those with overt type 2 diabetes 103.

A small randomized uncontrolled trial in 20 healthy participants suggested that supplemental wheat dextrin, which is partially absorbed as sugar in the small intestine, could increase fasting glucose concentration into the prediabetes range after one month of supplementation 119. Since there is little evidence from clinical trials that increasing nonviscous fiber alone is beneficial 120, individuals with diabetes should preferably increase fiber intake from sources of soluble viscous fibers, such as oats and barley (beta-glucans), vegetables, beans, and legumes 111.

Lowering blood pressure

An analysis of 2004-2014 US National Health and Nutrition Examination Survey (NHANES) data from 18,433 participants found inverse associations between either total, cereal, or vegetable fiber intake and the odds of high blood pressure (hypertension) 121. A 2018 meta-analysis of 22 randomized control trials that examined the effect of isolated soluble fiber supplements or diets enriched with soluble viscous fiber in either normal blood pressure or hypertensive participants found an overall 1.59 mm Hg reduction in systolic blood pressure and 0.39 mm Hg reduction in diastolic blood pressure 122. Further analyses showed that, among all the soluble viscous fiber under examination (beta-glucan [oat], guar gum, konjac glucomannan, pectin, and psyllium), only psyllium could reduce systolic blood pressure (mean reduction of 2.39 mm Hg) 122. It is not yet understood how soluble viscous fiber would induce a lowering of blood pressure, but this effect may be indirect and dependent on established benefits of these fiber on other cardiometabolic parameters.

Metabolic syndrome

Metabolic syndrome also called insulin resistance syndrome is the name for a group of conditions that together raise your risk of coronary heart disease, diabetes, stroke, and other serious health problems. You can have just one condition, but people often have several of them together. When you have at least three of them, it is called metabolic syndrome. These risk factors or conditions include:

  • A large waistline, also called abdominal obesity or “having an apple shape”. Too much fat around your stomach area is a greater risk factor for heart disease than too much fat in other parts of your body.
  • High triglyceride level. Triglycerides are a type of fat found in your blood. High levels of triglycerides can raise your levels of LDL cholesterol (bad cholesterol). This raises your risk of heart disease.
  • Low HDL cholesterol level. HDL is sometimes called the “good” cholesterol because it helps remove cholesterol from your arteries. Blood cholesterol levels are important for heart health. “Good” HDL cholesterol can help remove “bad” LDL cholesterol from your blood vessels. “Bad” LDL cholesterol can cause plaque buildup in your blood vessels.
  • Having high blood pressure. If your blood pressure stays high over time, it can damage your heart and lead to other health problems. High blood pressure can also cause plaque, a waxy substance, to build up in your arteries. Plaque can cause heart and blood vessel diseases such as heart attack or stroke.
  • High fasting blood sugar levels. Mildly high blood sugar may be an early sign of diabetes. Mildly high blood sugar can damage your blood vessels and raise your risk of getting blood clots . Blood clots can cause heart and blood vessel diseases.

The more risk factors you have, the higher your risk for heart disease, diabetes, and stroke is.

Metabolic syndrome is common in the United States. Metabolic syndrome is estimated to affect nearly 35% of US adults and half of those older than 60 years 123. Two recent meta-analyses of observational studies have reported an inverse association between total fiber intake and odds of metabolic syndrome in cross-sectional studies (observational studies that analyze data from a population at a single point in time) but not in prospective cohort studies (a type of observational study focused on following a group of people [a cohort] over a period of time, collecting data on their exposure to a factor of interest) 124, 125.

In this study 126, 111 overweight adults with features of the metabolic syndrome were randomly assigned to one of four 18-week isoenergetic diets, including control, high cereal fiber, high protein and mixed high cereal fiber and protein (Mix) groups. Amongst the 84 participants who completed the dietary intervention, it was demonstrated that compared with the high protein diet group, insulin sensitivity was significantly (25%) higher in the high cereal fiber group 126. Furthermore, high cereal fiber intake prevented the reduction of insulin sensitivity upon increased protein intake 126. The effects of high cereal fiber on insulin sensitivity at 18 weeks likely related to diminished adherence to the high protein diet 126.

There have also been reports from observational studies to corroborate the metabolic benefits of dietary fiber. In one such study, Morimoto and colleagues 127 reported on a study on a Japanese cohort (n = 190) without type 2 diabetes to explore the metabolic effects of dietary fiber intake in the context of a diet and exercise program. Increases in the ratio of dietary fiber to carbohydrate intake during the 5-month period of the study associated significantly with a reduction in HbA1C 127. The authors suggested the potential utility of an increased dietary ratio of fiber to carbohydrate in the prevention of type 2 diabetes 127. In a separate study from Mexico on 217 adolescents 128, it was demonstrated that those with the highest dietary fiber intake had lower odds of Homeostatic Model Assessment for Insulin Resistance (HOMA-IR) >2.97, following adjustments for age, sex, body fat percentage and intake of saturated fatty acids. In a recent systematic review and meta-analysis on the effects of dietary fiber and whole grains in the management of Diabetes Mellitus, there was an association of high-fiber diet with improved insulin sensitivity, including many other aspects of metabolic health, such as HbA1C, lipid profile, body weight and C-reactive protein 129. A recent systematic review and meta-analysis of twenty-one randomized controlled trials in patients with type 2 diabetes reported that, compared to controls, dietary fiber at a median daily dose of 10 g/day for a mean intervention duration of 8 weeks significantly reduced glycated hemoglobin A1c (HbA1c), fasting glucose and insulin, and Homeostatic Model Assessment for Insulin Resistance (HOMA-IR) 130. Both soluble fiber products and fiber from natural foods were found to be effective in improving glycemic control and insulin sensitivity in type 2 diabetes patients, with the former yielding better effects 130. There is, however, a deficiency of published longer-term controlled studies (>12 months) on the metabolic effects of increasing dietary fiber intake 129, and this should be a focus for future research in this field.

A high intake of soluble dietary fiber appears to have additional metabolic benefits, including improved glycemic index of carbohydrate-rich foods and lipid profiles 131, 132, 133. However, it is mainly the consumption of insoluble cereal dietary fiber and whole grains and not soluble fiber that associate consistently with a reduced risk for the development of type 2 diabetes in large prospective cohort studies 19, 134, 135. Other effects of dietary fiber that may also have an impact on overall metabolic health include the release of various gut hormones 136, 137, 138, 139, 140, 141, adipokines 142, bile acids 143 and the metabolic signatures of amino acids 144. Based on the current scientific evidence from prospectively designed and controlled studies, dietary fiber does appear to associate with improvements in insulin sensitivity and overall metabolic status. Future studies should focus on the underlying mechanisms implicated, which mediate the metabolic benefits of dietary fiber.

Cancer prevention

Numerous observational studies have examined the relationship between consumption of fiber and risk of cancer at various sites. A 2014 review compiled published analyses of data from the large, multicenter European Prospective Investigation into Cancer and Nutrition (EPIC) prospective cohort (>500,000 participants) 145. This European Prospective Investigation into Cancer and Nutrition (EPIC) review reported evidence of inverse associations between higher versus lower daily total fiber intakes (≥28.5 g/day versus ≤16.4 g/day) and the risk of colorectal, liver, and breast cancers 145. Total fiber intakes were not associated with the risk of cancer at other sites, i.e., the biliary tract, endometrium, prostate, kidney, or bladder. In addition, further analyses suggested that the consumption of cereal fiber was inversely related to the risk of colorectal, stomach, and liver cancers, and vegetable fiber intake was inversely associated with breast cancer 145. Yet, associations between the consumption of specific fiber types were not examined in relation to the risk of endometrial, kidney, or bladder cancer in EPIC participants 145.

The preventive effect of dietary fiber on the development of cancer is consistent with the results of a meta-analysis of a large sample published by Andrew Reynolds in The Lancet 146, which showed a 13% reduction of cancer mortality in those who consumed the most dietary fiber compared to those who ate the least. Dietary fiber can increase stool volume and decrease stool transit time, therefore diluting the concentration of carcinogens in the colon and reducing the time of intestinal exposure to carcinogens 147. Dietary fiber binds bile acids and alters the enterohepatic axis, which can reduce cholesterol levels involved in the cause of colon cancer 148. In contrast, secondary bile acids produced by bile acid metabolism are thought to be promoters of colorectal cancer 149, 150, which can cause significant damage to the colonic mucosa, such as oxidative stress and inflammation 151:S67–S69. doi: 10.1097/MCG.0000000000000252)). Dietary fiber is broken down by intestinal flora into short-chain fatty acids (SCFA), such as acetate, propionate, and butyrate, which can decrease intestinal luminal pH, which helps reduce the conversion of proto-bile acids to carcinogenic secondary bile acids 152. Moreover, butyrate not only provides energy to normal colonic epithelial cells but also induces excessive activation of Wnt signaling in colon cancer cells, an event necessary to achieve high levels of apoptosis in these cells, where Wnt activity is associated with cancer cell proliferation 153. Furthermore, under acidic conditions, dietary fiber has been shown to remove nitrite from the stomach 154 and decrease the concentration of nitroso compounds, which increase the risk of gastric cancer 155. It has been shown that dietary fiber is negatively associated with precancerous lesions in esophageal cancer, and the potential mechanisms include improvement of gastroesophageal reflux and weight control, adsorption of carcinogens contained in food, improvement of cancer-associated esophageal ecological dysregulation, and direct action on cancer cells 156, 157, 158, 159.

Pooling information from individual observational studies can be helpful to draw conclusions regarding the potential associations between dietary fiber consumption and cancer risk. Results from the most recent meta-analyses of observational studies are reported in Table 2 below.

Table 2. Dietary fiber intake and cancer risk

Type of CancerType of Observational StudiesRisk Ratio [RR] or Odds Ratio [OR]* (95% Confidence Interval)Risk Ratio [RR] in Subgroup Analyses (e.g., by fiber type, study type, and cancer subtype)References
Breast cancer16 prospective cohort studiesRR: 0.93 (0.89-0.98)RR: 0.95 (0.86-1.06) in studies reporting on fruit fiber
RR: 0.99 (0.92-1.07) in studies reporting on vegetable fiber
RR : 0.96 (0.90-1.02) in studies reporting on cereal fiber
RR: 0.91 (0.84-0.99) in studies reporting on soluble fiber
RR: 0.95 (0.89-1.02) in studies reporting on insoluble fiber		Aune et al. 160
20 prospective cohort and 4 case-control studiesRR: 0.88 (0.83-0.93)RR: 0.91 (0.87-0.95) in cohort studies only
RR: 0.75 (0.47-1.02) in case-control studies only		Chen et al. 161
Colorectal adenoma4 prospective cohort and 16 case-control studiesRR: 0.72 (0.63-0.83)RR: 0.84 (0.76-0.94) in studies reporting on fruit fiber
RR: 0.93 (0.84-1.04) in studies reporting on vegetable fiber
RR : 0.76 (0.62-0.92) in studies reporting on cereal fiber
RR: 0.92 (0.76-1.10) in cohort studies only
RR: 0.66 (0.56-0.77) in case-control studies only		Ben et al. 162
Colorectal cancer11 prospective cohort studiesRR: 0.86 (0.78-0.95) for proximal colorectal cancerRR: 0.93 (0.72-1.14) in women only
RR: 0.79 (0.71-0.87) in men only		Ma et al. 163
RR: 0.79 (0.71-0.87) for distal colorectal cancerRR: 0.70 (0.52-0.87) in women only
RR: 0.85 (0.74-0.95) in men only
13 prospective cohort and 8 case-control studiesRR: 0.74 (0.67-0.84)RR: 0.81 (0.74-0.89) in cohort studies only
RR: 0.58 (0.50-0.68) in case-control studies only		Gianfredi et al. 164
Endometrial cancer3 prospective cohort and 11 case-control studiesRR: 0.86 (0.73-1.02)RR: 1.22 (1.00-1.49) in cohort studies only
OR: 0.76 (0.64-0.89) in case-control studies only
RR: 1.26 (1.03-1.52) in studies reporting on cereal fiber
OR: 0.74 (0.58-0.94) in studies reporting on vegetable fiber		Chen et al. 165
Esophageal cancer9 case-control studiesOR: 0.66 (0.44-0.98) for esophageal adenocarcinoma
OR: 0.61 (0.31-1.20) for esophageal squamous cell carcinoma		Coleman et al. 166
15 case-control studiesOR: 0.52 (0.43-0.64)OR: 0.42 (0.29-0.61) for Barrett’s esophagus (precancerous lesions)
OR: 0.56 (0.37-0.67) for esophageal adenocarcinoma
OR: 0.53 (0.31-0.90) for esophageal squamous cell carcinoma
OR: 0.73 (0.48-1.12) in studies reporting on fruit fiber
OR: 0.61 (0.45-0.83) in studies reporting on vegetable fiber
OR : 0.81 (0.61-1.07) in studies reporting on cereal fiber
OR: 0.85 (0.65-1.11) in studies reporting on grain fiber
OR: 0.40 (0.20-0.78) in studies reporting on soluble fiber
OR: 0.37 (0.18-0.75) in studies reporting on insoluble fiber		Sun et al. 167
Gastric cancer2 prospective cohort and 19 case-control studiesOR: 0.58 (0.49-0.67)OR: 0.67 (0.46-0.99) in studies reporting on fruit fiber
OR: 0.72 (0.57-0.90) in studies reporting on vegetable fiber
OR: 0.58 (0.41-0.82) in studies reporting on cereal fiber
OR: 0.41 (0.32-0.52) in studies reporting on soluble fiber
OR: 0.42 (0.34-0.52) in studies reporting on insoluble fiber		Zhang et al. 168
Ovarian cancer5 prospective cohort and 14 case-control studiesRR: 0.70 (0.57-0.87)RR: 0.97 (0.85-1.12) in cohort studies
RR: 0.62 (0.47-0.82) in case-control studies		Xu et al. 169
4 prospective cohort and 13 case-control studiesRR: 0.76 (0.70-0.82)RR: 0.76 (0.63-0.92) in cohort studies
RR: 0.75 (0.68-0.83) in case-control studies		Huang et al. 170
Pancreatic cancer1 prospective cohort and 13 case-control studiesOR: 0.52 (0.43-0.63)OR: 1.01 (0.59-1.73)  in the cohort study
OR: 0.54 (0.44-0.67) in case-control studies		Wang et al. ** 171
1 prospective cohort and 13 case-control studiesOR: 0.52 (0.44-0.61)OR: 0.66 (0.51-0.80) in studies reporting on soluble fiber
OR: 0.65 (0.44-0.87) in studies reporting on insoluble fiber		Mao et al. (2017)** 171
Prostate cancer5 prospective cohort and 12 case-control studiesOR: 0.89 (0.77-1.01)OR: 0.94 (0.77-1.11) in cohort studies
OR: 0.82 (0.68-0.96) in case-control studies
OR: 0.92 (0.81-1.03) in studies reporting on fruit fiber
OR: 0.87 (0.53-1.21) in studies reporting on vegetable fiber
OR: 1.05 (0.94-1.16) in studies reporting on cereal fiber
OR: 0.87 (0.52-1.22) in studies reporting on soluble fiber
OR: 0.80 (0.46-1.13) in studies reporting on insoluble fiber		Sheng et al. 172
5 prospective cohort and 11 case-control studiesRR: 0.94 (0.85-1.05)OR: 0.99 (0.87-1.14) in cohort studies
OR: 0.89 (0.75-1.06) in case-control studies		Wang et al. 173
Renal cell carcinoma2 prospective cohort and 4 case-control studiesRR: 0.84 (0.74-0.96)OR: 0.88 (0.69-1.12) in cohort studies
OR: 0.82 (0.68-1.00) in case-control studies
OR: 0.92 (0.80-1.05) in studies reporting on fruit fiber
OR: 0.70 (0.49-1.00) in studies reporting on vegetable fiber
OR: 1.04 (0.91-1.18) in studies reporting on cereal fiber
OR: 0.83 (0.70-0.97) in studies reporting on soluble fiber
OR: 0.81 (0.69-0.94) in studies reporting on insoluble fiber		Huang et al. 174

Footnotes:

* for the highest versus lowest level of fiber intake (unless otherwise specified)
** both meta-analyses identified the same 14 observational studies

Risk Ratio (RR) also called relative risk = Risk Ratio or Relative Risk is a ratio of the probability of an event occurring in the exposed group versus the probability of the event occurring in the non-exposed group.

Relative Risk = (Probability of event in exposed group) / (Probability of event in not exposed group) 175

In cancer research, risk ratios (relative risks) are used in prospective (forward looking) studies, such as cohort studies and clinical trials. A risk ratio (relative risk) of 1 means the risk is comparable in the two groups and there is no difference between two groups in terms of their risk of cancer, based on whether or not they were exposed to a certain substance or factor, or how they responded to two treatments being compared. A risk ratio (relative risk) of greater than one (RR>1) or of less than one (RR<1) usually means that being exposed to a certain substance or factor either increases (risk ratio greater than one) or decreases (risk ratio less than one) the risk of cancer, or that the treatments being compared do not have the same effects 175.

Odds Ratio (OR) is used to compare the relative odds of the occurrence of the outcome of interest (e.g. cancer), given exposure to the variable of interest (e.g. dietary fiber). The odds ratio can also be used to determine whether a particular exposure is a risk factor for a particular outcome, and to compare the magnitude of various risk factors for that outcome.

  • OR=1 Exposure does not affect odds of outcome
  • OR>1 Exposure associated with higher odds of outcome
  • OR<1 Exposure associated with lower odds of outcome

Colorectal cancer

Three most recent meta-analyses of observational studies have reported evidence of an inverse association between fiber intake and risk of colorectal cancer (see Table 2) 162, 164, 163. A recent review that included earlier meta-analyses reached a similar conclusion 176.

Several mechanisms have been proposed to explain why consuming fiber can have a protective effect against colorectal cancer. First, the presence of insoluble, coarse fiber can increase stool bulk thereby promoting the fecal excretion of carcinogens like nitrosamines 177. Fiber can also reduce exposure of the gut mucosa to carcinogens by shortening transit time 177. Secondly, fiber consumption influences the composition of the gut microbiota. Test tube studies have shown inulin to selectively stimulate the proliferation of beneficial bacteria while limiting the growth of potentially pathogenic bacteria 47. Gut bacterial imbalance (dysbiosis) has been associated with the incidence of several conditions, including colorectal cancer 178. The major health benefits conferred by the consumption of fiber are likely mediated by the bacteria the fiber contributes to feed. Depending on the physicochemical characteristics of fiber, some fiber, like inulin, can be fermented by colonic bacteria and lead to the formation of short-chain fatty acids, namely acetate, propionate, and butyrate. These short-chain fatty acids have been found to protect against gastrointestinal bacterial pathogens 179 and to display anti-inflammatory and anti-carcinogenic actions 180, 181.

A few controlled clinical trials have examined the effect of fiber consumption on the recurrence of colorectal adenomas (precancerous polyps), but none have been conducted in the last two decades. These trials examined the effect of wheat bran fiber 182, 183, 184, 185, 186, psyllium 187 and a high-fiber diet 188 on the risk of adenomas in participants with a history of adenomas. A 2017 meta-analysis of these trials found no difference between intervention and control groups in the number of participants with at least one new adenomatous polyp during the follow-up period (2-8 years), regardless of the type of fiber intervention 189.

Breast cancer

A review of four meta-analyses of observational studies reported substantial evidence of an inverse association between dietary fiber intake and breast cancer risk 176. The two most recent meta-analyses of prospective cohort studies found dietary fiber intake to be associated with a 7%-9% lower risk of breast cancer (Table 2) 160, 161. Prolonged exposure to estrogens has been associated with an increased risk of breast cancer 190. Several mechanisms might support the potential protective effect of dietary fiber against cancer, including breast cancer. The results of small, short-term intervention trials in premenopausal and postmenopausal women suggested that a low-fat (10-25% of total energy), high-fiber (25-40 g/day) diet could decrease circulating estrogen concentrations by increasing the excretion of estrogens and by promoting the metabolism of estrogens to less estrogenic forms 191, 192. Estrogens are conjugated in the liver and excreted within the bile into the gastrointestinal lumen; they are then de-conjugated by bacterial β-glucuronidase, re-absorbed as free estrogens through the enterohepatic circulation, and delivered to different organs and tissues like the breast.

Dietary fiber might interfere with estrogen reabsorption by reducing beta-glucoronidase activity 193. Alterations in gut bacteria composition have also been reported in women with breast cancer and might contribute to increased estrogen metabolism and absorption, resulting in higher circulating estrogen concentrations 194. However, it is not known whether fiber-associated effects on endogenous estrogen concentrations have a clinically significant impact on breast cancer risk 13. Finally, a healthy microbiota might also promote the degradation of plant-derived molecules other than fiber, such as lignans, which are precursors of metabolites with anti-estrogenic activities 195.

Other cancers

A review of the most recent meta-analyses of observational studies suggests that dietary fiber consumption is inversely associated with the risk of cancer of the esophagus 166, 167, stomach 168, pancreas 196, 171, and ovaries (see Table 2) 169, 170. The evidence linking fiber intake and esophageal cancer was exclusively based on observations from case-control studies, and for the other cancer sites, the evidence is primarily derived from case-control studies (Table 2). It is important to note that the evidence of an inverse association between fiber intake and risk of ovarian cancer (2 meta-analyses) was observed in case-control but not in prospective cohort studies (Table 2). Additionally, there was no evidence of an association between fiber intake and risk of endometrial cancer (1 meta-analysis) 165, prostate cancer (2 meta-analyses) 172, 173, or renal cell carcinoma (1 meta-analysis) 174. At present, evidence from randomized controlled trials of a causal relationship between fiber intake and risk of any cancer is lacking.

A recent study in a mouse model presenting a dysbiotic microbiota characterized by an increase in fiber-fermenting bacteria showed that the consumption of an obesogenic, high-fat diet enriched with soluble fiber could cause icteric hepatocarcinoma 197. Such findings suggest that a prolonged consumption of fermentable fiber may have detrimental consequences in contexts of dysbiosis. No such observations were found when insoluble fiber were substituted for soluble fiber 197.

Dietary fiber for weight loss

It has been suggested that higher fiber intakes could help maintain weight or promote weight loss by increasing satiation (causing meal termination) and/or extending the feeling of fullness after a meal (satiety) 198. Several mechanisms have been proposed to explain the potential satiating effect of fibers and the subsequent reduction in food intake. The presence of fiber in food may indirectly stimulate the production of hormones involved in the regulation of appetite in particular through (i) increasing the processing time in the mouth due to increased efforts required to masticate large particles containing fibers, and/or (ii) increasing the duration of stomach distention due to a lower rate of gastric emptying, and/or (iii) increasing the colonic production of short-chain fatty acids that can bind to receptors present on gut endocrine cells 199. Fiber-enriched meals decrease the hunger hormone ghrelin and increase the satiety hormone peptide YY 200. This finding suggests that fiber-rich meals might reduce appetite and increase satiety, although the data are inconsistent. Adverse effects like gas production and bloating observed with the supplementation of isolated fibers (e.g., wheat dextrin) might also reduce hunger and increase satiety.

Solah and colleagues 198 performed a three-arm, parallel, blind, randomized controlled trial with either 4.5 g of PolyGlycopleX (PGX) as softgel, 5 g PGX as granules or 5 g of rice flour as a control. Compared with the rice flour control, in the PGX granules group, there was a significant reduction in waist circumference (−2.5 cm), body weight (−1.4 kg), Body Mass Index (BMI) (−0.5 kg/m²) and number of eating occasions and intake of grain food 198. However, in other studies, the effects of fiber consumption on weight loss and changes in anthropometric markers were, at best, minor, or no significant and clinically relevant effects were observed 201, 202.

A 2013 review of 44 randomized controlled trials found that beta-glucans from oat or barley, lupin kernel fiber, whole grain rye, rye bran, and a mixed high-fiber diet could enhance satiety, whereas psyllium, whole grain barley, whole grain buckwheat, resistant starch, and wheat bran had no benefit or even reduced measures of the feeling of fullness after a meal (satiety) 203. However, for many types of fiber examined, results from interventions were mixed, some showing a positive effect on satiety, and others showing no effect. Additionally, there seemed to be no relationship between the physicochemical properties of fiber (i.e., solubility, viscosity, fermentability) and evidence of efficacy. For example, among soluble viscous fibers, beta-glucans appeared to enhance satiety, but pectin or psyllium did not. Similarly, among fermentable fibers, beta-glucans enhanced satiety, but guar gum, inulin, fructooligosaccharides, and resistant starch did not. Finally, a positive effect of fiber on satiety was not consistently associated with a reduction in food intake 203.

To explore further the association of dietary fiber intake in the form of legume consumption (e.g., beans, lentils, and peas) on body weight and composition, Kim and colleagues reported on a systematic review and meta-analysis of 21 randomised controlled trials including 940 participants 204. Pooled data showed an overall significant reduction in body weight of −0.34 kg for diets containing dietary legumes versus diets without pulse intervention (median duration of 6 weeks). Data from six of the trials also suggested an association of dietary legume consumption with reduced body fat percentage 204. In a separate systematic review and meta-analysis of the literature on the effects of viscous fiber ingestion on body weight and composition from 62 trials and 3877 participants, there was a similar significant association with weight loss of −0.33 kg 205. In the ‘Preventing Overweight Using Novel Dietary Strategies’ (POUNDS Lost) study, in 345 participants who consumed a calorie-restricted diet (−750 kcal per day) for 6 months, the most successful predictor of reduction in body weight from a variety of anthropometric and dietary factors was intake of dietary fiber 206. Furthermore, dietary fiber was also strongly associated with adherence to the macronutrient prescriptions within the calorie-restricted diets 206.

A 2011 systematic review of 61 randomized controlled studies examined the effect of different fiber types on body weight 207. This analysis found that dextrins and marine polysaccharides reduced body weight in all the studies, while chitosan, arabinoxylans, and fructans reduced body weight in at least two-thirds of the studies. Average weight reductions were greatest for the fructans and marine polysaccharides groups (~1.3 kg or 2.8 lb/4 weeks for a 79 kg person in both groups). For all fiber types combined, however, the average weight reduction was only 0.3 kg (0.7 lb) per 4 weeks for a 79-kg person 207.

Based on current published evidence, dietary fiber appears to associate only with small improvements in body weight, and evidence for changes in body composition (including fat mass) is less clear 20. The association of dietary fiber intake with only small improvements in body weight suggests that dietary fiber per se, is not a realistic solution for effective weight reduction. More research needs to be conducted in order to clarify which types of fiber might play a role in appetite regulation and weight management 199. Future studies should also focus on the longer-term benefits of dietary fiber on weight loss and maintenance of body weight.

Psyllium

Psyllium seed is a soluble fiber supplement derived from the husk of Plantago psyllium. Psyllium is purported to promote weight loss by acting as a bulking agent in the gut, which results in delayed gastric emptying and increased satiety. A few randomized controlled trials in overweight or obese subjects suggested that psyllium supplementation may influence body composition and/or promote weight loss 208. A study in overweight and obese individuals noted a dose-response relationship with psyllium supplementation, with a dose greater than 30 g of fiber per day leading to the most robust weight loss effect compared to a placebo 209. In one randomized, placebo-controlled trial in 159 Australian with body mass indices (BMI) ≥25 kg/m², psyllium (5 g/day) reduced waist circumference, waist-to-hip ratio, and body fat percentage, and increased the percentage of lean mass after 3, 6, and 12 months 210. Psyllium appeared to transiently reduce body weight at 3 and 6 months, yet there was no difference in body weight between psyllium and placebo at the end of the intervention (12 months) 210.

Many human studies show no improvement in body weight and composition after psyllium consumption. One early study of psyllium supplementation showed improved glucose and lipid control compared to placebo in 125 overweight patients with type 2 diabetes, although no weight loss occurred 211. Recent studies have demonstrated similar results with improved metabolic parameters without statistically significant weight reduction. A more recent trial in patients with type 2 diabetes supported these positive findings, demonstrating that 10.5 g of psyllium supplementation daily for eight weeks was associated with a significant reduction in body weight, waist circumference, and hip circumference 212.

Psyllium is less readily fermented and does not cause as much flatulence and abdominal distension as other fiber supplements. Still, the most commonly reported side effects are gastrointestinal, including flatulence, abdominal pain, diarrhea, constipation, and nausea. Generally, psyllium is well tolerated for short-term use without serious adverse effects 213.

Beta-glucans

Beta-glucans are glucose polymers (glucose polysaccharides) with a mixture of beta-1,4 glycosidic bonds and beta-1,3 glycosidic bonds. Beta-glucans are soluble fibers found in bacteria, yeast, fungi, and grains such as oat bran and barley are particularly rich in beta-glucans 41, 40. Weight loss effects may be due to increased satiety and decreased food intake 41. A meta-analysis published in 2019 showed that most trials reported non-significant or no weight loss from beta-glucans administered at a dose of three to ten grams per day for four to twelve weeks 214. Data does not currently support the use of beta-glucans for the treatment of obesity. Adverse effects include increased flatulence 215.

Glucomannan

Glucomannan is a soluble fiber commonly derived from the Amorphophallus konjac root. Glucomannan is a hemicellulose containing about 60% of mannose and 40% of glucose bonded together by beta-1,4 glycosidic linkages. Because human salivary and pancreatic amylase cannot split beta-1,4 glycosidic linkages, glucomannan passes relatively unchanged into the colon, where the gut microbiota ferment it 216. While glucomannan may be an ingredient in weight-loss products, it is more commonly used to treat constipation or elevated glucose and cholesterol. Glucomannan reportedly promotes satiety, slows gastrointestinal transit, and reduces fat and protein absorption through fecal loss. In animal studies, glucomannan suppressed cholesterol synthesis in the liver and increased the fecal excretion of bile acids and cholesterol 217. In a 2008 systematic review and meta-analysis, glucomannan significantly lowered total cholesterol, low-density lipoprotein (LDL or “bad”) cholesterol, triglycerides, body weight, and fasting blood glucose. This led to a statistically significant, although unlikely clinically significant weight loss of 0.79 kg 218.However, 2 recent reviews showed no statistically significant change in body weight compared to a placebo, contradicting the earlier meta-analysis.

Glucomannan appears to be well tolerated for short-term use. Minor adverse gastrointestinal effects include belching, bloating, frequent loose stools, flatulence, constipation, and abdominal discomfort 219. There have been reports of esophageal obstruction following the consumption of glucomannan-containing compounds, specifically with the tablet formulation and in patients with esophageal pathology. The capsule form of glucomannan supplement has not been associated with this effect 220.

Guar Gum

Guar Gum is a soluble fiber supplement derived from the Indian bean Cyamopsis tetragonolobus and is generally found in food products as a thickening agent. Guar gum is purported to promote weight loss by acting as a bulking agent in the gut, which results in delayed gastric emptying and increased satiety. Several studies have evaluated the effect of guar gum on weight reduction. A meta-analysis of 11 randomized, double-blind, placebo-controlled clinical trials of guar gum at dosages of nine to thirty grams daily for three weeks to six months found no significant difference in weight loss compared to placebo 221. More recently, a clinical trial in 44 patients with type 2 diabetes evaluated the effects of ten grams per day of guar gum on metabolic syndrome parameters and found a significant reduction in waist circumference but no effect on weight loss 222.

Reported guar gum adverse effects include gastrointestinal complaints, such as abdominal pain, flatulence, diarrhea, nausea, and cramps. More research is needed to support the use of guar gum as a weight-loss supplement.

Chitosan

Chitosan is an indigestible glucosamine polymer derived from chitin. Chitosan is available as a dietary supplement without a prescription in the US, being marketed to promote weight loss and lower cholesterol. A 2018 meta-analysis of randomized controlled, clinical trials found a lowering of total and LDL-cholesterol concentrations with chitosan supplementation (0.3-6.75 g/day for 4-24 weeks) and no effect on HDL-cholesterol or triglycerides 223. Another recent pooled analysis of trials found chitosan to be more effective than placebo in promoting weight loss 224.

Irvingia Gabonensis

Irvingia gabonensis also known as African mango is a fruit native to Africa and commonly consumed in African cuisine 225. The plant has many advantageous properties, including high fiber content and anti-diabetic and anti-lipidemic effects. Several studies have examined different formulations of Irvingia gabonensis (African mango) on weight and found beneficial results. A 2013 systematic review of the efficacy of Irvingia gabonensis (African mango) for weight management reported significant reductions in body weight, waist circumference, and total cholesterol 226. An article published in 2018 studied the effect of 150 mg (milligrams) of Irvingia gabonensis (African mango) taken twice a day over 90 days and found improved and statistically significant differences in waist circumference, serum glucose, and triglycerides 227. While multiple studies have reported beneficial results on metabolic disease markers, small sample sizes and mixed methods make it difficult to extrapolate a true clinical benefit. Overall, Irvingia gabonensis (African mango) appears to be safe and well-tolerated. The most common side effects include headache, flatulence, and difficulty sleeping 228, 229. Further studies are needed to determine efficacy, dosing, and safety.

Chronic Inflammation

It has been hypothesized that low intake of dietary fiber is a risk factor for both local and systemic chronic inflammation 230, 231. The current belief suggests that limited dietary fiber intake hampers the establishment and maintenance of a healthy, viable and diverse colonic microbiota that, in turn, limits the local production of short-chain fatty acids (SCFAs), including butyrate. Signalling pathways that implicate nuclear factor kappa-B (NF-ĸB) and inhibition of deacetylase influence inflammatory processes both locally including gut-wall leakiness and colonic inflammation in patients with inflammatory bowel disease and systemically 232 and both are likely influenced by levels of butyrate within the colon 230. Furthermore, butyrate may improve oxidative stress within the colon through effects on gene expression implicated in glutathione and uric acid metabolism 233.

In support of a role for dietary fiber in influencing inflammatory pathways, Miller and colleagues 234 reported a cross-sectional study on >140 overweight Hispanic and African-American adolescents. This study revealed that the highest consumption of dietary fiber intake compared with the lowest dietary fiber intake had significantly lower plasma markers of inflammatory status, including 36% and 43% lower levels of plasminogen activator inhibitor-1 (PAI-1) and resistin, respectively, with similar data for insoluble fiber 234. In a much larger study from the UK, Gibson and colleagues 235 reported on data from the Airwave Health Monitoring Study, a cross-sectional analysis on 6898 participants with 7-day food records. Data from this study revealed a significant inverse linear trend across fifths of total fiber intake and consumption of fiber from fruit with C-reactive protein (CRP, a plasma measure of general inflammatory status) and BMI, percentage body fat and waist circumference 235. In this study, given the association of dietary fiber intake with body fat percentage, it is possible that the favorable effects of dietary fiber on inflammatory status (indicated by plasma level of CRP) are actually mediated, at least in part, by changes in body composition rather than a direct effect of dietary fiber 235. In a further study, Kabisch and colleagues 236 demonstrated an interventional interaction effect of dietary fiber supplementation on inflammation. Interestingly, whilst the effect size for the anti-hyperglycaemic properties of insoluble dietary fiber seemed to depend mainly on the prevailing metabolic state, the anti-inflammatory effect of the particular supplement used in this study related primarily to the presence or absence of obesity 236.

Given the likely effects of dietary fiber on colonic microbiota diversity and production of short-chain fatty acids (SCFAs) and the known effects of butyrate in the mediation of inflammatory pathways, it is entirely plausible, and that dietary fiber does have at least some influence on inflammatory status both within the colon and systemically 20. The mechanisms implicated should form a focus for future research. Given the multiple possible beneficial effects of dietary fiber and the complexity of the implicated mechanisms including involvement of the colonic microflora, identifying the actual mechanisms that mediate the anti-inflammatory effects of dietary fiber will likely be challenging and necessitate a variety of approaches, including prospectively designed Randomized Controlled Trials (RCTs) and rodent-based mechanistic studies 20.

Depression

Large cohort studies have demonstrated that high diet quality and healthy dietary patterns are associated with reduced symptoms of depression 237, 238. More recently, adequate dietary fiber intake (often a hallmark of diet quality) has also emerged as an important factor in supporting mental well-being by lowering odds of developing depression 239. Although the underlying mechanisms remain incompletely understood, it has been hypothesised that inflammation may mediate the link between dietary fiber and depression, and that the association between a high-fiber diet and a reduction in inflammatory compounds may alter the concentrations of certain neurotransmitters that, in turn, could reduce the risk for the development of depression 240. Consistent with a role for the gut microbiota in the mediation of fiber-effects on mental health, a meta-analysis of controlled clinical trials showed a small but significant effect of probiotics on depression and anxiety 241. Furthermore, proof of the concept that a healthy diet improves depressive symptoms was provided in the SMILES trial 242, in which a modified Mediterranean diet with nutrition counselling sessions in adult patients with poor quality diets and major depressive disorders was shown to associate with improvements in depressive symptoms compared with the control group. Given the association of poor diet and obesity with depression and other mental health problems, it is important for future studies to provide insights into the mechanisms linking diet including dietary fiber with mental health 20. Future guidance on the prevention and management of depression and other mental health disorders may also include a high-fiber diet as an important factor to consider 20.

Good sources of dietary fiber

Whole grains and beans tend to be higher in fiber than fruits and vegetables, but these foods are good natural sources of dietary fiber and contribute other important nutrients. Make sure you include a variety of these foods regularly to meet your dietary fiber needs. Eating the skin or peel of fruits and vegetables provides a greater dose of fiber. Fiber is also found in beans and lentils, whole grains, nuts and seeds. Typically, the more refined or processed a food is, the lower its fiber content. For example, one medium apple with the peel contains 4.4 grams of fiber, while ½ cup of applesauce contains 1.4 grams, and 4 ounces of apple juice contains no fiber. By including certain foods, you can increase your fiber intake.

Here are a few foods that are naturally high in fiber:

  • Beans, peas, and lentils
  • Fruits
  • Nuts
  • Seeds
  • Vegetables
  • Wheat bran
  • Whole grains (such as whole oats, brown rice, popcorn, and quinoa) and foods made with whole grain ingredients (such as some breads, cereals, crackers, and pasta).

Table 3. High fiber foods

FOOD bcPORTION dCALORIESFIBER (g)
GRAINS
Ready-to-eat cereal, high fiber, unsweetened (e.g., bran)1/2 cup6214
Ready-to-eat cereal, whole grain kernels1/2 cup2097.5
Ready-to-eat cereal, wheat, shredded1 cup1726.2
Popcorn3 cups1695.8
Ready-to-eat cereal, bran flakes3/4 cup985.5
Bulgur, cooked1/2 cup764.1
Spelt, cooked1/2 cup1233.8
Teff, cooked1/2 cup1283.6
Barley, pearled, cooked1/2 cup973
Ready-to-eat cereal, toasted oat1 cup1113
Oat bran1/2 cup442.9
Crackers, whole wheat1 ounce1222.9
Chapati or roti, whole wheat1 ounce852.8
Tortillas, whole wheat1 ounce882.8
VEGETABLES
Lima beans (white), cooked*1 cup21613.2
Artichoke, cooked1 cup899.6
Navy beans, cooked*1/2 cup1289.6
Small white beans, cooked*1/2 cup1279.3
Yellow beans, cooked*1/2 cup1289.2
Green peas, cooked1 cup1348.8
Adzuki beans, cooked*1/2 cup1478.4
French beans, cooked*1/2 cup1148.3
Split peas, cooked*1/2 cup1168.2
Breadfruit, cooked1 cup1708
Lentils, cooked*1/2 cup1157.8
Lupini beans, cooked*1/2 cup1157.8
Mung beans, cooked*1/2 cup1067.7
Black turtle beans, cooked*1/2 cup1207.7
Pinto beans, cooked*1/2 cup1237.7
Cranberry (roman) beans, cooked*1/2 cup1217.6
Black beans, cooked*1/2 cup1147.5
Fufu, cooked1 cup3987.4
Pumpkin, canned1 cup837.1
Taro root (dasheen or yautia), cooked1 cup1876.7
Brussels sprouts, cooked1 cup656.4
Chickpeas (garbanzo beans), cooked*1/2 cup1356.3
Sweet potato, cooked1 cup1906.3
Great northern beans, cooked*1/2 cup1056.2
Parsnips, cooked1 cup1106.2
Nettles, cooked1 cup376.1
Jicama, raw1 cup465.9
Winter squash, cooked1 cup765.7
Pigeon peas, cooked*1/2 cup1025.7
Kidney beans, cooked*1/2 cup1135.7
White beans, cooked*1/2 cup1255.7
Black-eyed peas, dried and cooked*1/2 cup995.6
Cowpeas, dried and cooked*1/2 cup995.6
Yam, cooked1 cup1585.3
Broccoli, cooked1 cup545.2
Tree fern, cooked1 cup565.2
Luffa gourd, cooked1 cup1005.2
Soybeans, cooked*1/2 cup1485.2
Turnip greens, cooked1 cup295
Drumstick pods (moringa), cooked1 cup425
Avocado1/2 cup1205
Cauliflower, cooked1 cup344.9
Kohlrabi, raw1 cup364.9
Carrots, cooked1 cup544.8
Collard greens, cooked1 cup634.8
Kale, cooked1 cup434.7
Fava beans, cooked*1/2 cup944.6
Chayote (mirliton), cooked1 cup384.5
Snow peas, cooked1 cup674.5
Pink beans, cooked*1/2 cup1264.5
Spinach, cooked1 cup414.3
Escarole, cooked1 cup224.2
Beet greens, cooked1 cup394.2
Salsify, cooked1 cup924.2
Cabbage, savoy, cooked1 cup354.1
Cabbage, red, cooked1 cup414.1
Wax beans, snap, cooked1 cup444.1
Edamame, cooked*1/2 cup944.1
Okra, cooked1 cup364
Green beans, snap, cooked1 cup444
Hominy, canned1 cup1154
Corn, cooked1 cup1344
Potato, baked, with skin1 medium1613.9
Lambsquarters, cooked1 cup583.8
Lotus root, cooked1 cup1083.8
Swiss chard, cooked1 cup353.7
Mustard spinach, cooked1 cup293.6
Carrots, raw1 cup523.6
Hearts of palm, canned1 cup413.5
Mushrooms, cooked1 cup443.4
Bamboo shoots, raw1 cup413.3
Yardlong beans, cooked*1/2 cup1013.3
Turnip, cooked1 cup343.1
Red bell pepper, raw1 cup393.1
Rutabaga, cooked1 cup513.1
Plantains, cooked1 cup2153.1
Nopales, cooked1 cup223
Dandelion greens, cooked1 cup353
Cassava (yuca), cooked1 cup2673
Asparagus, cooked1 cup322.9
Taro leaves, cooked1 cup352.9
Onions, cooked1 cup922.9
Cabbage, cooked1 cup342.8
Mustard greens, cooked1 cup362.8
Beets, cooked1 cup492.8
Celeriac, raw1 cup662.8
FRUITS
Sapote or Sapodilla1 cup2179.5
Guava1 cup1128.9
Nance1 cup828.4
Raspberries1 cup648
Loganberries1 cup817.8
Blackberries1 cup627.6
Soursop1 cup1487.4
Boysenberries1 cup667
Gooseberries1 cup666.5
Pear, Asian1 medium756.5
Blueberries, wild1 cup806.2
Passion fruit1/4 cup576.1
Persimmon1 fruit1186
Pear1 medium1035.5
Kiwifruit1 cup1105.4
Grapefruit1 fruit1305
Apple, with skin1 medium1044.8
Cherimoya1 cup1204.8
Durian1/2 cup1794.6
Starfruit1 cup413.7
Orange1 medium733.7
Figs, dried1/4 cup933.7
Blueberries1 cup843.6
Pomegranate seeds1/2 cup723.5
Mandarin orange1 cup1033.5
Tangerine (tangelo)1 cup1033.5
Pears, dried1/4 cup1183.4
Peaches, dried1/4 cup963.3
Banana1 medium1123.2
Apricots1 cup743.1
Prunes or dried plum1/4 cup1053.1
Strawberries1 cup493
Dates1/4 cup1043
Blueberries, dried1/4 cup1273
Cherries1 cup872.9
PROTEIN FOODS
Wocas, yellow pond lily seeds1 ounce1025.4
Pumpkin seeds, whole1 ounce1265.2
Chia seeds1 Tbsp584.1
Almonds1 ounce1643.5
Chestnuts1 ounce1063.3
Sunflower seeds1 ounce1653.1
Pine nuts1 ounce1783
Pistachio nuts1 ounce1622.9
Flax seeds1 Tbsp552.8
Hazelnuts (filberts)1 ounce1782.8
Other Sources
Coconut1 ounce1874.6

Footnotes:

* Beans, peas, and lentils are listed under Vegetables but can also be counted in the Protein Foods group.

a All foods listed are assumed to be in nutrient-dense forms; lean or low-fat and prepared with minimal or no added sugars, saturated fat, and sodium.

b Some fortified foods and beverages are included. Other fortified options may exist on the market, but not all fortified foods are nutrient-dense. For example, some foods with added sugars may be fortified and would not be examples in the lists provided here.

c Some foods or beverages are not appropriate for all ages, (e.g., nuts, popcorn), particularly young children for whom some foods could be a choking hazard

d This list includes “Standard” portions, which provide at least 2.8 g of dietary fiber. Portions listed are not necessarily recommended serving sizes.

[Source 243 ]

Fiber Intake Recommendations

The Adequate Intake recommendations for total fiber intake, set by the Food and Nutrition Board of the Institute of Medicine, are based on the findings of several large prospective cohort studies that dietary fiber intakes of approximately 14 g for every 1,000 calories (kcal) consumed were associated with significant reductions in the risk of coronary heart disease (coronary artery disease). Total fiber is defined by the Institute of Medicine as “the sum of dietary fiber and functional fiber” 2. For adults who are 50 years of age and younger, the Adequate Intake recommendation for total fiber intake is 38 g/day for men and 25 g/day for women. For adults over 50 years of age, the recommendation is 30 g/day for men and 21 g/day for women. The Adequate Intake recommendations for males and females of all ages are presented in Table 4 below.

Table 4. Fiber Intake Recommendations (Adequate Intake for Total Fiber)

Life StageAgeMales (g/day)Females (g/day)
Infants0-6 months ND*ND
Infants7-12 months NDND
Children1-3 years 1919
Children4-8 years 2525
Children9-13 years 3126
Adolescents14-18 years 3826
Adults19-50 years 3825
Adults51 years and older  3021
Pregnancyall ages –28
Breast-feedingall ages –29

Footnote: *ND = Not determined

[Source 2 ]

Fiber supplements

Fiber supplements are man-made (synthetic) or isolated fiber and do not provide many of the health benefits associated with fiber-rich whole foods (eg, fruits, vegetables, legumes, whole grains) 1.

There are 4 main characteristics of fiber supplements that drive their health benefits 1:

  • Solubility. Solubility defines whether a fiber supplement will dissolve in water (soluble) or remain as discreet insoluble particles 14, 244. A fiber that is 70% soluble will be considered a soluble fiber
  • Degree or rate of fermentation. Fermentation refers to the rate and degree to which a dietary fiber, after resisting enzymatic digestion in the small bowel, can be degraded by gut bacteria, producing fermentation byproducts such as short chain fatty acids and gas 14
  • Viscosity. For soluble fibers, viscosity refers to the ability of some fibers to “thicken” when water is added, in a concentration-dependent manner 14, 245, 246, 244.
  • Gel formation. Gel formation refers to the ability of a subset of soluble viscous fibers to form cross-links, resulting in a viscoelastic gel when hydrated 14, 244.

Using the 4 fiber characteristics described above, fiber supplements can be divided into 4 clinically meaningful categories 1:

  • Insoluble, poorly fermented (e.g, wheat bran): when you think of “insoluble fiber”, think of plastic (clinical studies described later actually used plastic particles to mimic effects of wheat bran): does not dissolve in water (no water-holding capacity); poorly fermented; can exert a laxative effect by mechanical irritation/stimulation of gut mucosa if particles are sufficiently large and coarse (“plastic effect”); small smooth particles (eg, wheat bran flour/bread) have no significant laxative effect; insoluble fiber does not gel or alter viscosity and thus does not provide other (gel-dependent) fiber health benefits.
  • Soluble, nonviscous, readily fermented (e.g, inulin, wheat dextrin, oligosaccharides, resistant starches): dissolves in water; no increase in viscosity; rapidly and completely fermented (once fermented, the fiber is no longer present in stool, rapid gas formation, increased flatulence, energy harvest [calorie uptake] from fermentation by-products); may alter the numbers of specific bacteria in the gut (eg, “prebiotic” effect); no laxative effect at physiologic doses; does not gel or alter viscosity and thus does not provide any of the gel-dependent fiber health benefits. Readily fermented fibers are part of an emerging area of science relating to their effects on the gut microbiome, but to date, the marketed fiber supplements have no established clinically meaningful health benefits.
  • Soluble viscous or gel forming, readily fermented (e.g, beta-glucan [oats, barley], raw guar gum): dissolves in water, forms a viscous gel (eg, oatmeal), increases chyme viscosity to slow nutrient absorption and improve glycemic control, lowers elevated serum cholesterol, readily fermented (gas formation, energy harvest [calorie uptake] from fermentation by-products), fermentation results in loss of gel and water-holding capacity, and thus, no significant laxative effect and no retained gel to attenuate diarrhea.
  • Soluble viscous or gel forming, nonfermented (i.e, psyllium): dissolves in water; forms a viscous gel; increases chyme viscosity to slow nutrient absorption and improve glycemic control, lowers elevated serum cholesterol; not fermented (no gas production, no calorie harvest from fermentation by-products); because it is not fermented, it remains gelled throughout the large bowel, providing a dichotomous “stool-normalizing” effect: softens hard stool in constipation (relieves/prevents constipation) and firms/forms loose/liquid stool in diarrhea (relieves/prevents diarrhea), and normalizes stool form in irritable bowel syndrome (IBS).

Beta-glucans

Beta-glucans are viscous, easily fermented, soluble fibers found naturally in oats, barley, mushrooms, yeast, bacteria, and algae. Beta-glucans extracted from oats, mushrooms, and yeast are available in a variety of nutritional supplements without a prescription.

Glucomannan

Glucomannan also called konjac mannan is classified as a soluble fiber isolated from konjac flour, which is derived from the plant Amorphophallus konjac. Glucomannan is available as powder and in capsules, which should be taken with plenty of liquids 42. Glucomannan forms gels that are firmer than regular gelatin products (e.g., “jello”) and do no melt in the mouth. The FDA has banned gel candies containing glucomannan (e.g., “mini-cup jelly products”) because of their potential to cause choking 247.

Pectin

Pectins are readily fermented soluble viscous fibers, most often extracted from citrus peels and apple pulp. Pectins are widely used as gelling agents in food but are also available as dietary supplements without a prescription 42.

Inulins and oligofructose

Inulins and oligofructose, extracted from chicory root or synthesized from sucrose, are used as food additives 248. Isolated inulin is added to replace fat in products like salad dressing, while sweet-tasting oligofructose is added to products like fruit yogurts and desserts. Inulins and oligofructose are highly fermentable fibers that are also classified as prebiotics because of their ability to stimulate the growth of potentially beneficial Bifidobacteria species in the human colon 249. Encouraging the growth of Bifidobacteria might promote intestinal health by suppressing the growth of pathogenic bacteria known to cause diarrhea or by enhancing the immune response 250. Although a number of dietary supplements containing inulins and oligofructose are marketed as prebiotics, the health benefits of prebiotics have not yet been convincingly demonstrated in humans 251, 1.

Guar gum

Raw guar gum is a viscous, fermentable fiber derived from the Indian guar or cluster bean 2. Guar gum is used as a thickener or emulsifier in many food products. Dietary supplements containing guar gum have been marketed as weight-loss aids, but there is no evidence of their efficacy 221. Unlike guar gum, partially hydrolyzed guar gum is nonviscous and therefore does not exhibit the biological activities of guar gum (i.e., it has no effect on serum cholesterol and blood sugar control). Use of a guar gum-containing supplement for weight loss has been associated with esophageal and small bowel obstruction 252.

Psyllium

Psyllium, a viscous, soluble, gel-forming fiber isolated from psyllium seed husks, is available without a prescription in laxatives, ready-to-eat cereal, and dietary supplements 42. Psyllium is proven to be efficacious to lower serum cholesterol and improve blood sugar control. Because it also normalizes stool form, psyllium is the only fiber recommended by the American College of Gastroenterology to treat chronic constipation and irritable bowel syndrome (IBS). Several cases of intestinal obstruction by psyllium have been reported when taken with insufficient fluids or by people with impaired swallowing or gastrointestinal motility 253, 254. Anaphylaxis has also been reported after the ingestion of cereal containing psyllium, and asthma has occasionally been reported in people with occupational exposure to psyllium powder 255. One randomized controlled trial in patients with a history of colorectal adenomas (precancerous polyps) found that supplementation with 3.5 g/day of psyllium for three years resulted in a significant increase in colorectal adenoma recurrence compared to placebo 187.

Chitosan

Chitosan is an indigestible glucosamine polymer derived from chitin. Chitosan is available as a dietary supplement without a prescription in the US, being marketed to promote weight loss and lower cholesterol. A 2018 meta-analysis of randomized controlled, clinical trials found a lowering of total and LDL-cholesterol concentrations with chitosan supplementation (0.3-6.75 g/day for 4-24 weeks) and no effect on HDL-cholesterol or triglycerides 223. Another recent pooled analysis of trials found chitosan to be more effective than placebo in promoting weight loss 224.

Dietary fiber side effects

Eating a large amount of fiber in a short period of time can cause intestinal gas (flatulence), bloating, diarrhea and abdominal cramps. This problem often goes away once the natural bacteria in your digestive system get used to the increase in fiber. It is recommended to gradually introduce a new fiber supplement, not exceeding 3 to 4 g/day the first week, in order to minimize gastrointestinal symptoms 256. These symptoms can be minimized or avoided by increasing intake of fiber-rich foods gradually and increasing fluid intake to at least ~2 liters or 2 quarts/day. There have been rare reports of intestinal obstruction related to large intakes of oat bran or wheat bran, primarily in people with impaired intestinal motility or difficulty chewing 257, 258, 259, 260. Too much fiber may interfere with the absorption of minerals such as iron, zinc, magnesium, and calcium. In most cases, this is not a cause for too much concern because high-fiber foods tend to be rich in minerals. The National Academy of Medicine (the Institute of Medicine) has not established a tolerable upper intake level (UL) for dietary or functional fiber 2.

Gastrointestinal symptoms

The following dietary fibers have been found to cause gastrointestinal distress, including abdominal cramping, bloating, gas, and diarrhea: guar gum, inulin and oligofructose, fructooligosaccharides, polydextrose, resistant starch, and psyllium 2. It is recommended to gradually introduce a new fiber supplement, not exceeding 3 to 4 g/day the first week, in order to minimize gastrointestinal symptoms 256. In subjects who are constipated, the initiation of a fiber supplement should start once the hard stool is cleared 256. Use of a guar gum-containing supplement for weight loss has been associated with esophageal and small bowel obstruction 252. Additionally, several cases of intestinal obstruction by psyllium have been reported when taken with insufficient fluids or by people with impaired swallowing or gastrointestinal motility 253, 254.

Colorectal adenomas

One randomized controlled trial in patients with a history of colorectal adenomas (precancerous polyps) found that supplementation with 3.5 g/day of psyllium for three years resulted in a significant increase in colorectal adenoma recurrence compared to placebo 187.

Allergy and anaphylaxis

Since chitin is isolated from the exoskeletons of crustaceans, such as crabs and lobsters, and chitosan is derived from chitin, people with shellfish allergies should avoid taking chitosan supplements 42. Anaphylaxis has been reported after intravenous (IV) administration of inulin 261, as well as ingestion of margarine containing inulin extracted from chicory 262. Anaphylaxis has also been reported after the ingestion of cereal containing psyllium, and asthma has occasionally been reported in people with occupational exposure to psyllium powder 255.

Nutrient interactions

The addition of cereal fiber to meals has generally been found to decrease the absorption of iron, zinc, calcium, and magnesium in the same meal, but this effect appears to be related to the phytate present in the cereal fiber rather than the fiber itself 263. In general, dietary fiber as part of a balanced diet has not been found to adversely affect the calcium, magnesium, iron, or zinc status of healthy people at recommended intake levels 2. Evidence from animal studies and limited research in humans suggests that inulin and oligofructose may enhance calcium absorption 264, 265. The addition of pectin and guar gum to a meal significantly reduced the absorption of the carotenoids β-carotene, lycopene, and lutein from that meal 266, 267.

Drug interactions

Gel-forming fibers (e.g., beta-glucan, psyllium, raw guar gum, pectin) have the potential to slow the absorption of drugs if taken at the same time. Psyllium may reduce the absorption of lithium, carbamazepine (Tegretol), digoxin (Lanoxin), and warfarin (Coumadin) when taken at the same time 42. Guar gum may slow the absorption of digoxin, acetaminophen (Tylenol), and bumetanide (Bumex) and decrease the absorption of metformin (Glucophage), penicillin, and some formulations of glyburide (Glynase) when taken at the same time 268. Pectin may decrease the absorption of lovastatin (Mevacor) when taken at the same time 269. Concomitant administration of a kaolin-pectin antidiarrheal suspension has been reported to decrease the absorption of clindamycin, tetracycline, and digoxin, but it is not known whether kaolin, pectin, or both were responsible for the interaction 42. In general, medications should be taken at least one hour before or two hours after fiber supplements and gel-forming dietary fibers (e.g., oatmeal).

  1. McRorie JW Jr. Evidence-Based Approach to Fiber Supplements and Clinically Meaningful Health Benefits, Part 1: What to Look for and How to Recommend an Effective Fiber Therapy. Nutr Today. 2015 Mar;50(2):82-89. doi: 10.1097/NT.0000000000000082[][][][][][]
  2. Institute of Medicine. Dietary, functional, and total fiber. Dietary Reference Intakes for Energy, Carbohydrate, Fiber, Fat, Fatty Acids, Cholesterol, Protein, and Amino Acids. Washington, D. C.: The National Academies Press; 2002:265-334. https://nap.nationalacademies.org/read/10490/chapter/9[][][][][][][][][][][][][][][][][][][]
  3. Ha MA, Jarvis MC, Mann JI. A definition for dietary fibre. Eur J Clin Nutr. 2000 Dec;54(12):861-4. doi: 10.1038/sj.ejcn.1601109[]
  4. Baĭgarin EK, Zhminchenko VM. [Dietary fiber: terms and definition]. Vopr Pitan. 2007;76(4):10-4. Russian.[]
  5. DeVries JW. On defining dietary fibre. Proc Nutr Soc. 2003 Feb;62(1):37-43. doi: 10.1079/PNS2002234[]
  6. Stephen A.M., Champ M.M., Cloran S.J., Fleith M., van Lieshout L., Mejborn H., Burley V.J. Dietary fibre in Europe: Current state of knowledge on definitions, sources, recommendations, intakes and relationships to health. Nutr. Res. Rev. 2017;30:149–190. doi: 10.1017/S095442241700004X[][][][]
  7. EFSA NDA Panel (EFSA Panel on Dietetic Products, Nutrition, and Allergies). (2010a). Scientific opinion on the safety of chitin-glucan as a novel food ingredient. EFSA Journal, 8(7), 1687. https://doi.org/10.2903/j.efsa.2010.1687[][][]
  8. EFSA NDA Panel (EFSA Panel on Dietetic Products, Nutrition, and Allergies). (2010b). Scientific opinion on dietary reference values for carbohydrates and dietary fibre. EFSA Journal, 8(3), 1462. https://doi.org/10.2903/j.efsa.2010.1462[][][]
  9. Hijová E., Bertková I., Štofilová J. Dietary Fibre as Prebiotics in Nutrition. Cent. Eur. J. Public Health. 2019;27:251–255. doi: 10.21101/cejph.a5313[][]
  10. Alimentarius C. Guidelines on nutrition labelling CAC/GL 2-1985 as last amended 2010 . Joint FAO/WHO food standards programme, secretariat of the codex alimentarius commission. Rome: FAO, 2010[]
  11. Jones JM. CODEX-aligned dietary fiber definitions help to bridge the ‘fiber gap’. Nutr J. 2014 Apr 12;13:34. doi: 10.1186/1475-2891-13-34[][]
  12. Lupton JR. Microbial degradation products influence colon cancer risk: the butyrate controversy. J Nutr. 2004 Feb;134(2):479-82. doi: 10.1093/jn/134.2.479[][]
  13. Fiber. https://lpi.oregonstate.edu/mic/other-nutrients/fiber[][][]
  14. McRorie J, Fahey G. A review of gastrointestinal physiology and the mechanisms underlying the health benefits of dietary fiber: matching an effective fiber with specific patient needs. Clin Nurs Stud. 2013; 1( 4): 82– 92.[][][][][]
  15. Chutkan R, Fahey G, Wright WL, McRorie J. Viscous versus nonviscous soluble fiber supplements: mechanisms and evidence for fiber-specific health benefits. J Am Acad Nurse Pract. 2012 Aug;24(8):476-87. doi: 10.1111/j.1745-7599.2012.00758.x[]
  16. Klosterbuer A, Roughead ZF, Slavin J. Benefits of dietary fiber in clinical nutrition. Nutr Clin Pract. 2011 Oct;26(5):625-35. doi: 10.1177/0884533611416126[]
  17. Slavin JL. Position of the American Dietetic Association: health implications of dietary fiber. J Am Diet Assoc. 2008 Oct;108(10):1716-31. doi: 10.1016/j.jada.2008.08.007. Erratum in: J Am Diet Assoc. 2009 Feb;109(2):350.[]
  18. Trowell H. Dietary fibre, ischaemic heart disease and diabetes mellitus. Proceedings of the Nutrition Society. 1973;32(3):151-157. doi:10.1079/PNS19730033[][]
  19. Weickert M.O., Pfeiffer A.F. Metabolic effects of dietary fiber consumption and prevention of diabetes. J. Nutr. 2008;138:439–442. doi: 10.1093/jn/138.3.439[][][]
  20. Barber TM, Kabisch S, Pfeiffer AFH, Weickert MO. The Health Benefits of Dietary Fibre. Nutrients. 2020 Oct 21;12(10):3209. doi: 10.3390/nu12103209[][][][][][][][]
  21. Dietary Guidelines for Americans, 2020-2025. https://www.dietaryguidelines.gov/sites/default/files/2021-03/Dietary_Guidelines_for_Americans-2020-2025.pdf[][][]
  22. Thompson H.J. The Dietary Guidelines for Americans (2020–2025): Pulses, Dietary Fiber, and Chronic Disease Risk-A Call for Clarity and Action. Nutrients. 2021;13:4034. doi: 10.3390/nu13114034[]
  23. Reicks M, Jonnalagadda S, Albertson AM, Joshi N. Total dietary fiber intakes in the US population are related to whole grain consumption: results from the National Health and Nutrition Examination Survey 2009 to 2010. Nutr Res. 2014 Mar;34(3):226-34. doi: 10.1016/j.nutres.2014.01.002[][]
  24. Dietary Guidelines for Americans. https://www.dietaryguidelines.gov/[]
  25. Holscher H.D. Dietary fiber and prebiotics and the gastrointestinal microbiota. Gut Microbes. 2017;8:172–184. doi: 10.1080/19490976.2017.1290756[]
  26. Barber T.M., Kabisch S., Pfeiffer A.F.H., Weickert M.O. The Health Benefits of Dietary Fibre. Nutrients. 2020;12:3209. doi: 10.3390/nu12103209[]
  27. Dong J.L., Wang L., Lü J., Zhu Y.Y., Shen R.L. Structural, antioxidant and adsorption properties of dietary fiber from foxtail millet (Setaria italica) bran. J. Sci. Food Agric. 2019;99:3886–3894. doi: 10.1002/jsfa.9611[]
  28. Aleixandre A., Miguel M. Dietary fiber and blood pressure control. Food Funct. 2016;7:1864–1871. doi: 10.1039/C5FO00950B[]
  29. Post R.E., Mainous AG 3rd King D.E., Simpson K.N. Dietary fiber for the treatment of type 2 diabetes mellitus: A meta-analysis. J. Am. Board. Fam. Med. 2012;25:16–23. doi: 10.3122/jabfm.2012.01.110148[]
  30. Weickert M.O., Pfeiffer A.F. Impact of dietary fiber consumption on insulin resistance and the prevention of type 2 diabetes. J. Nutr. 2018;148:7–12. doi: 10.1093/jn/nxx008[]
  31. Weickert M.O., Pfeiffer A.F.H. Metabolic effects of dietary fiber consumption and prevention of diabetes. J. Nutr. 2008;138:439–442. doi: 10.1093/jn/138.3.439[]
  32. Nie Y., Luo F. Dietary Fiber: An Opportunity for a Global Control of Hyperlipidemia. Oxid. Med. Cell Longev. 2021;8:5542342. doi: 10.1155/2021/5542342[]
  33. Sun L., Zhang Z., Xu J., Xu G., Liu X. Dietary fiber intake reduces risk for Barrett’s esophagus and esophageal cancer. Crit. Rev. Food Sci. Nutr. 2017;57:2749–2757. doi: 10.1080/10408398.2015.1067596[]
  34. Tucker L.A. Dietary Fiber and Telomere Length in 5674 U.S. Adults: An NHANES Study of Biological Aging. Nutrients. 2018;10:400. doi: 10.3390/nu10040400[]
  35. Marlett JA. Content and composition of dietary fiber in 117 frequently consumed foods. J Am Diet Assoc. 1992 Feb;92(2):175-86.[][][]
  36. Dahl WJ, Stewart ML. Position of the Academy of Nutrition and Dietetics: Health Implications of Dietary Fiber. J Acad Nutr Diet. 2015 Nov;115(11):1861-70. doi: 10.1016/j.jand.2015.09.003[][]
  37. How to Get More Fiber in Your Diet. https://familydoctor.org/fiber-how-to-increase-the-amount-in-your-diet[]
  38. Questions and Answers on Dietary Fiber. https://www.fda.gov/food/food-labeling-nutrition/questions-and-answers-dietary-fiber[][]
  39. Lupton JR, Turner ND. Dietary fiber. In: Stipanuk MH, ed. Biochemical and Physiological Aspects of Human Nutrition. Philadelphia: W. B. Saunders; 2000:143-154.[][]
  40. Gallaher CM, Schneeman BO. Dietary fiber. In: Bowman BA, Russell RM, eds. Present Knowledge in Nutrition. 8th ed. Washington, D.C.: ILSI Press; 2001:83-91.[][][]
  41. Ríos-Hoyo A, Gutiérrez-Salmeán G. New Dietary Supplements for Obesity: What We Currently Know. Curr Obes Rep. 2016 Jun;5(2):262-70. doi: 10.1007/s13679-016-0214-y[][][]
  42. Hendler SS, Rorvik DR, eds. PDR for Nutritional Supplements. 2nd ed. Montvale: Physicians’ Desk Reference Inc.; 2008.[][][][][][][][]
  43. Niness KR. Inulin and oligofructose: what are they? J Nutr. 1999 Jul;129(7 Suppl):1402S-6S. doi: 10.1093/jn/129.7.1402S[][]
  44. Hahn T, Roth A, Febel E, Fijalkowska M, Schmitt E, Arsiwalla T, Zibek S. New methods for high-accuracy insect chitin measurement. J Sci Food Agric. 2018 Oct;98(13):5069-5073. doi: 10.1002/jsfa.9044[]
  45. Wilson B, Whelan K. Prebiotic inulin-type fructans and galacto-oligosaccharides: definition, specificity, function, and application in gastrointestinal disorders. J Gastroenterol Hepatol. 2017 Mar;32 Suppl 1:64-68. doi: 10.1111/jgh.13700[]
  46. Holscher HD. Dietary fiber and prebiotics and the gastrointestinal microbiota. Gut Microbes. 2017 Mar 4;8(2):172-184. doi: 10.1080/19490976.2017.1290756[][]
  47. Zeng H, Lazarova DL, Bordonaro M. Mechanisms linking dietary fiber, gut microbiota and colon cancer prevention. World J Gastrointest Oncol. 2014 Feb 15;6(2):41-51. doi: 10.4251/wjgo.v6.i2.41[][]
  48. Burkitt DP, Trowell HC. Dietary fibre and western diseases. Ir Med J. 1977 Jun 18;70(9):272-7.[]
  49. Mozaffarian D, Kumanyika SK, Lemaitre RN, Olson JL, Burke GL, Siscovick DS. Cereal, fruit, and vegetable fiber intake and the risk of cardiovascular disease in elderly individuals. JAMA. 2003 Apr 2;289(13):1659-66. doi: 10.1001/jama.289.13.1659[]
  50. Rimm EB, Ascherio A, Giovannucci E, Spiegelman D, Stampfer MJ, Willett WC. Vegetable, fruit, and cereal fiber intake and risk of coronary heart disease among men. JAMA. 1996 Feb 14;275(6):447-51. doi: 10.1001/jama.1996.03530300031036[][]
  51. van de Vijver LP, van den Bosch LM, van den Brandt PA, Goldbohm RA. Whole-grain consumption, dietary fibre intake and body mass index in the Netherlands cohort study. Eur J Clin Nutr. (2009) 63:31–8. 10.1038/sj.ejcn.1602895[]
  52. O’Neil CE, Zanovec M, Cho SS, Nicklas TA. Whole grain and fiber consumption are associated with lower body weight measures in US adults: National Health and Nutrition Examination Survey 1999–2004. Nutr Res. (2010) 30:815–22. 10.1016/j.nutres.2010.10.013[]
  53. McRorie JW Jr, McKeown NM. Understanding the Physics of Functional Fibers in the Gastrointestinal Tract: An Evidence-Based Approach to Resolving Enduring Misconceptions about Insoluble and Soluble Fiber. J Acad Nutr Diet. 2017 Feb;117(2):251-264. doi: 10.1016/j.jand.2016.09.021[][][][][][][][]
  54. Woo H.I., Kwak S.H., Lee Y., Choi J.H., Cho Y.M., Om A.S. A Controlled, Randomized, Double-blind Trial to Evaluate the Effect of Vegetables and Whole Grain Powder That Is Rich in Dietary Fibers on Bowel Functions and Defecation in Constipated Young Adults. J. Cancer Prev. 2015;20:64–69. doi: 10.15430/JCP.2015.20.1.64[]
  55. Rao S.S., Yu S., Fedewa A. Systematic review: Dietary fibre and FODMAP-restricted diet in the management of constipation and irritable bowel syndrome. Aliment. Pharmacol. Ther. 2015;41:1256–1270. doi: 10.1111/apt.13167[][][][]
  56. McRorie JW, Chey WD. Fermented Fiber Supplements Are No Better Than Placebo for a Laxative Effect. Dig Dis Sci. 2016 Nov;61(11):3140-3146. doi: 10.1007/s10620-016-4304-1[][][]
  57. Christodoulides S, Dimidi E, Fragkos KC, Farmer AD, Whelan K, Scott SM. Systematic review with meta-analysis: effect of fibre supplementation on chronic idiopathic constipation in adults. Aliment Pharmacol Ther. 2016 Jul;44(2):103-16. doi: 10.1111/apt.13662[]
  58. Prasad VG, Abraham P. Management of chronic constipation in patients with diabetes mellitus. Indian J Gastroenterol. 2017 Jan;36(1):11-22. doi: 10.1007/s12664-016-0724-2[]
  59. Dahl WJ, Mendoza DR. Is Fibre an Effective Strategy to Improve Laxation in Long-Term Care Residents? Can J Diet Pract Res. 2018 Mar 1;79(1):35-41. doi: 10.3148/cjdpr-2017-028[]
  60. Rungsiprakarn P, Laopaiboon M, Sangkomkamhang US, Lumbiganon P, Pratt JJ. Interventions for treating constipation in pregnancy. Cochrane Database Syst Rev. 2015 Sep 4;2015(9):CD011448. doi: 10.1002/14651858.CD011448.pub2[]
  61. Turawa EB, Musekiwa A, Rohwer AC. Interventions for treating postpartum constipation. Cochrane Database Syst Rev. 2014 Sep 23;2014(9):CD010273. doi: 10.1002/14651858.CD010273.pub2[]
  62. Bharucha AE, Pemberton JH, Locke GR 3rd. American Gastroenterological Association technical review on constipation. Gastroenterology. 2013 Jan;144(1):218-38. doi: 10.1053/j.gastro.2012.10.028[]
  63. Ford AC, Moayyedi P, Lacy BE, Lembo AJ, Saito YA, Schiller LR, Soffer EE, Spiegel BM, Quigley EM; Task Force on the Management of Functional Bowel Disorders. American College of Gastroenterology monograph on the management of irritable bowel syndrome and chronic idiopathic constipation. Am J Gastroenterol. 2014 Aug;109 Suppl 1:S2-26; quiz S27. doi: 10.1038/ajg.2014.187[][]
  64. Defrees DN, Bailey J. Irritable Bowel Syndrome: Epidemiology, Pathophysiology, Diagnosis, and Treatment. Prim Care. 2017 Dec;44(4):655-671. doi: 10.1016/j.pop.2017.07.009[]
  65. Varjú P, Farkas N, Hegyi P, Garami A, Szabó I, Illés A, Solymár M, Vincze Á, Balaskó M, Pár G, Bajor J, Szűcs Á, Huszár O, Pécsi D, Czimmer J. Low fermentable oligosaccharides, disaccharides, monosaccharides and polyols (FODMAP) diet improves symptoms in adults suffering from irritable bowel syndrome (IBS) compared to standard IBS diet: A meta-analysis of clinical studies. PLoS One. 2017 Aug 14;12(8):e0182942. doi: 10.1371/journal.pone.0182942[]
  66. Moayyedi P, Quigley EM, Lacy BE, Lembo AJ, Saito YA, Schiller LR, Soffer EE, Spiegel BM, Ford AC. The effect of fiber supplementation on irritable bowel syndrome: a systematic review and meta-analysis. Am J Gastroenterol. 2014 Sep;109(9):1367-74. doi: 10.1038/ajg.2014.195[]
  67. Nagarajan N, Morden A, Bischof D, King EA, Kosztowski M, Wick EC, Stein EM. The role of fiber supplementation in the treatment of irritable bowel syndrome: a systematic review and meta-analysis. Eur J Gastroenterol Hepatol. 2015 Sep;27(9):1002-10. doi: 10.1097/MEG.0000000000000425[][]
  68. Rezapour M, Ali S, Stollman N. Diverticular Disease: An Update on Pathogenesis and Management. Gut Liver. 2018 Mar 15;12(2):125-132. doi: 10.5009/gnl16552[]
  69. Korzenik JR. Case closed? Diverticulitis: epidemiology and fiber. J Clin Gastroenterol. 2006 Aug;40 Suppl 3:S112-6. doi: 10.1097/01.mcg.0000225503.59923.6c[][]
  70. Painter NS, Burkitt DP. Diverticular disease of the colon: a deficiency disease of Western civilization. Br Med J. 1971 May 22;2(5759):450-4. doi: 10.1136/bmj.2.5759.450[]
  71. Peery AF, Barrett PR, Park D, Rogers AJ, Galanko JA, Martin CF, Sandler RS. A high-fiber diet does not protect against asymptomatic diverticulosis. Gastroenterology. 2012 Feb;142(2):266-72.e1. doi: 10.1053/j.gastro.2011.10.035[]
  72. Carabotti M, Annibale B, Severi C, Lahner E. Role of Fiber in Symptomatic Uncomplicated Diverticular Disease: A Systematic Review. Nutrients. 2017 Feb 20;9(2):161. doi: 10.3390/nu9020161[][]
  73. Dahl C, Crichton M, Jenkins J, Nucera R, Mahoney S, Marx W, Marshall S. Evidence for Dietary Fibre Modification in the Recovery and Prevention of Reoccurrence of Acute, Uncomplicated Diverticulitis: A Systematic Literature Review. Nutrients. 2018 Jan 27;10(2):137. doi: 10.3390/nu10020137[][]
  74. Floch MH, Longo WE. United States Guidelines for Diverticulitis Treatment. J Clin Gastroenterol. 2016 Oct;50 Suppl 1:S53-6. doi: 10.1097/MCG.0000000000000668[]
  75. Galetin T, Galetin A, Vestweber KH, Rink AD. Systematic review and comparison of national and international guidelines on diverticular disease. Int J Colorectal Dis. 2018 Mar;33(3):261-272. doi: 10.1007/s00384-017-2960-z[]
  76. Webster DJ, Gough DC, Craven JL. The use of bulk evacuant in patients with haemorrhoids. Br J Surg. 1978 Apr;65(4):291-2. doi: 10.1002/bjs.1800650421[]
  77. Perez-Miranda M, Gomez-Cedenilla A, León-Colombo T, Pajares J, Mate-Jimenez J. Effect of fiber supplements on internal bleeding hemorrhoids. Hepatogastroenterology. 1996 Nov-Dec;43(12):1504-7.[]
  78. Garg P, Singh P. Adequate dietary fiber supplement and TONE can help avoid surgery in most patients with advanced hemorrhoids. Minerva Gastroenterol Dietol. 2017 Jun;63(2):92-96. doi: 10.23736/S1121-421X.17.02364-9[]
  79. Kamarul Zaman M, Chin KF, Rai V, Majid HA. Fiber and prebiotic supplementation in enteral nutrition: A systematic review and meta-analysis. World J Gastroenterol. 2015 May 7;21(17):5372-81. doi: 10.3748/wjg.v21.i17.5372[][]
  80. Staller K, Song M, Grodstein F, Whitehead WE, Matthews CA, Kuo B, Chan AT. Increased Long-term Dietary Fiber Intake Is Associated With a Decreased Risk of Fecal Incontinence in Older Women. Gastroenterology. 2018 Sep;155(3):661-667.e1. doi: 10.1053/j.gastro.2018.05.021[]
  81. Bliss DZ, Savik K, Jung HJ, Whitebird R, Lowry A, Sheng X. Dietary fiber supplementation for fecal incontinence: a randomized clinical trial. Res Nurs Health. 2014 Oct;37(5):367-78. doi: 10.1002/nur.21616[][]
  82. Markland AD, Burgio KL, Whitehead WE, Richter HE, Wilcox CM, Redden DT, Beasley TM, Goode PS. Loperamide Versus Psyllium Fiber for Treatment of Fecal Incontinence: The Fecal Incontinence Prescription (Rx) Management (FIRM) Randomized Clinical Trial. Dis Colon Rectum. 2015 Oct;58(10):983-93. doi: 10.1097/DCR.0000000000000442[]
  83. Wei ZH, Wang H, Chen XY, Wang BS, Rong ZX, Wang BS, Su BH, Chen HZ. Time- and dose-dependent effect of psyllium on serum lipids in mild-to-moderate hypercholesterolemia: a meta-analysis of controlled clinical trials. Eur J Clin Nutr. 2009 Jul;63(7):821-7. doi: 10.1038/ejcn.2008.49[]
  84. Brum J, Ramsey D, McRorie J, Bauer B, Kopecky SL. Meta-Analysis of Usefulness of Psyllium Fiber as Adjuvant Antilipid Therapy to Enhance Cholesterol Lowering Efficacy of Statins. Am J Cardiol. 2018 Oct 1;122(7):1169-1174. doi: 10.1016/j.amjcard.2018.06.040[]
  85. Jovanovski E, Yashpal S, Komishon A, Zurbau A, Blanco Mejia S, Ho HVT, Li D, Sievenpiper J, Duvnjak L, Vuksan V. Effect of psyllium (Plantago ovata) fiber on LDL cholesterol and alternative lipid targets, non-HDL cholesterol and apolipoprotein B: a systematic review and meta-analysis of randomized controlled trials. Am J Clin Nutr. 2018 Nov 1;108(5):922-932. doi: 10.1093/ajcn/nqy115[][]
  86. Sniderman AD, Williams K, Contois JH, Monroe HM, McQueen MJ, de Graaf J, Furberg CD. A meta-analysis of low-density lipoprotein cholesterol, non-high-density lipoprotein cholesterol, and apolipoprotein B as markers of cardiovascular risk. Circ Cardiovasc Qual Outcomes. 2011 May;4(3):337-45. doi: 10.1161/CIRCOUTCOMES.110.959247[]
  87. Ho HVT, Jovanovski E, Zurbau A, Blanco Mejia S, Sievenpiper JL, Au-Yeung F, Jenkins AL, Duvnjak L, Leiter L, Vuksan V. A systematic review and meta-analysis of randomized controlled trials of the effect of konjac glucomannan, a viscous soluble fiber, on LDL cholesterol and the new lipid targets non-HDL cholesterol and apolipoprotein B. Am J Clin Nutr. 2017 May;105(5):1239-1247. doi: 10.3945/ajcn.116.142158[]
  88. Ho HV, Sievenpiper JL, Zurbau A, Blanco Mejia S, Jovanovski E, Au-Yeung F, Jenkins AL, Vuksan V. The effect of oat β-glucan on LDL-cholesterol, non-HDL-cholesterol and apoB for CVD risk reduction: a systematic review and meta-analysis of randomised-controlled trials. Br J Nutr. 2016 Oct;116(8):1369-1382. doi: 10.1017/S000711451600341X[]
  89. Kerckhoffs DA, Hornstra G, Mensink RP. Cholesterol-lowering effect of beta-glucan from oat bran in mildly hypercholesterolemic subjects may decrease when beta-glucan is incorporated into bread and cookies. Am J Clin Nutr. 2003 Aug;78(2):221-7. doi: 10.1093/ajcn/78.2.221[]
  90. Food and Drug Administration. Electronic Code of Federal Regulations. Health claims: Soluble fiber from certain foods and risk of coronary heart disease (Title 21, Chapter I, Subchapter B, Part 101, Subpart E, §101.81). 9th May 2024. https://www.ecfr.gov/current/title-21/chapter-I/subchapter-B/part-101/subpart-E/section-101.81[][][]
  91. Wolk A, Manson JE, Stampfer MJ, Colditz GA, Hu FB, Speizer FE, Hennekens CH, Willett WC. Long-term intake of dietary fiber and decreased risk of coronary heart disease among women. JAMA. 1999 Jun 2;281(21):1998-2004. doi: 10.1001/jama.281.21.1998[]
  92. Pietinen P, Rimm EB, Korhonen P, Hartman AM, Willett WC, Albanes D, Virtamo J. Intake of dietary fiber and risk of coronary heart disease in a cohort of Finnish men. The Alpha-Tocopherol, Beta-Carotene Cancer Prevention Study. Circulation. 1996 Dec 1;94(11):2720-7. doi: 10.1161/01.cir.94.11.2720[]
  93. Threapleton DE, Greenwood DC, Evans CE, Cleghorn CL, Nykjaer C, Woodhead C, Cade JE, Gale CP, Burley VJ. Dietary fibre intake and risk of cardiovascular disease: systematic review and meta-analysis. BMJ. 2013 Dec 19;347:f6879. doi: 10.1136/bmj.f6879[][]
  94. Wu Y, Qian Y, Pan Y, Li P, Yang J, Ye X, Xu G. Association between dietary fiber intake and risk of coronary heart disease: A meta-analysis. Clin Nutr. 2015 Aug;34(4):603-11. doi: 10.1016/j.clnu.2014.05.009[][][]
  95. Ning H, Van Horn L, Shay CM, Lloyd-Jones DM. Associations of dietary fiber intake with long-term predicted cardiovascular disease risk and C-reactive protein levels (from the National Health and Nutrition Examination Survey Data [2005-2010]). Am J Cardiol. 2014 Jan 15;113(2):287-91. doi: 10.1016/j.amjcard.2013.09.020[]
  96. Honsek C, Kabisch S, Kemper M, Gerbracht C, Arafat AM, Birkenfeld AL, Dambeck U, Osterhoff MA, Weickert MO, Pfeiffer AFH. Fibre supplementation for the prevention of type 2 diabetes and improvement of glucose metabolism: the randomised controlled Optimal Fibre Trial (OptiFiT). Diabetologia. 2018 Jun;61(6):1295-1305. doi: 10.1007/s00125-018-4582-6[][]
  97. Schäfer G, Schenk U, Ritzel U, Ramadori G, Leonhardt U. Comparison of the effects of dried peas with those of potatoes in mixed meals on postprandial glucose and insulin concentrations in patients with type 2 diabetes. Am J Clin Nutr. 2003 Jul;78(1):99-103. doi: 10.1093/ajcn/78.1.99[]
  98. Kabir M, Oppert JM, Vidal H, Bruzzo F, Fiquet C, Wursch P, Slama G, Rizkalla SW. Four-week low-glycemic index breakfast with a modest amount of soluble fibers in type 2 diabetic men. Metabolism. 2002 Jul;51(7):819-26. doi: 10.1053/meta.2002.33345[]
  99. Brand-Miller JC, Atkinson FS, Gahler RJ, Kacinik V, Lyon MR, Wood S. Effects of PGX, a novel functional fibre, on acute and delayed postprandial glycaemia. Eur J Clin Nutr. 2010 Dec;64(12):1488-93. doi: 10.1038/ejcn.2010.199[]
  100. Jenkins AL, Kacinik V, Lyon MR, Wolever TM. Reduction of postprandial glycemia by the novel viscous polysaccharide PGX, in a dose-dependent manner, independent of food form. J Am Coll Nutr. 2010 Apr;29(2):92-8. doi: 10.1080/07315724.2010.10719821[]
  101. Sierra M, Garcia JJ, Fernández N, Diez MJ, Calle AP, Sahagún AM; Farmafibra Group. Effects of ispaghula husk and guar gum on postprandial glucose and insulin concentrations in healthy subjects. Eur J Clin Nutr. 2001 Apr;55(4):235-43. doi: 10.1038/sj.ejcn.1601147[]
  102. Williams JA, Lai CS, Corwin H, Ma Y, Maki KC, Garleb KA, Wolf BW. Inclusion of guar gum and alginate into a crispy bar improves postprandial glycemia in humans. J Nutr. 2004 Apr;134(4):886-9. doi: 10.1093/jn/134.4.886[]
  103. Gibb RD, McRorie JW Jr, Russell DA, Hasselblad V, D’Alessio DA. Psyllium fiber improves glycemic control proportional to loss of glycemic control: a meta-analysis of data in euglycemic subjects, patients at risk of type 2 diabetes mellitus, and patients being treated for type 2 diabetes mellitus. Am J Clin Nutr. 2015 Dec;102(6):1604-14. doi: 10.3945/ajcn.115.106989[][][]
  104. Bodnaruc AM, Prud’homme D, Blanchet R, Giroux I. Nutritional modulation of endogenous glucagon-like peptide-1 secretion: a review. Nutr Metab (Lond). 2016 Dec 9;13:92. doi: 10.1186/s12986-016-0153-3[]
  105. Yao B, Fang H, Xu W, Yan Y, Xu H, Liu Y, Mo M, Zhang H, Zhao Y. Dietary fiber intake and risk of type 2 diabetes: a dose-response analysis of prospective studies. Eur J Epidemiol. 2014 Feb;29(2):79-88. doi: 10.1007/s10654-013-9876-x[][][]
  106. InterAct Consortium. Dietary fibre and incidence of type 2 diabetes in eight European countries: the EPIC-InterAct Study and a meta-analysis of prospective studies. Diabetologia. 2015 Jul;58(7):1394-408. doi: 10.1007/s00125-015-3585-9[][]
  107. Whincup PH, Donin AS. Cereal fibre and type 2 diabetes: time now for randomised controlled trials? Diabetologia. 2015 Jul;58(7):1383-5. doi: 10.1007/s00125-015-3644-2[]
  108. Giacco R, Costabile G, Della Pepa G, Anniballi G, Griffo E, Mangione A, Cipriano P, Viscovo D, Clemente G, Landberg R, Pacini G, Rivellese AA, Riccardi G. A whole-grain cereal-based diet lowers postprandial plasma insulin and triglyceride levels in individuals with metabolic syndrome. Nutr Metab Cardiovasc Dis. 2014 Aug;24(8):837-44. doi: 10.1016/j.numecd.2014.01.007[]
  109. Gemen R, de Vries JF, Slavin JL. Relationship between molecular structure of cereal dietary fiber and health effects: focus on glucose/insulin response and gut health. Nutr Rev. 2011 Jan;69(1):22-33. doi: 10.1111/j.1753-4887.2010.00357.x[]
  110. McRae MP. Dietary Fiber Intake and Type 2 Diabetes Mellitus: An Umbrella Review of Meta-analyses. J Chiropr Med. 2018 Mar;17(1):44-53. doi: 10.1016/j.jcm.2017.11.002[]
  111. Anderson JW, Randles KM, Kendall CW, Jenkins DJ. Carbohydrate and fiber recommendations for individuals with diabetes: a quantitative assessment and meta-analysis of the evidence. J Am Coll Nutr. 2004 Feb;23(1):5-17. doi: 10.1080/07315724.2004.10719338[][]
  112. MacLeod J, Franz MJ, Handu D, Gradwell E, Brown C, Evert A, Reppert A, Robinson M. Academy of Nutrition and Dietetics Nutrition Practice Guideline for Type 1 and Type 2 Diabetes in Adults: Nutrition Intervention Evidence Reviews and Recommendations. J Acad Nutr Diet. 2017 Oct;117(10):1637-1658. doi: 10.1016/j.jand.2017.03.023[]
  113. American Diabetes Association; Bantle JP, Wylie-Rosett J, Albright AL, Apovian CM, Clark NG, Franz MJ, Hoogwerf BJ, Lichtenstein AH, Mayer-Davis E, Mooradian AD, Wheeler ML. Nutrition recommendations and interventions for diabetes: a position statement of the American Diabetes Association. Diabetes Care. 2008 Jan;31 Suppl 1:S61-78. doi: 10.2337/dc08-S061. Erratum in: Diabetes Care. 2010 Aug;33(8):1911[]
  114. American Diabetes Association; Bantle JP, Wylie-Rosett J, Albright AL, Apovian CM, Clark NG, Franz MJ, Hoogwerf BJ, Lichtenstein AH, Mayer-Davis E, Mooradian AD, Wheeler ML. Nutrition recommendations and interventions for diabetes: a position statement of the American Diabetes Association. Diabetes Care. 2008 Jan;31 Suppl 1:S61-78. doi: 10.2337/dc08-S061. Erratum in: Diabetes Care. 2010 Aug;33(8):1911.[]
  115. Medina-Remón A, Kirwan R, Lamuela-Raventós RM, Estruch R. Dietary patterns and the risk of obesity, type 2 diabetes mellitus, cardiovascular diseases, asthma, and neurodegenerative diseases. Crit Rev Food Sci Nutr. 2018 Jan 22;58(2):262-296. doi: 10.1080/10408398.2016.1158690[]
  116. Schwingshackl L, Missbach B, König J, Hoffmann G. Adherence to a Mediterranean diet and risk of diabetes: a systematic review and meta-analysis. Public Health Nutr. 2015 May;18(7):1292-9. doi: 10.1017/S1368980014001542[]
  117. Huo R, Du T, Xu Y, Xu W, Chen X, Sun K, Yu X. Effects of Mediterranean-style diet on glycemic control, weight loss and cardiovascular risk factors among type 2 diabetes individuals: a meta-analysis. Eur J Clin Nutr. 2015 Nov;69(11):1200-8. doi: 10.1038/ejcn.2014.243[]
  118. Jovanovski E, Khayyat R, Zurbau A, Komishon A, Mazhar N, Sievenpiper JL, Blanco Mejia S, Ho HVT, Li D, Jenkins AL, Duvnjak L, Vuksan V. Should Viscous Fiber Supplements Be Considered in Diabetes Control? Results From a Systematic Review and Meta-analysis of Randomized Controlled Trials. Diabetes Care. 2019 May;42(5):755-766. doi: 10.2337/dc18-1126. Epub 2019 Jan 7. Erratum in: Diabetes Care. 2019 Aug;42(8):1604. doi: 10.2337/dc19-er08a[]
  119. McRorie JWJ, Gibb RD, Womack JB, Pambianco DJ. Psyllium is superior to wheat dextrin for lowering elevated serum cholesterol. Nutrition Today. 2017;52(6):289-294. DOI: 10.1097/NT.0000000000000243[]
  120. Jenkins DJ, Kendall CW, Augustin LS, Martini MC, Axelsen M, Faulkner D, Vidgen E, Parker T, Lau H, Connelly PW, Teitel J, Singer W, Vandenbroucke AC, Leiter LA, Josse RG. Effect of wheat bran on glycemic control and risk factors for cardiovascular disease in type 2 diabetes. Diabetes Care. 2002 Sep;25(9):1522-8. doi: 10.2337/diacare.25.9.1522[]
  121. Whelton PK, Carey RM, Aronow WS, Casey DE Jr, Collins KJ, Dennison Himmelfarb C, DePalma SM, Gidding S, Jamerson KA, Jones DW, MacLaughlin EJ, Muntner P, Ovbiagele B, Smith SC Jr, Spencer CC, Stafford RS, Taler SJ, Thomas RJ, Williams KA Sr, Williamson JD, Wright JT Jr. 2017 ACC/AHA/AAPA/ABC/ACPM/AGS/APhA/ASH/ASPC/NMA/PCNA Guideline for the Prevention, Detection, Evaluation, and Management of High Blood Pressure in Adults: A Report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. J Am Coll Cardiol. 2018 May 15;71(19):e127-e248. doi: 10.1016/j.jacc.2017.11.006. Epub 2017 Nov 13. Erratum in: J Am Coll Cardiol. 2018 May 15;71(19):2275-2279. doi: 10.1016/j.jacc.2018.03.016[]
  122. Khan K, Jovanovski E, Ho HVT, Marques ACR, Zurbau A, Mejia SB, Sievenpiper JL, Vuksan V. The effect of viscous soluble fiber on blood pressure: A systematic review and meta-analysis of randomized controlled trials. Nutr Metab Cardiovasc Dis. 2018 Jan;28(1):3-13. doi: 10.1016/j.numecd.2017.09.007[][]
  123. Aguilar M, Bhuket T, Torres S, Liu B, Wong RJ. Prevalence of the metabolic syndrome in the United States, 2003-2012. JAMA. 2015 May 19;313(19):1973-4. doi: 10.1001/jama.2015.4260[]
  124. Chen JP, Chen GC, Wang XP, Qin L, Bai Y. Dietary Fiber and Metabolic Syndrome: A Meta-Analysis and Review of Related Mechanisms. Nutrients. 2017 Dec 26;10(1):24. doi: 10.3390/nu10010024[]
  125. Wei B, Liu Y, Lin X, Fang Y, Cui J, Wan J. Dietary fiber intake and risk of metabolic syndrome: A meta-analysis of observational studies. Clin Nutr. 2018 Dec;37(6 Pt A):1935-1942. doi: 10.1016/j.clnu.2017.10.019[]
  126. Weickert M.O., Roden M., Isken F., Hoffmann D., Nowotny P., Osterhoff M., Blaut M., Alpert C., Gogebakan O., Bumke-Vogt C., et al. Effects of supplemented isoenergetic diets differing in cereal fiber and protein content on insulin sensitivity in overweight humans. Am. J. Clin. Nutr. 2011;94:459–471. doi: 10.3945/ajcn.110.004374[][][][]
  127. Morimoto N., Kasuga C., Tanaka A., Kamachi K., Ai M., Urayama K.Y., Tanaka A. Association between dietary fibre:carbohydrate intake ratio and insulin resistance in Japanese adults without type 2 diabetes. Br. J. Nutr. 2018;119:620–628. doi: 10.1017/S0007114517003725[][][]
  128. Castro-Quezada I., Flores-Guillen E., Nunez-Ortega P.E., Irecta-Najera C.A., Sanchez-Chino X.M., Mendez-Flores O.G., Olivo-Vidal Z.E., Garcia-Miranda R., Solis-Hernandez R., Ochoa-Diaz-Lopez H. Dietary Carbohydrates and Insulin Resistance in Adolescents from Marginalized Areas of Chiapas, Mexico. Nutrients. 2019;11:3066. doi: 10.3390/nu11123066[]
  129. Reynolds A.N., Akerman A.P., Mann J. Dietary fibre and whole grains in diabetes management: Systematic review and meta-analyses. PLoS Med. 2020;17:e1003053. doi: 10.1371/journal.pmed.1003053[][]
  130. Mao T., Huang F., Zhu X., Wei D., Chen L. Effects of dietary fiber on glycemic control and insulin sensitivity in patients with type 2 diabetes: A systematic review and meta-analysis. J. Funct. Foods. 2021;82:104500. doi: 10.1016/j.jff.2021.104500[][]
  131. Russell W.R., Baka A., Bjorck I., Delzenne N., Gao D., Griffiths H.R., Hadjilucas E., Juvonen K., Lahtinen S., Lansink M., et al. Impact of Diet Composition on Blood Glucose Regulation. Crit. Rev. Food Sci. Nutr. 2016;56:541–590. doi: 10.1080/10408398.2013.792772[]
  132. Isken F., Klaus S., Petzke K.J., Loddenkemper C., Pfeiffer A.F., Weickert M.O. Impairment of fat oxidation under high- vs. low-glycemic index diet occurs before the development of an obese phenotype. Am. J. Physiol. Endocrinol. Metab. 2010;298:E287–E295. doi: 10.1152/ajpendo.00515.2009[]
  133. Gruendel S., Otto B., Garcia A.L., Wagner K., Mueller C., Weickert M.O., Heldwein W., Koebnick C. Carob pulp preparation rich in insoluble dietary fibre and polyphenols increases plasma glucose and serum insulin responses in combination with a glucose load in humans. Br. J. Nutr. 2007;98:101–105. doi: 10.1017/S0007114507701642[]
  134. Schulze M.B., Schulz M., Heidemann C., Schienkiewitz A., Hoffmann K., Boeing H. Fiber and magnesium intake and incidence of type 2 diabetes: A prospective study and meta-analysis. Arch. Intern. Med. 2007;167:956–965. doi: 10.1001/archinte.167.9.956[]
  135. De Munter J.S., Hu F.B., Spiegelman D., Franz M., van Dam R.M. Whole grain, bran, and germ intake and risk of type 2 diabetes: A prospective cohort study and systematic review. PLoS Med. 2007;4:e261. doi: 10.1371/journal.pmed.0040261[]
  136. Isken F., Weickert M.O., Tschop M.H., Nogueiras R., Mohlig M., Abdelrahman A., Klaus S., Thorens B., Pfeiffer A.F. Metabolic effects of diets differing in glycaemic index depend on age and endogenous glucose-dependent insulinotrophic polypeptide in mice. Diabetologia. 2009;52:2159–2168. doi: 10.1007/s00125-009-1466-9[]
  137. Weickert M.O., Spranger J., Holst J.J., Otto B., Koebnick C., Mohlig M., Pfeiffer A.F.H. Wheat-fibre-induced changes of postprandial peptide YY and ghrelin responses are not associated with acute alterations of satiety. Br. J. Nutr. 2006;96:795–798. doi: 10.1017/BJN20061902[]
  138. Mohlig M., Koebnick C., Weickert M.O., Lueder W., Otto B., Steiniger J., Twilfert M., Meuser F., Pfeiffer A.F.H., Zunft H.J. Arabinoxylan-enriched meal increases serum ghrelin levels in healthy humans. Horm. Metab. Res. 2005;37:303–308. doi: 10.1055/s-2005-861474[]
  139. Gruendel S., Garcia A.L., Otto B., Mueller C., Steiniger J., Weickert M.O., Speth M., Katz N., Koebnick C. Carob pulp preparation rich in insoluble dietary fiber and polyphenols enhances lipid oxidation and lowers postprandial acylated ghrelin in humans. J. Nutr. 2006;136:1533–1538. doi: 10.1093/jn/136.6.1533[]
  140. Garcia A.L., Otto B., Reich S.C., Weickert M.O., Steiniger J., Machowetz A., Rudovich N.N., Mohlig M., Katz N., Speth M., et al. Arabinoxylan consumption decreases postprandial serum glucose, serum insulin and plasma total ghrelin response in subjects with impaired glucose tolerance. Eur. J. Clin. Nutr. 2007;61:334–341. doi: 10.1038/sj.ejcn.1602525[]
  141. Gruendel S., Garcia A.L., Otto B., Wagner K., Bidlingmaier M., Burget L., Weickert M.O., Dongowski G., Speth M., Katz N., et al. Increased acylated plasma ghrelin, but improved lipid profiles 24-h after consumption of carob pulp preparation rich in dietary fibre and polyphenols. Br. J. Nutr. 2007;98:1170–1177. doi: 10.1017/S0007114507777127[]
  142. Garcia A.L., Steiniger J., Reich S.C., Weickert M.O., Harsch I., Machowetz A., Mohlig M., Spranger J., Rudovich N.N., Meuser F., et al. Arabinoxylan fibre consumption improved glucose metabolism, but did not affect serum adipokines in subjects with impaired glucose tolerance. Horm. Metab. Res. 2006;38:761–766. doi: 10.1055/s-2006-955089[]
  143. Weickert M.O., Hattersley J.G., Kyrou I., Arafat A.M., Rudovich N., Roden M., Nowotny P., von Loeffelholz C., Matysik S., Schmitz G., et al. Effects of supplemented isoenergetic diets varying in cereal fiber and protein content on the bile acid metabolic signature and relation to insulin resistance. Nutr. Diabetes. 2018;8:11. doi: 10.1038/s41387-018-0020-6[]
  144. Hattersley J.G., Pfeiffer A.F., Roden M., Petzke K.J., Hoffmann D., Rudovich N.N., Randeva H.S., Vatish M., Osterhoff M., Goegebakan O., et al. Modulation of amino acid metabolic signatures by supplemented isoenergetic diets differing in protein and cereal fiber content. J. Clin. Endocrinol. Metab. 2014;99:E2599–E2609. doi: 10.1210/jc.2014-2302[]
  145. Bradbury KE, Appleby PN, Key TJ. Fruit, vegetable, and fiber intake in relation to cancer risk: findings from the European Prospective Investigation into Cancer and Nutrition (EPIC). Am J Clin Nutr. 2014 Jul;100 Suppl 1:394S-8S. doi: 10.3945/ajcn.113.071357[][][][]
  146. Reynolds A., Mann J., Cummings J., Winter N., Mete E., Te Morenga L. Carbohydrate Quality and Human Health: A Series of Systematic Reviews and Meta-Analyses. Lancet. 2019;393:434–445. doi: 10.1016/S0140-6736(18)31809-9[]
  147. World Cancer Research Fund International . Diet, Nutrition, Physical Activity and Cancer: A Global Perspective: A Summary of the Third Expert Report. World Cancer Research Fund International; London, UK: 2018. pp. 15–30.[]
  148. Wang C., Li P., Xuan J., Zhu C., Liu J., Shan L., Du Q., Ren Y., Ye J. Cholesterol Enhances Colorectal Cancer Progression via ROS Elevation and MAPK Signaling Pathway Activation. Cell. Physiol. Biochem. 2017;42:729–742. doi: 10.1159/000477890[]
  149. Farhana L., Nangia-Makker P., Arbit E., Shango K., Sarkar S., Mahmud H., Hadden T., Yu Y., Majumdar A.P.N. Bile Acid: A Potential Inducer of Colon Cancer Stem Cells. Stem Cell Res. Ther. 2016;7:181. doi: 10.1186/s13287-016-0439-4[]
  150. Stadler J., Stern H.S., Yeung K.S., McGuire V., Furrer R., Marcon N., Bruce W.R. Effect of High Fat Consumption on Cell Proliferation Activity of Colorectal Mucosa and on Soluble Faecal Bile Acids. Gut. 1988;29:1326–1331. doi: 10.1136/gut.29.10.1326[]
  151. Akin H., Tözün N. Diet, Microbiota, and Colorectal Cancer. J. Clin. Gastroenterol. 2014;48((Suppl. S1[]
  152. Fung K.Y.C., Cosgrove L., Lockett T., Head R., Topping D.L. A Review of the Potential Mechanisms for the Lowering of Colorectal Oncogenesis by Butyrate. Br. J. Nutr. 2012;108:820–831. doi: 10.1017/S0007114512001948[]
  153. Bordonaro M., Lazarova D.L., Sartorelli A.C. Butyrate and Wnt Signaling: A Possible Solution to the Puzzle of Dietary Fiber and Colon Cancer Risk? Cell Cycle. 2008;7:1178–1183. doi: 10.4161/cc.7.9.5818[]
  154. Grosse Y., Baan R., Straif K., Secretan B., Ghissassi F.E., Cogliano V. Carcinogenicity of Nitrate, Nitrite, and Cyanobacterial Peptide Toxins. Lancet Oncol. 2006;7:628–629. doi: 10.1016/S1470-2045(06)70789-6[]
  155. Møller M.E., Dahl R., Bøckman O.C. A Possible Role of the Dietary Fibre Product, Wheat Bran, as a Nitrite Scavenger. Food Chem. Toxicol. 1988;26:841–845. doi: 10.1016/0278-6915(88)90024-5[]
  156. Sun L., Zhang Z., Xu J., Xu G., Liu X. Dietary Fiber Intake Reduces Risk for Barrett’s Esophagus and Esophageal Cancer. Crit. Rev. Food Sci. Nutr. 2017;57:2749–2757. doi: 10.1080/10408398.2015.1067596[]
  157. Mayne S.T., Navarro S.A. Diet, Obesity and Reflux in the Etiology of Adenocarcinomas of the Esophagus and Gastric Cardia in Humans. J. Nutr. 2002;132:3467S–3470S. doi: 10.1093/jn/132.11.3467S[]
  158. Mulholland H.G., Cantwell M.M., Anderson L.A., Johnston B.T., Watson R.G.P., Murphy S.J., Ferguson H.R., McGuigan J., Reynolds J.V., Comber H., et al. Glycemic Index, Carbohydrate and Fiber Intakes and Risk of Reflux Esophagitis, Barrett’s Esophagus, and Esophageal Adenocarcinoma. Cancer Causes Control. 2009;20:279–288. doi: 10.1007/s10552-008-9242-6[]
  159. McFadden D., Riggs D., Jackson B., Cunningham C. Corn-Derived Carbohydrate Inositol Hexaphosphate Inhibits Barrett’s Adenocarcinoma Growth by pro-Apoptotic Mechanisms. Oncol. Rep. 2008;19:563–566. doi: 10.3892/or.19.2.563[]
  160. Aune D, Chan DS, Greenwood DC, Vieira AR, Rosenblatt DA, Vieira R, Norat T. Dietary fiber and breast cancer risk: a systematic review and meta-analysis of prospective studies. Ann Oncol. 2012 Jun;23(6):1394-402. doi: 10.1093/annonc/mdr589[][]
  161. Chen S, Chen Y, Ma S, Zheng R, Zhao P, Zhang L, Liu Y, Yu Q, Deng Q, Zhang K. Dietary fibre intake and risk of breast cancer: A systematic review and meta-analysis of epidemiological studies. Oncotarget. 2016 Dec 6;7(49):80980-80989. doi: 10.18632/oncotarget.13140[][]
  162. Ben Q, Sun Y, Chai R, Qian A, Xu B, Yuan Y. Dietary fiber intake reduces risk for colorectal adenoma: a meta-analysis. Gastroenterology. 2014 Mar;146(3):689-699.e6. doi: 10.1053/j.gastro.2013.11.003[][]
  163. Ma Y, Hu M, Zhou L, Ling S, Li Y, Kong B, Huang P. Dietary fiber intake and risks of proximal and distal colon cancers: A meta-analysis. Medicine (Baltimore). 2018 Sep;97(36):e11678. doi: 10.1097/MD.0000000000011678[][]
  164. Gianfredi V, Salvatori T, Villarini M, Moretti M, Nucci D, Realdon S. Is dietary fibre truly protective against colon cancer? A systematic review and meta-analysis. Int J Food Sci Nutr. 2018 Dec;69(8):904-915. doi: 10.1080/09637486.2018.1446917[][]
  165. Chen K, Zhao Q, Li X, Zhao J, Li P, Lin S, Wang H, Zang J, Xiao Y, Xu W, Chen F, Gao Y. Dietary Fiber Intake and Endometrial Cancer Risk: A Systematic Review and Meta-Analysis. Nutrients. 2018 Jul 22;10(7):945. doi: 10.3390/nu10070945[][]
  166. Coleman HG, Murray LJ, Hicks B, Bhat SK, Kubo A, Corley DA, Cardwell CR, Cantwell MM. Dietary fiber and the risk of precancerous lesions and cancer of the esophagus: a systematic review and meta-analysis. Nutr Rev. 2013 Jul;71(7):474-82. doi: 10.1111/nure.12032[][]
  167. Sun L, Zhang Z, Xu J, Xu G, Liu X. Dietary fiber intake reduces risk for Barrett’s esophagus and esophageal cancer. Crit Rev Food Sci Nutr. 2017 Sep 2;57(13):2749-2757. doi: 10.1080/10408398.2015.1067596[][]
  168. Zhang Z, Xu G, Ma M, Yang J, Liu X. Dietary fiber intake reduces risk for gastric cancer: a meta-analysis. Gastroenterology. 2013 Jul;145(1):113-120.e3. doi: 10.1053/j.gastro.2013.04.001[][]
  169. Xu H, Ding Y, Xin X, Wang W, Zhang D. Dietary fiber intake is associated with a reduced risk of ovarian cancer: a dose-response meta-analysis. Nutr Res. 2018 Sep;57:1-11. doi: 10.1016/j.nutres.2018.04.011[][]
  170. Huang X, Wang X, Shang J, Lin Y, Yang Y, Song Y, Yu S. Association between dietary fiber intake and risk of ovarian cancer: a meta-analysis of observational studies. J Int Med Res. 2018 Oct;46(10):3995-4005. doi: 10.1177/0300060518792801[][]
  171. Mao QQ, Lin YW, Chen H, Qin J, Zheng XY, Xu X, Xie LP. Dietary fiber intake is inversely associated with risk of pancreatic cancer: a meta-analysis. Asia Pac J Clin Nutr. 2017 Jan;26(1):89-96. doi: 10.6133/apjcn.102015.03[][][]
  172. Sheng T, Shen RL, Shao H, Ma TH. No association between fiber intake and prostate cancer risk: a meta-analysis of epidemiological studies. World J Surg Oncol. 2015 Aug 28;13:264. doi: 10.1186/s12957-015-0681-8[][]
  173. Wang RJ, Tang JE, Chen Y, Gao JG. Dietary fiber, whole grains, carbohydrate, glycemic index, and glycemic load in relation to risk of prostate cancer. Onco Targets Ther. 2015 Sep 2;8:2415-26. doi: 10.2147/OTT.S88528[][]
  174. Huang TB, Ding PP, Chen JF, Yan Y, Zhang L, Liu H, Liu PC, Che JP, Zheng JH, Yao XD. Dietary fiber intake and risk of renal cell carcinoma: evidence from a meta-analysis. Med Oncol. 2014 Aug;31(8):125. doi: 10.1007/s12032-014-0125-2[][]
  175. Andrade C. Understanding relative risk, odds ratio, and related terms: as simple as it can get. J Clin Psychiatry. 2015 Jul;76(7):e857-61. doi: 10.4088/JCP.15f10150[][]
  176. McRae MP. The Benefits of Dietary Fiber Intake on Reducing the Risk of Cancer: An Umbrella Review of Meta-analyses. J Chiropr Med. 2018 Jun;17(2):90-96. doi: 10.1016/j.jcm.2017.12.001[][]
  177. Bultman SJ. Molecular pathways: gene-environment interactions regulating dietary fiber induction of proliferation and apoptosis via butyrate for cancer prevention. Clin Cancer Res. 2014 Feb 15;20(4):799-803. doi: 10.1158/1078-0432.CCR-13-2483[][]
  178. Kosumi K, Mima K, Baba H, Ogino S. Dysbiosis of the gut microbiota and colorectal cancer: the key target of molecular pathological epidemiology. J Lab Precis Med. 2018 Sep;3:76. doi: 10.21037/jlpm.2018.09.05[]
  179. Ubeda C, Djukovic A, Isaac S. Roles of the intestinal microbiota in pathogen protection. Clin Transl Immunology. 2017 Feb 10;6(2):e128. doi: 10.1038/cti.2017.2[]
  180. Encarnação JC, Abrantes AM, Pires AS, Botelho MF. Revisit dietary fiber on colorectal cancer: butyrate and its role on prevention and treatment. Cancer Metastasis Rev. 2015 Sep;34(3):465-78. doi: 10.1007/s10555-015-9578-9[]
  181. Sivaprakasam S, Prasad PD, Singh N. Benefits of short-chain fatty acids and their receptors in inflammation and carcinogenesis. Pharmacol Ther. 2016 Aug;164:144-51. doi: 10.1016/j.pharmthera.2016.04.007[]
  182. Alberts DS, Martínez ME, Roe DJ, Guillén-Rodríguez JM, Marshall JR, van Leeuwen JB, Reid ME, Ritenbaugh C, Vargas PA, Bhattacharyya AB, Earnest DL, Sampliner RE. Lack of effect of a high-fiber cereal supplement on the recurrence of colorectal adenomas. Phoenix Colon Cancer Prevention Physicians’ Network. N Engl J Med. 2000 Apr 20;342(16):1156-62. doi: 10.1056/NEJM200004203421602[]
  183. DeCosse JJ, Miller HH, Lesser ML. Effect of wheat fiber and vitamins C and E on rectal polyps in patients with familial adenomatous polyposis. J Natl Cancer Inst. 1989 Sep 6;81(17):1290-7. doi: 10.1093/jnci/81.17.1290[]
  184. Ishikawa H, Akedo I, Otani T, Suzuki T, Nakamura T, Takeyama I, Ishiguro S, Miyaoka E, Sobue T, Kakizoe T. Randomized trial of dietary fiber and Lactobacillus casei administration for prevention of colorectal tumors. Int J Cancer. 2005 Sep 20;116(5):762-7. doi: 10.1002/ijc.21115[]
  185. MacLennan R, Macrae F, Bain C, Battistutta D, Chapuis P, Gratten H, Lambert J, Newland RC, Ngu M, Russell A, Ward M, Wahlqvist ML; Australian Polyp Prevention Project. Randomized trial of intake of fat, fiber, and beta carotene to prevent colorectal adenomas. J Natl Cancer Inst. 1995 Dec 6;87(23):1760-6. doi: 10.1093/jnci/87.23.1760[]
  186. McKeown-Eyssen GE, Bright-See E, Bruce WR, Jazmaji V, Cohen LB, Pappas SC, Saibil FG. A randomized trial of a low fat high fibre diet in the recurrence of colorectal polyps. Toronto Polyp Prevention Group. J Clin Epidemiol. 1994 May;47(5):525-36. doi: 10.1016/0895-4356(94)90299-2. Erratum in: J Clin Epidemiol 1995 Feb;48(2):i.[]
  187. Bonithon-Kopp C, Kronborg O, Giacosa A, Räth U, Faivre J. Calcium and fibre supplementation in prevention of colorectal adenoma recurrence: a randomised intervention trial. European Cancer Prevention Organisation Study Group. Lancet. 2000 Oct 14;356(9238):1300-6. doi: 10.1016/s0140-6736(00)02813-0[][][]
  188. Schatzkin A, Lanza E, Corle D, Lance P, Iber F, Caan B, Shike M, Weissfeld J, Burt R, Cooper MR, Kikendall JW, Cahill J. Lack of effect of a low-fat, high-fiber diet on the recurrence of colorectal adenomas. Polyp Prevention Trial Study Group. N Engl J Med. 2000 Apr 20;342(16):1149-55. doi: 10.1056/NEJM200004203421601[]
  189. Yao Y, Suo T, Andersson R, Cao Y, Wang C, Lu J, Chui E. Dietary fibre for the prevention of recurrent colorectal adenomas and carcinomas. Cochrane Database Syst Rev. 2017 Jan 8;1(1):CD003430. doi: 10.1002/14651858.CD003430.pub2[]
  190. Hormones. https://www.cancer.gov/about-cancer/causes-prevention/risk/hormones[]
  191. Rock CL, Flatt SW, Thomson CA, Stefanick ML, Newman VA, Jones LA, Natarajan L, Ritenbaugh C, Hollenbach KA, Pierce JP, Chang RJ. Effects of a high-fiber, low-fat diet intervention on serum concentrations of reproductive steroid hormones in women with a history of breast cancer. J Clin Oncol. 2004 Jun 15;22(12):2379-87. doi: 10.1200/JCO.2004.09.025[]
  192. Kasim-Karakas SE, Almario RU, Gregory L, Todd H, Wong R, Lasley BL. Effects of prune consumption on the ratio of 2-hydroxyestrone to 16alpha-hydroxyestrone. Am J Clin Nutr. 2002 Dec;76(6):1422-7. doi: 10.1093/ajcn/76.6.1422[]
  193. Manoj G, Thampi BS, Leelamma S, Menon PV. Effect of dietary fiber on the activity of intestinal and fecal beta-glucuronidase activity during 1,2-dimethylhydrazine induced colon carcinogenesis. Plant Foods Hum Nutr. 2001;56(1):13-21. doi: 10.1023/a:1008188009174[]
  194. Fernández MF, Reina-Pérez I, Astorga JM, Rodríguez-Carrillo A, Plaza-Díaz J, Fontana L. Breast Cancer and Its Relationship with the Microbiota. Int J Environ Res Public Health. 2018 Aug 14;15(8):1747. doi: 10.3390/ijerph15081747[]
  195. Landete JM. Plant and mammalian lignans: A review of source, intake, metabolism, intestinal bacteria and health. Food Research International. 2012;46(1):410-424.[]
  196. Wang CH, Qiao C, Wang RC, Zhou WP. Dietary fiber intake and pancreatic cancer risk: a meta-analysis of epidemiologic studies. Sci Rep. 2015 Jun 2;5:10834. doi: 10.1038/srep10834[]
  197. Singh V, Yeoh BS, Chassaing B, Xiao X, Saha P, Aguilera Olvera R, Lapek JD Jr, Zhang L, Wang WB, Hao S, Flythe MD, Gonzalez DJ, Cani PD, Conejo-Garcia JR, Xiong N, Kennett MJ, Joe B, Patterson AD, Gewirtz AT, Vijay-Kumar M. Dysregulated Microbial Fermentation of Soluble Fiber Induces Cholestatic Liver Cancer. Cell. 2018 Oct 18;175(3):679-694.e22. doi: 10.1016/j.cell.2018.09.004[][]
  198. Solah V.A., Kerr D.A., Hunt W.J., Johnson S.K., Boushey C.J., Delp E.J., Meng X., Gahler R.J., James A.P., Mukhtar A.S., et al. Effect of Fibre Supplementation on Body Weight and Composition, Frequency of Eating and Dietary Choice in Overweight Individuals. Nutrients. 2017;9:149. doi: 10.3390/nu9020149[][][]
  199. Hervik AK, Svihus B. The Role of Fiber in Energy Balance. J Nutr Metab. 2019 Jan 21;2019:4983657. doi: 10.1155/2019/4983657[][]
  200. Karhunen LJ, Juvonen KR, Flander SM, Liukkonen KH, Lähteenmäki L, Siloaho M, Laaksonen DE, Herzig KH, Uusitupa MI, Poutanen KS. A psyllium fiber-enriched meal strongly attenuates postprandial gastrointestinal peptide release in healthy young adults. J Nutr. 2010 Apr;140(4):737-44. doi: 10.3945/jn.109.115436[]
  201. Weickert M.O. What dietary modification best improves insulin sensitivity and why? Clin. Endocrinol. 2012;77:508–512. doi: 10.1111/j.1365-2265.2012.04450.x[]
  202. Weickert M.O. High fiber intake, dietary protein, and prevention of type 2 diabetes. Expert Rev. Endocrinol. Metab. 2018;13:223–224. doi: 10.1080/17446651.2018.1513320[]
  203. Clark MJ, Slavin JL. The effect of fiber on satiety and food intake: a systematic review. J Am Coll Nutr. 2013;32(3):200-11. doi: 10.1080/07315724.2013.791194[][]
  204. Kim S.J., de Souza R.J., Choo V.L., Ha V., Cozma A.I., Chiavaroli L., Mirrahimi A., Blanco Mejia S., Di Buono M., Bernstein A.M., et al. Effects of dietary pulse consumption on body weight: A systematic review and meta-analysis of randomized controlled trials. Am. J. Clin. Nutr. 2016;103:1213–1223. doi: 10.3945/ajcn.115.124677[][]
  205. Jovanovski E., Mazhar N., Komishon A., Khayyat R., Li D., Blanco Mejia S., Khan T., Jenkins A.L., Smircic-Duvnjak L., Sievenpiper J.L., et al. Can dietary viscous fiber affect body weight independently of an energy-restrictive diet? A systematic review and meta-analysis of randomized controlled trials. Am. J. Clin. Nutr. 2020;111:471–485. doi: 10.1093/ajcn/nqz292[]
  206. Miketinas D.C., Bray G.A., Beyl R.A., Ryan D.H., Sacks F.M., Champagne C.M. Fiber Intake Predicts Weight Loss and Dietary Adherence in Adults Consuming Calorie-Restricted Diets: The POUNDS Lost (Preventing Overweight Using Novel Dietary Strategies) Study. J. Nutr. 2019;149:1742–1748. doi: 10.1093/jn/nxz117[][]
  207. Wanders AJ, van den Borne JJ, de Graaf C, Hulshof T, Jonathan MC, Kristensen M, Mars M, Schols HA, Feskens EJ. Effects of dietary fibre on subjective appetite, energy intake and body weight: a systematic review of randomized controlled trials. Obes Rev. 2011 Sep;12(9):724-39. doi: 10.1111/j.1467-789X.2011.00895.x[][]
  208. Jane M, McKay J, Pal S. Effects of daily consumption of psyllium, oat bran and polyGlycopleX on obesity-related disease risk factors: A critical review. Nutrition. 2019 Jan;57:84-91. doi: 10.1016/j.nut.2018.05.036[]
  209. Pal S, Khossousi A, Binns C, Dhaliwal S, Ellis V. The effect of a fibre supplement compared to a healthy diet on body composition, lipids, glucose, insulin and other metabolic syndrome risk factors in overweight and obese individuals. Br J Nutr. 2011 Jan;105(1):90-100. doi: 10.1017/S0007114510003132[]
  210. Pal S, Ho S, Gahler RJ, Wood S. Effect on body weight and composition in overweight/obese Australian adults over 12 months consumption of two different types of fibre supplementation in a randomized trial. Nutr Metab (Lond). 2016 Nov 17;13:82. doi: 10.1186/s12986-016-0141-7[][]
  211. Ziai SA, Larijani B, Akhoondzadeh S, Fakhrzadeh H, Dastpak A, Bandarian F, Rezai A, Badi HN, Emami T. Psyllium decreased serum glucose and glycosylated hemoglobin significantly in diabetic outpatients. J Ethnopharmacol. 2005 Nov 14;102(2):202-7. doi: 10.1016/j.jep.2005.06.042[]
  212. Abutair AS, Naser IA, Hamed AT. Soluble fibers from psyllium improve glycemic response and body weight among diabetes type 2 patients (randomized control trial). Nutr J. 2016 Oct 12;15(1):86. doi: 10.1186/s12937-016-0207-4[]
  213. Anderson JW, Allgood LD, Lawrence A, Altringer LA, Jerdack GR, Hengehold DA, Morel JG. Cholesterol-lowering effects of psyllium intake adjunctive to diet therapy in men and women with hypercholesterolemia: meta-analysis of 8 controlled trials. Am J Clin Nutr. 2000 Feb;71(2):472-9. doi: 10.1093/ajcn/71.2.472[]
  214. Rahmani J, Miri A, Černevičiūtė R, Thompson J, de Souza NN, Sultana R, Kord Varkaneh H, Mousavi SM, Hekmatdoost A. Effects of cereal beta-glucan consumption on body weight, body mass index, waist circumference and total energy intake: A meta-analysis of randomized controlled trials. Complement Ther Med. 2019 Apr;43:131-139. doi: 10.1016/j.ctim.2019.01.018[]
  215. Queenan KM, Stewart ML, Smith KN, Thomas W, Fulcher RG, Slavin JL. Concentrated oat beta-glucan, a fermentable fiber, lowers serum cholesterol in hypercholesterolemic adults in a randomized controlled trial. Nutr J. 2007 Mar 26;6:6. doi: 10.1186/1475-2891-6-6[]
  216. Devaraj RD, Reddy CK, Xu B. Health-promoting effects of konjac glucomannan and its practical applications: A critical review. Int J Biol Macromol. 2019 Apr 1;126:273-281. doi: 10.1016/j.ijbiomac.2018.12.203[]
  217. Hozumi T, Yoshida M, Ishida Y, Mimoto H, Sawa J, Doi K, Kazumi T. Long-term effects of dietary fiber supplementation on serum glucose and lipoprotein levels in diabetic rats fed a high cholesterol diet. Endocr J. 1995 Apr;42(2):187-92. doi: 10.1507/endocrj.42.187[]
  218. Sood N, Baker WL, Coleman CI. Effect of glucomannan on plasma lipid and glucose concentrations, body weight, and blood pressure: systematic review and meta-analysis. Am J Clin Nutr. 2008 Oct;88(4):1167-75. doi: 10.1093/ajcn/88.4.1167[]
  219. Zalewski BM, Chmielewska A, Szajewska H. The effect of glucomannan on body weight in overweight or obese children and adults: a systematic review of randomized controlled trials. Nutrition. 2015 Mar;31(3):437-42.e2. doi: 10.1016/j.nut.2014.09.004[]
  220. Vanderbeek PB, Fasano C, O’Malley G, Hornstein J. Esophageal obstruction from a hygroscopic pharmacobezoar containing glucomannan. Clin Toxicol (Phila). 2007;45(1):80-2. doi: 10.1080/15563650601006215[]
  221. Pittler MH, Ernst E. Guar gum for body weight reduction: meta-analysis of randomized trials. Am J Med. 2001 Jun 15;110(9):724-30. doi: 10.1016/s0002-9343(01)00702-1[][]
  222. Dall’Alba V, Silva FM, Antonio JP, Steemburgo T, Royer CP, Almeida JC, Gross JL, Azevedo MJ. Improvement of the metabolic syndrome profile by soluble fibre – guar gum – in patients with type 2 diabetes: a randomised clinical trial. Br J Nutr. 2013 Nov 14;110(9):1601-10. doi: 10.1017/S0007114513001025[]
  223. Huang H, Zou Y, Chi H, Liao D. Lipid-Modifying Effects of Chitosan Supplementation in Humans: A Pooled Analysis with Trial Sequential Analysis. Mol Nutr Food Res. 2018 Apr;62(8):e1700842. doi: 10.1002/mnfr.201700842[][]
  224. Moraru C, Mincea MM, Frandes M, Timar B, Ostafe V. A Meta-Analysis on Randomised Controlled Clinical Trials Evaluating the Effect of the Dietary Supplement Chitosan on Weight Loss, Lipid Parameters and Blood Pressure. Medicina (Kaunas). 2018 Dec 12;54(6):109. doi: 10.3390/medicina54060109[][]
  225. Martínez-Abundis E, Méndez-Del Villar M, Pérez-Rubio KG, Zuñiga LY, Cortez-Navarrete M, Ramírez-Rodriguez A, González-Ortiz M. Novel nutraceutic therapies for the treatment of metabolic syndrome. World J Diabetes. 2016 Apr 10;7(7):142-52. doi: 10.4239/wjd.v7.i7.142[]
  226. Onakpoya I, Davies L, Posadzki P, Ernst E. The efficacy of Irvingia gabonensis supplementation in the management of overweight and obesity: a systematic review of randomized controlled trials. J Diet Suppl. 2013 Mar;10(1):29-38. doi: 10.3109/19390211.2012.760508[]
  227. Méndez-Del Villar M, González-Ortiz M, Martínez-Abundis E, Pérez-Rubio KG, Cortez-Navarrete M. Effect of Irvingia gabonensis on Metabolic Syndrome, Insulin Sensitivity, and Insulin Secretion. J Med Food. 2018 Jun;21(6):568-574. doi: 10.1089/jmf.2017.0092[]
  228. Oben JE, Ngondi JL, Momo CN, Agbor GA, Sobgui CS. The use of a Cissus quadrangularis/Irvingia gabonensis combination in the management of weight loss: a double-blind placebo-controlled study. Lipids Health Dis. 2008 Mar 31;7:12. doi: 10.1186/1476-511X-7-12[]
  229. Egras AM, Hamilton WR, Lenz TL, Monaghan MS. An evidence-based review of fat modifying supplemental weight loss products. J Obes. 2011;2011:297315. doi: 10.1155/2011/297315[]
  230. Bach Knudsen K.E., Laerke H.N., Hedemann M.S., Nielsen T.S., Ingerslev A.K., Gundelund Nielsen D.S., Kappel Theil P., Purup S., Hald S., Grethe Schioldan A., et al. Impact of Diet-Modulated Butyrate Production on Intestinal Barrier Function and Inflammation. Nutrients. 2018;10:1499. doi: 10.3390/nu10101499[][]
  231. Gogebakan O., Kohl A., Osterhoff M.A., van Baak M.A., Jebb S.A., Papadaki A., Alfredo Martinez J., Handjieva-Darlenska T., Hlavaty P., Weickert M.O., et al. Effects of weight loss and long-term weight maintenance with diets varying in protein and glycemic index on cardiovascular risk factors: The diet, obesity, and genes (DiOGenes) study: A randomized, controlled trial. Circulation. 2011;124:2829–2838. doi: 10.1161/CIRCULATIONAHA.111.033274[]
  232. Wong C., Harris P.J., Ferguson L.R. Potential Benefits of Dietary Fibre Intervention in Inflammatory Bowel Disease. Int. J. Mol. Sci. 2016;17:919. doi: 10.3390/ijms17060919[]
  233. Hamer H.M., Jonkers D.M., Bast A., Vanhoutvin S.A., Fischer M.A., Kodde A., Troost F.J., Venema K., Brummer R.J.M. Butyrate modulates oxidative stress in the colonic mucosa of healthy humans. Clin. Nutr. 2009;28:88–93. doi: 10.1016/j.clnu.2008.11.002[]
  234. Miller S.J., Batra A.K., Shearrer G.E., House B.T., Cook L.T., Pont S.J., Goran M.I., Davis J.N. Dietary fibre linked to decreased inflammation in overweight minority youth. Pediatr. Obes. 2016;11:33–39. doi: 10.1111/ijpo.12017[][]
  235. Gibson R., Eriksen R., Chambers E., Gao H., Aresu M., Heard A., Chan Q., Elliott P., Frost G. Intakes and Food Sources of Dietary Fibre and Their Associations with Measures of Body Composition and Inflammation in UK Adults: Cross-Sectional Analysis of the Airwave Health Monitoring Study. Nutrients. 2019;11:1839. doi: 10.3390/nu11081839[][][]
  236. Kabisch S., Meyer N.M.T., Honsek C., Gerbracht C., Dambeck U., Kemper M., Osterhoff M.A., Birkenfeld A.L., Arafat A.M., Weickert M.O., et al. Obesity Does Not Modulate the Glycometabolic Benefit of Insoluble Cereal Fibre in Subjects with Prediabetes-A Stratified Post Hoc Analysis of the Optimal Fibre Trial (OptiFiT) Nutrients. 2019;11:2726. doi: 10.3390/nu11112726[][]
  237. Nanri A, Kimura Y, Matsushita Y, Ohta M, Sato M, Mishima N, Sasaki S, Mizoue T. Dietary patterns and depressive symptoms among Japanese men and women. Eur J Clin Nutr. 2010 Aug;64(8):832-9. doi: 10.1038/ejcn.2010.86[]
  238. Jacka FN, Mykletun A, Berk M, Bjelland I, Tell GS. The association between habitual diet quality and the common mental disorders in community-dwelling adults: the Hordaland Health study. Psychosom Med. 2011 Jul-Aug;73(6):483-90. doi: 10.1097/PSY.0b013e318222831a[]
  239. Fatahi S, Matin SS, Sohouli MH, Găman MA, Raee P, Olang B, Kathirgamathamby V, Santos HO, Guimarães NS, Shidfar F. Association of dietary fiber and depression symptom: A systematic review and meta-analysis of observational studies. Complement Ther Med. 2021 Jan;56:102621. doi: 10.1016/j.ctim.2020.102621[]
  240. Swann O.G., Kilpatrick M., Breslin M., Oddy W.H. Dietary fiber and its associations with depression and inflammation. Nutr. Rev. 2020;78:394–411. doi: 10.1093/nutrit/nuz072[]
  241. Liu R.T., Walsh R.F.L., Sheehan A.E. Prebiotics and probiotics for depression and anxiety: A systematic review and meta-analysis of controlled clinical trials. Neurosci. Biobehav. Rev. 2019;102:13–23. doi: 10.1016/j.neubiorev.2019.03.023[]
  242. Opie R.S., O’Neil A., Jacka F.N., Pizzinga J., Itsiopoulos C. A modified Mediterranean dietary intervention for adults with major depression: Dietary protocol and feasibility data from the SMILES trial. Nutr. Neurosci. 2018;21:487–501. doi: 10.1080/1028415X.2017.1312841[]
  243. Food Sources of Dietary Fiber. https://www.dietaryguidelines.gov/resources/2020-2025-dietary-guidelines-online-materials/food-sources-select-nutrients/food-sources-fiber[]
  244. Dikeman CL, Fahey GC. Viscosity as related to dietary fiber: a review. Crit Rev Food Sci Nutr. 2006;46(8):649-63. doi: 10.1080/10408390500511862[][][]
  245. Anderson JW. All fibers are not created equal. J Med. 2009; 2: 87– 91.[]
  246. Anderson JW, Baird P, Davis RH Jr, Ferreri S, Knudtson M, Koraym A, Waters V, Williams CL. Health benefits of dietary fiber. Nutr Rev. 2009 Apr;67(4):188-205. doi: 10.1111/j.1753-4887.2009.00189.x[]
  247. Food and Drug Administration. Import Alert 33-15. https://www.accessdata.fda.gov/cms_ia/importalert_105.html[]
  248. Niness KR. Inulin and oligofructose: what are they? J Nutr. 1999 Jul;129(7 Suppl):1402S-6S. doi: 10.1093/jn/129.7.1402S.[]
  249. Gibson GR, Beatty ER, Wang X, Cummings JH. Selective stimulation of bifidobacteria in the human colon by oligofructose and inulin. Gastroenterology. 1995 Apr;108(4):975-82. doi: 10.1016/0016-5085(95)90192-2[]
  250. Kolida S, Tuohy K, Gibson GR. Prebiotic effects of inulin and oligofructose. Br J Nutr. 2002 May;87 Suppl 2:S193-7. doi: 10.1079/BJNBJN/2002537[]
  251. Cummings JH, Macfarlane GT. Gastrointestinal effects of prebiotics. Br J Nutr. 2002 May;87 Suppl 2:S145-51. doi: 10.1079/BJNBJN/2002530[]
  252. Lewis JH. Esophageal and small bowel obstruction from guar gum-containing “diet pills”: analysis of 26 cases reported to the Food and Drug Administration. Am J Gastroenterol. 1992 Oct;87(10):1424-8.[][]
  253. Schneider RP. Perdiem causes esophageal impaction and bezoars. South Med J. 1989 Nov;82(11):1449-50. doi: 10.1097/00007611-198911000-00032[][]
  254. Agha FP, Nostrant TT, Fiddian-Green RG. “Giant colonic bezoar:” a medication bezoar due to psyllium seed husks. Am J Gastroenterol. 1984 Apr;79(4):319-21.[][]
  255. Khalili B, Bardana EJ Jr, Yunginger JW. Psyllium-associated anaphylaxis and death: a case report and review of the literature. Ann Allergy Asthma Immunol. 2003 Dec;91(6):579-84. doi: 10.1016/S1081-1206(10)61538-4[][]
  256. McRorie Jr JW, Fahey Jr GC. Fiber supplements and clinically meaningful health benefits: Identifying the physiochemical characteristics of fiber that drive specific physiologic effects. Dietary Supplements in Health Promotion: CRC Press; 2015:172-217.[][][]
  257. Cooper SG, Tracey EJ. Small-bowel obstruction caused by oat-bran bezoar. N Engl J Med. 1989 Apr 27;320(17):1148-9. doi: 10.1056/NEJM198904273201717[]
  258. McClurken JB, Carp NZ. Bran-induced small-intestinal obstruction in a patient with no history of abdominal operation. Arch Surg. 1988 Jan;123(1):98-100. doi: 10.1001/archsurg.1988.01400250108021[]
  259. Rosario PG, Gerst PH, Prakash K, Albu E. Dentureless distention: oat bran bezoars cause obstruction. J Am Geriatr Soc. 1990 May;38(5):608. doi: 10.1111/j.1532-5415.1990.tb02419.x[]
  260. Miller DL, Miller PF, Dekker JJ. Small-Bowel Obstruction From Bran Cereal. JAMA. 1990;263(6):813–814. doi:10.1001/jama.1990.03440060053027[]
  261. Chandra R, Barron JL. Anaphylactic reaction to intravenous sinistrin (Inutest). Ann Clin Biochem. 2002 Jan;39(Pt 1):76. doi: 10.1258/0004563021901621[]
  262. Gay-Crosier F, Schreiber G, Hauser C. Anaphylaxis from inulin in vegetables and processed food. N Engl J Med. 2000 May 4;342(18):1372. doi: 10.1056/NEJM200005043421814[]
  263. Greger JL. Nondigestible carbohydrates and mineral bioavailability. J Nutr. 1999 Jul;129(7 Suppl):1434S-5S. doi: 10.1093/jn/129.7.1434S[]
  264. Bosscher D, Van Caillie-Bertrand M, Van Cauwenbergh R, Deelstra H. Availabilities of calcium, iron, and zinc from dairy infant formulas is affected by soluble dietary fibers and modified starch fractions. Nutrition. 2003 Jul-Aug;19(7-8):641-5. doi: 10.1016/s0899-9007(03)00063-7[]
  265. Scholz-Ahrens KE, Schrezenmeir J. Inulin, oligofructose and mineral metabolism – experimental data and mechanism. Br J Nutr. 2002 May;87 Suppl 2:S179-86. doi: 10.1079/BJNBJN/2002535[]
  266. Rock CL, Swendseid ME. Plasma beta-carotene response in humans after meals supplemented with dietary pectin. Am J Clin Nutr. 1992 Jan;55(1):96-9. doi: 10.1093/ajcn/55.1.96[]
  267. Riedl J, Linseisen J, Hoffmann J, Wolfram G. Some dietary fibers reduce the absorption of carotenoids in women. J Nutr. 1999 Dec;129(12):2170-6. doi: 10.1093/jn/129.12.2170[]
  268. Fugh-Berman A. Herb-drug interactions. Lancet. 2000 Jan 8;355(9198):134-8. doi: 10.1016/S0140-6736(99)06457-0. Erratum in: Lancet 2000 Mar 18;355(9208):1020.[]
  269. Richter WO, Jacob BG, Schwandt P. Interaction between fibre and lovastatin. Lancet. 1991 Sep 14;338(8768):706. doi: 10.1016/0140-6736(91)91291-2[]

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