Summary
Glycemic Index
Glycemic index of individual foods
In the past, carbohydrates were classified as simple or complex based on the number of simple sugars in the molecule. Carbohydrates composed of one or two simple sugars like fructose or sucrose (table sugar; a disaccharide composed of one molecule of glucose and one molecule of fructose) were labeled simple, while starchy foods were labeled complex because starch is composed of long chains of the simple sugar, glucose. Advice to eat less simple and more complex carbohydrates (i.e., polysaccharides) was based on the assumption that consuming starchy foods would lead to smaller increases in blood glucose than sugary foods (1). This assumption turned out to be too simplistic since the blood glucose (glycemic) response to complex carbohydrates has been found to vary considerably. The concept of glycemic index (GI) has thus been developed in order to rank dietary carbohydrates based on their overall effect on postprandial blood glucose concentration relative to a referent carbohydrate, generally pure glucose (2). The GI is meant to represent the relative quality of a carbohydrate-containing food. Foods containing carbohydrates that are easily digested, absorbed, and metabolized have a high GI (GI≥70 on the glucose scale), while low-GI foods (GI≤55 on the glucose scale) have slowly digestible carbohydrates that elicit a reduced postprandial glucose response. Intermediate-GI foods have a GI between 56 and 69 (3). The GI of selected carbohydrate-containing foods can be found in Table 1.
Measuring the glycemic index of foods
To determine the glycemic index (GI) of a food, healthy volunteers are typically given a test food that provides 50 grams (g) of carbohydrate and a control food (white, wheat bread or pure glucose) that provides the same amount of carbohydrate, on different days (4). Blood samples for the determination of glucose concentrations are taken prior to eating, and at regular intervals for a few hours after eating. The changes in blood glucose concentration over time are plotted as a curve. The GI is calculated as the incremental area under the glucose curve (iAUC) after the test food is eaten, divided by the corresponding iAUC after the control food (pure glucose) is eaten. The value is multiplied by 100 to represent a percentage of the control food (5):
GI = (iAUCtest food/iAUCglucose) x 100
For example, a boiled white potato has an average GI of 82 relative to glucose and 116 relative to white bread, which means that the blood glucose response to the carbohydrate in a baked potato is 82% of the blood glucose response to the same amount of carbohydrate in pure glucose and 116% of the blood glucose response to the same amount of carbohydrate in white bread. In contrast, cooked brown rice has an average GI of 50 relative to glucose and 69 relative to white bread. In the traditional system of classifying carbohydrates, both brown rice and potato would be classified as complex carbohydrates despite the difference in their effects on blood glucose concentrations.
While the GI should preferably be expressed relative to glucose, other reference foods (e.g., white bread) can be used for practical reasons as long as their preparation has been standardized and they have been calibrated against glucose (2). Additional recommendations have been suggested to improve the reliability of GI values for research, public health, and commercial application purposes (2, 6).
Physiological responses to high- versus low-glycemic index foods
By definition, the consumption of high-GI foods results in higher and more rapid increases in blood glucose concentrations than the consumption of low-GI foods. Rapid increases in blood glucose (resulting in hyperglycemia) are potent signals to the β-cells of the pancreas to increase insulin secretion (7). Over the next few hours, the increase in blood insulin concentration (hyperinsulinemia) induced by the consumption of high-GI foods may cause a sharp decrease in the concentration of glucose in blood (resulting in hypoglycemia). In contrast, the consumption of low-GI foods results in lower but more sustained increases in blood glucose and lower insulin demands on pancreatic β-cells (8).
Glycemic index of a mixed meal or diet
Many observational studies have examined the association between GI and risk of chronic disease, relying on published GI values of individual foods and using the following formula to calculate meal (or diet) GI (9):
Meal GI = [(GI x amount of available carbohydrate)Food A + (GI x amount of available carbohydrate)Food B +…]/ total amount of available carbohydrate
Yet, the use of published GI values of individual foods to estimate the average GI value of a meal or diet may be inappropriate because factors such as food variety, ripeness, processing, and cooking are known to modify GI values. In a study by Dodd et al., the estimation of meal GIs using published GI values of individual foods was overestimated by 22 to 50% compared to direct measures of meal GIs (9).
Besides the GI of individual foods, various food factors are known to influence the postprandial glucose and insulin responses to a carbohydrate-containing mixed diet. A recent cross-over, randomized trial in 14 subjects with type 2 diabetes mellitus examined the acute effects of four types of breakfasts with high- or low-GI and high- or low-fiber content on postprandial glucose concentrations. Plasma glucose was found to be significantly higher following consumption of a high-GI and low-fiber breakfast than following a low-GI and high-fiber breakfast. However, there was no significant difference in postprandial glycemic responses between high-GI and low-GI breakfasts of similar fiber content (10). In this study, meal GI values (derived from published data) failed to correctly predict postprandial glucose response, which appeared to be essentially influenced by the fiber content of meals. Since the amounts and types of carbohydrate, fat, protein, and other dietary factors in a mixed meal modify the glycemic impact of carbohydrate GI values, the GI of a mixed meal calculated using the above-mentioned formula is unlikely to accurately predict the postprandial glucose response to this meal (3). Moreover, the GI is a property of a given food carbohydrate such that it does not take into account individuals’ characteristics like ethnicity, metabolic status, or eating habits (e.g., the degree to which we masticate) which might, to a limited extent, also influence the glycemic response to a given carbohydrate-containing meal (11-14).
Using direct measures of meal GIs in future trials — rather than estimates derived from GI tables — would increase the accuracy and predictive value of the GI method (2, 6). In addition, in a recent meta-analysis of 28 studies examining the effect of low- versus high-GI diets on serum lipids, Goff et al. indicated that the mean GI of low-GI diets varied from 21 to 57 across studies, while the mean GI of high-GI diets ranged from 51 to 75 (15). Therefore, a stricter use of GI cutoff values may also be warranted to provide more reliable information about carbohydrate-containing foods.
Glycemic Load
The glycemic index (GI) compares the potential of foods containing the same amount of carbohydrate to raise blood glucose. However, the amount of carbohydrate contained in a food serving also affects blood glucose concentrations and insulin responses. For example, the mean GI of watermelon is 76, which is as high as the GI of a doughnut (see Table 1). Yet, one serving of watermelon provides 11 g of available carbohydrate, while a medium doughnut provides 23 g of available carbohydrate.
The concept of glycemic load (GL) was developed by scientists to simultaneously describe the quality (GI) and quantity of carbohydrate in a food serving, meal, or diet. The GL of a single food is calculated by multiplying the GI by the amount of carbohydrate in grams (g) provided by a food serving and then dividing the total by 100 (4):
GLFood = (GIFood x amount (g) of available carbohydrateFood per serving)/100
For a typical serving of a food, GL would be considered high with GL≥20, intermediate with GL of 11-19, and low with GL≤10. Using the above-mentioned example, despite similar GIs, one serving of watermelon has a GL of 8, while a medium-sized doughnut has a GL of 17. Dietary GL is the sum of the GLs for all foods consumed in the diet.
It should be noted that while healthy food choices generally include low-GI foods, this is not always the case. For example, intermediate-to-high-GI foods like parsnip, watermelon, banana, and pineapple, have low-to-intermediate GLs (see Table 1).
Disease Prevention
Type 2 diabetes mellitus
The consumption of high-GI and -GL diets for several years might result in higher postprandial blood glucose concentration and excessive insulin secretion. This might contribute to the loss of the insulin-secreting function of pancreatic β-cells and lead to irreversible type 2 diabetes mellitus (16).
A US ecologic study of national data from 1909 to 1997 found that the increased consumption of refined carbohydrates in the form of corn syrup, coupled with the declining intake of dietary fiber, has paralleled the increased prevalence of type 2 diabetes (17). In addition, high-GI and -GL diets have been associated with an increased risk of type 2 diabetes in several large prospective cohort studies. A recent updated analysis of three large US cohorts indicated consumption of foods with the highest versus lowest GI was associated with a risk of developing type 2 diabetes that was increased by 44% in the Nurses’ Health Study (NHS) I, 20% in the NHS II, and 30% in the Health Professionals Follow-up Study (HPFS). High-GL diets were associated with an increased risk of type 2 diabetes (+18%) only in the NHS I and in the pooled analysis of the three studies (+10%) (18). Additionally, the consumption of high-GI foods that are low in cereal fiber was associated with a 59% increase in diabetes risk compared to low-GI and high-cereal-fiber foods. High-GL and low-cereal-fiber diets were associated with a 47% increase in risk compared to low-GL and high-cereal-fiber diets. Moreover, obese participants who consumed foods with high-GI or -GL values had a risk of developing type 2 diabetes that was more than 10-fold greater than lean subjects consuming low-GI or -GL diets (18).
However, a number of prospective cohort studies have reported a lack of association between GI or GL and type 2 diabetes (19-24). The use of GI food classification tables based predominantly on Australian and American food products might be a source of GI value misassignment and partly explain null associations reported in many prospective studies of European and Asian cohorts.
Nevertheless, conclusions from several recent meta-analyses of prospective studies (including the above-mentioned studies) suggest that low-GI and -GL diets might have a modest but significant effect in the prevention of type 2 diabetes (18, 25, 26). Organizations like Diabetes UK (27) and the European Association for the Study of Diabetes (28) have included the use of diets of low GI/GL and high in dietary fiber and whole grains in their recommendations for diabetes prevention in high-risk individuals. The use of GI and GL is currently not implemented in US dietary guidelines (29).
Cardiovascular disease
Observational studies
Numerous observational studies have examined the relationship between dietary GI/GL and the incidence of cardiovascular events, especially coronary heart disease (CHD) and stroke. A meta-analysis of 14 prospective cohort studies (229,213 participants; mean follow-up of 11.5 years) found a 13% and 23% increased risk of cardiovascular disease (CVD) with high versus low dietary GI and GL, respectively (30). Three independent meta-analyses of prospective studies also reported that higher GI or GL was associated with increased risk of CHD in women but not in men (31-33). A recent analysis of the European Prospective Investigation into Cancer and Nutrition (EPIC) study in 20,275 Greek participants, followed for a median of 10.4 years, showed a significant increase in CHD incidence and mortality with high dietary GL specifically in those with high BMI (≥28 kg/m2) (34). This is in line with earlier findings in the Nurses’ Health Study (NHS) showing that a high dietary GL was associated with a doubling of the risk of CHD over 10 years in women with higher (≥23 kg/m2) vs. lower BMI (35). A similar finding was reported in a cohort of middle-aged Dutch women followed for nine years (36).
Additionally, high dietary GL (but not GI) was associated with a 19% increased risk of stroke in pooled analyses of prospective cohort studies (32, 37). A meta-analysis of seven prospective studies (242,132 participants; 3,255 stroke cases) found that dietary GL was associated with an overall 23% increase in risk of stroke and a specific 35% increase in risk of ischemic stroke; GL was not found to be related to hemorrhagic stroke (38).
Overall, observational studies have found that higher glycemic load diets are associated with increased risk of cardiovascular disease, especially in women and in those with higher BMIs.
GI/GL and cardiometabolic markers
The GI/GL of carbohydrate foods may modify cardiometabolic markers associated with CVD risk. A meta-analysis of 27 randomized controlled trials (published between 1991 and 2008) examining the effect of low-GI diets on serum lipid profile reported a significant reduction in total and LDL-cholesterol independent of weight loss (15). Yet, further analysis suggested significant reductions in serum lipids only with the consumption of low-GI diets with high fiber content. In a three-month, randomized controlled study, an increase in the values of flow-mediated dilation (FMD) of the brachial artery, a surrogate marker of vascular health, was observed following the consumption of a low- versus high-GI hypocaloric diet in obese subjects (39).
High dietary GLs have been associated with increased concentrations of markers of systemic inflammation, such as C-reactive protein (CRP), interleukin-6, and tumor necrosis factor-α (TNF-α) (40, 41). In a small 12-week dietary intervention study, the consumption of a Mediterranean-style, low-GL diet (without caloric restriction) significantly reduced waist circumference, insulin resistance, systolic blood pressure, as well as plasma fasting insulin, triglycerides, LDL-cholesterol, and TNF-α in women with metabolic syndrome. A reduction in the expression of the gene coding for 3-hydroxy-3-methylglutaryl (HMG)-CoA reductase, the rate-limiting enzyme in cholesterol synthesis, in blood cells further confirmed an effect for the low-GI diet on cholesterol homeostasis (42). Well-controlled, long-term intervention studies are needed to confirm the potential cardiometabolic benefits of low GI/GL diets in people at risk for CVD.
Cancer
Evidence that high-GI or -GL diets are related to cancer is inconsistent. A recent meta-analysis of 32 case-control studies and 20 prospective cohort studies found modest and nonsignificant increased risks of hormone-related cancers (breast, prostate, ovarian, and endometrial cancers) and digestive tract cancers (esophageal, gastric, pancreas, and liver cancers) with high versus low dietary GI and GL (43). A significant positive association was found only between a high dietary GI and colorectal cancer (43). Yet, earlier meta-analyses of prospective cohort studies failed to find a link between high-GI or -GL diets and colorectal cancer (44-46). Another recent meta-analysis of prospective studies suggested a borderline increase in breast cancer risk with high dietary GI and GL. Adjustment for confounding factors across studies found no modification of menopausal status or BMI on the association (47). Further investigations are needed to verify whether GI and GL are associated with various cancers.
Gallbladder disease
Results of two studies indicate GI and GL may be related to gallbladder disease: a higher dietary GI and GL were associated with significantly increased risks of developing gallstones in a cohort of men participating in the Health Professionals Follow-up Study (48) and in a cohort of women participating in the Nurses’ Health Study (49). However, more epidemiological research is needed to determine an association between dietary glycemic index/load and gallbladder disease.
Disease Treatment
Diabetes mellitus
Whether low-GI foods could improve overall blood glucose control in people with type 1 or type 2 diabetes mellitus has been investigated in a number of intervention studies. A meta-analysis of 19 randomized controlled trials that included 840 diabetic patients (191 with type 1 diabetes and 649 with type 2 diabetes) found that consumption of low-GI foods improved short-term and long-term control of blood glucose concentrations, reflected by significant decreases in fructosamine and glycated hemoglobin (HbA1c) levels (50). However, these results need to be cautiously interpreted because of significant heterogeneity among the included studies. The American Diabetes Association has rated poorly the current evidence supporting the substitution of low-GL foods for high-GL foods to improve glycemic control in adults with type 1 or type 2 diabetes (51, 52). Well-controlled studies are needed to further assess whether the use of low-GI/GL diets could significantly improve long-term glycemic control and the quality of life of subjects with diabetes.
A randomized controlled study in 92 pregnant women (20-32 weeks) diagnosed with gestational diabetes found no significant effects of a low-GI diet on maternal metabolic profile (e.g., blood concentrations of glucose, insulin, fructosamine, HbA1c; insulin resistance) and pregnancy outcomes (i.e., maternal weight gain and neonatal anthropometric measures) compared to a conventional high-fiber, moderate-GI diet (53). The low-GI diet consumed during the pregnancy also failed to improve maternal glucose tolerance, insulin sensitivity, and other cardiovascular risk factors, or maternal and infant anthropometric data in a three-month postpartum follow-up study of 55 of the mother-infant pairs (54). In addition, another trial in 139 pregnant women (12-20 weeks’ gestation) at high risk for gestational diabetes showed no statistical differences regarding the diagnosis of gestational diabetes during the second and third trimester of pregnancy, the requirement for insulin therapy, and pregnancy outcomes and neonatal anthropometry whether women followed a low-GI diet or a high-fiber, moderate-GI diet (55). At present, there is no evidence that a low-GI diet provides benefits beyond those of a healthy, moderate-GI diet in women at high risk or affected by gestational diabetes.
Obesity
Obesity is often associated with metabolic disorders, such as hyperglycemia, insulin resistance, dyslipidemia, and hypertension, which place individuals at increased risk for type 2 diabetes mellitus, cardiovascular disease, and early death (56, 57). Traditionally, weight-loss strategies have included energy-restricted, low-fat, high-carbohydrate diets with >50% of calories from carbohydrates, ≤30% from fat, and the remainder from protein. However, a recent meta-analysis of randomized controlled intervention studies (≥6 months’ duration) has reported that low- or moderate-carbohydrate diets (4%-45% carbohydrate) and low-fat diets (10%-30% fat) were equally effective at reducing body weight and waist circumference in overweight or obese subjects (58).
Low-GI/GL diet versus moderate-GI/GL, low-fat diet
Several dietary intervention studies have examined how low-GI/GL diets compared with conventional low-fat diets to promote weight loss. Lowering the GI of conventional energy-restricted, low-fat diets was proven to be more effective to reduce postpartum body weight and waist and hip circumferences and prevent type 2 diabetes mellitus in women with prior gestational diabetes mellitus (59). In a six-month dietary intervention study in 73 obese adults, no differences in weight loss were reported in subjects following either a low-GL diet (40% carbohydrate and 35% fat) or a low-fat diet (55% carbohydrate and 20% fat). Yet, the consumption of a low-GL diet increased HDL-cholesterol and decreased triglyceride concentrations significantly more than the low-fat diet, but LDL-cholesterol concentration was significantly more reduced with the low-fat than low-GI diet (60).
A one-year randomized controlled study of 202 individuals with a body mass index (BMI) ≥28 and at least another metabolic disorder compared the effect of two dietary counseling-based interventions advocating either for a low-GL diet (30%-35% of calories from low-GI carbohydrates) or a low-fat diet (<30% of calories from fat) (61). Weight loss with each diet was equivalent (~4 kg). Both interventions similarly reduced triglycerides, C-reactive protein (CRP), and fasting insulin, and increased HDL-cholesterol. Yet, the reduction in waist and hip circumferences was greater with the low-fat diet, while blood pressure was significantly more reduced with the low-GL diet (61). In the GLYNDIET study, a six-month randomized dietary intervention trial, the comparison of two moderate-carbohydrate diets (42% of calories from carbohydrates) with different GIs (GI of 34 or GI of 62) and a low-fat diet (30% of calories from fat; GI of 65) on weight loss indicated that the low-GI diet reduced body weight more effectively than the low-fat diet. Additionally, the low-GI diet improved fasting insulin concentration, β-cell function, and insulin resistance better than the low-fat diet. None of the diets modulated hunger or satiety or affected biomarkers of endothelial function or inflammation. Finally, no significant differences were observed in low- compared to high-GL diets regarding weight loss and insulin metabolism (62).
Low-GI/GL diet versus high-GI/GL diet
In a meta-analysis of 14 randomized controlled trials published between 2005 and 2011, neither high- nor low-GI/GL dietary interventions conducted for 6 to 17 months had any significant effect on body weight and waist circumference in a total of 2,344 overweight and obese subjects (63). Low-GI/GL diets were found to significantly reduce C-reactive protein and fasting insulin but had no effect on blood lipid profile, fasting glucose concentration, or HbA1c concentration compared to high-GI/GL diets.
It has been suggested that the consumption of low-GI foods delayed the return of hunger, decreased subsequent food intake, and increased satiety when compared to high-GI foods (64). The effect of isocaloric low- and high-GI test meals on the activity of brain regions controlling appetite and eating behavior was evaluated in a small randomized, blinded, cross-over study in 12 overweight or obese men (65). During the postprandial period, blood glucose and insulin rose higher after the high-GI meal than after the low-GI meal. In addition, in response to the excess insulin secretion, blood glucose dropped below fasting concentrations three to five hours after high-GI meal consumption. Cerebral blood flow was significantly higher four hours after ingestion of the high-GI meal (compared to a low-GI meal) in a specific region of the striatum (right nucleus accumbens) associated with food intake reward and craving. If the data suggested that consuming low- rather than high-GI foods may help restrain overeating and protect against weight gain, this has not yet been confirmed in long-term randomized controlled trials. In the recent multicenter, randomized controlled Diet, Obesity, and Genes (DiOGenes) study in 256 overweight and obese individuals who lost ≥8% of body weight following an eight-week calorie-restricted diet, consumption of ad libitum diets with different protein and GI content for 12 months showed that only high-protein diets — regardless of their GI — could mitigate weight regain (66). However, the dietary interventions only achieved a modest difference in GI (~5 units) between high- and low-GI diets such that the effect of GI in weight maintenance remained unknown.
Lifestyle modification programs do not currently include the reduction of calories from carbohydrate as an alternative to standard prescription of low-fat diets, nor do they suggest the use of GI/GL as a guide to healthier dietary choices (67).
Lowering Dietary Glycemic Load
Some strategies for lowering dietary GL include:
• Increasing the consumption of whole grains, nuts, legumes, fruit, and non-starchy vegetables
• Decreasing the consumption of starchy, moderate- and high-GI foods like potatoes, white rice, and white bread
• Decreasing the consumption of sugary foods like cookies, cakes, candy, and soft drinks
Table 1 includes GI and GL values of selected foods relative to pure glucose (68). Foods are ranked in descending order of their GI values, with high-GI foods (GI≥70) at the top and foods with low-GI values (≤55) at the bottom of the table. To look up the GI values for other foods, visit the University of Sydney’s GI website.
Table 1. GI and GL Values for Selected Foods
Food
GI
(Glucose=100)
Serving Size
Carbohydrate* per Serving (g)
GL per Serving
Russet potato, baked
111
1 medium
30
33
Potato, white, boiled (average)
82
1 medium
30
25
Puffed rice cakes
82
3 cakes
21
17
Cornflakes
79
1 cup
26
20
Jelly beans
78
1 oz
28
22
Doughnut
76
1 medium
23
17
Watermelon
76
1 cup
11
8
Soda crackers
74
4 crackers
17
12
Bread, white-wheat flour
71
1 large slice
14
10
Pancake
67
6″ diameter
58
39
Rice, white, boiled
66
1 cup
53
35
Table sugar (sucrose)
63
2 tsp
10
6
Dates, dried
62
2 oz
40
25
Spaghetti, white, boiled (20 min)
58
1 cup
44
25
Honey, pure
58
1 Tbsp
17
10
Pineapple, raw
58
½ cup
19
11
Banana, raw
55
1 cup
24
13
Maple syrup, Canadian
54
1 Tbsp
14
7
Parsnips, peeled, boiled
52
½ cup
10
5
Rice, brown, boiled
50
1 cup
42
20
Spaghetti, white, boiled (average)
46
1 cup
44
20
Whole-grain pumpernickel bread
46
1 large slice
12
5
All-Bran™ cereal
45
1 cup
21
10
Spaghetti, whole-meal, boiled
32
1 cup
37
14
Orange, raw
42
1 medium
11
5
Apple, raw
39
1 medium
15
6
Pear, raw
38
1 medium
11
4
Skim milk
33
8 fl oz
13
4
Carrots, boiled
33
½ cup
4
1
Lentils, dried, boiled
29
1 cup
24
7
Kidney beans, dried, boiled
28
1 cup
29
8
Pearled barley, boiled
28
1 cup
38
11
Cashews
25
1 oz
9
2
Peanuts
18
1 oz
6
1
*Amount of available carbohydrates in a food serving that excludes indigestible carbohydrates, i.e., dietary fiber.
Authors and Reviewers
Originally written in 2003 by:
Jane Higdon, Ph.D.
Linus Pauling Institute
Oregon State University
Updated in December 2005 by:
Jane Higdon, Ph.D.
Linus Pauling Institute
Oregon State University
Updated in February 2009 by:
Victoria J. Drake, Ph.D.
Linus Pauling Institute
Oregon State University
Updated in March 2016 by:
Barbara Delage, Ph.D.
Linus Pauling Institute
Oregon State University
Reviewed in March 2016 by:
Simin Liu, M.D., M.S., M.P.H., Sc.D.
Professor of Epidemiology, Professor of Medicine
Brown University
Copyright 2003-2022 Linus Pauling Institute
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