amounts of different cereal types in the diet.
As scientists working in the field struggle to reconcile the consistent and strong evidence that whole grains reduce disease risk with the mixed intervention‐study evidence, it is clear that few studies offer both a clear idea of exactly which specific grains people were eating and in what amount, and whether the subjects were actually eating what they reported. One study using dietary biomarkers found major discrepancies between what people reported eating in an intervention study and what they plausibly ate based on an unbiased biomarker measurement of intake,(27) which raises questions about other studies where compliance was not rigorously cross‐checked. Another large study found that although average biomarker concentrations increased, individual variation suggested that a large proportion of subjects were likely not compliant, in spite of major efforts to ensure compliance using suitably packaged food and questionnaires.(28) In essence, the entire field has a cloud of uncertainty over it due to the fact that there are several different ways that intake of whole grains is reported, and we cannot confirm whether study volunteers are actually eating the products they are supposed to. Of some comfort is the observation that generally those studies where overall compliance has been judged to have been good based on biomarker measurements, have also been those where effects on risk markers have been observed.(29,30, 31,32)
These issues led to recommendations for reporting whole grain intake in both intervention and population‐based studies.(33) The proposed guidelines for reporting whole grains in foods and whole grain intake are as follows:
Report whole grain intake as grams of whole grain ingredients rather than absolute amounts of a particular food or poorly defined measures such as servings.
Note which definition is being used to define whole grain ingredients – for example, the AACCI or HealthGrain definition.
State the proportion of different cereal grains that have been provided or are consumed so that it is possible to separate effects of, for example, whole grain wheat or oats.
For intervention studies, describe the type of processing the intervention foods have undergone, including the structure of the flour (e.g., fine or coarse flour).
If bran or germ are of interest, clearly state what is added bran or germ versus bran and germ coming from whole grain flour.
Use an appropriate control group in intervention studies, such as an equivalent amount of similar foods based on refined flour. Avoid situations that may lead to the “addition” of intervention foods, rather than replacement of normal foods with intervention foods.
If possible, use a biomarker of whole grain intake to improve estimates of compliance or intake.
These recommendations aim to standardize reporting of whole grain intake and also allow greater nuances to be applied to our understanding of the effects of whole grains on health – in particular, around the different types of cereals and cereal processing. The requirement to report on food processing also increases the requirement for scientists running such trials to have some knowledge about food processing, or to include food scientists when designing and preparing for such studies.
5.3 How can we better measure whole grain content and intake in the future?
For there to be comparability, consistency and credibility among whole grain research and regulation, there need to be agreed standard measures for estimating the whole grain content of foods. New technologies may enable rapid measurement of whole grain content, and the development of such techniques should go hand in hand with efforts to define regulations around labeling whole grain foods. There also needs to be greater information availability and transparency around whole grain content in foods. For example, the reporting of whole grain content in national food composition databases would greatly enhance the ability to make better estimates of the whole grain content of different food categories. The Swedish Food Composition Database includes “whole grain” as one of the composition variables, reported on a percentage of dry‐weight basis, while the USDA has also recently included coding to capture foods that contain more than 50% whole grains (reported as “ounce equivalents”). The Oldways Whole Grains Council, with a large database of whole grain content of thousands of foods, can also provide publicly available data to researchers. Although these different approaches highlight the issues around standardization of reporting, it is positive that there are moves to make information about the whole grain content of foods readily available.
As part of efforts to improve reporting standards, scientific journals must clearly state that measurements of whole grain intake must meet recommended criteria. The recommended criteria, of course, need to be defined and agreed upon, and this only underlines the urgency of doing so.
Accurate estimation of whole grain intake is at the core of strong, science‐based recommendations for whole grains, and for there to be accurate estimation, there needs to be clear and reliable information about the whole grain content of foods that is consistently applied by scientists when doing research on whole grains. Further, clear information about whole grain foods will lead to standardized reporting of whole grain content on food packaging,(1) making it easier for consumers to compare products based on whole grain content.
5.4 References
1 1 Ross, A.B., van der Kamp, J.W., King, R., and et al. (2017). Perspective: A definition for whole‐grain food products – Recommendations from the Healthgrain Forum. Adv. Nutr., 8, 525–531.
2 2 Jones, A.R., Mann, K.D., Kuznes of SA, et al. (2017). The whole grain content of foods consumed in the UK. Food Chem., 214, 453–459.
3 3 Jacobs, D.R., Jr., Meyer, H.E., and Solvoll, K. (2001). Reduced mortality among whole grain bread eaters in men and women in the Norwegian County Study. Eur. J. Clin. Nutr., 55, 137–143.
4 4 Jacobs, D.R., Jr., Meyer, K.A., Kushi, L.H., et al. (1998). Whole‐grain intake may reduce the risk of ischemic heart disease death in postmenopausal women: The Iowa Women's Health Study. Am. J. Clin. Nutr., 68, 248–257.
5 5 Jacobs, J., Marquart, L., Slavin, J., et al. (1998). Whole‐grain intake and cancer: An expanded review and meta‐analysis. Nutr. Cancer, 30, 85–96.
6 6 Asp, N.‐G., and Bryngelsson, S. (2007). Health claims in the labelling and marketing of food products: The Swedish food sector's Code of Practice in a European perspective. Scandinavian Journal of Food & Nutrition, 51, 107–126.
7 7 Frank, J., Sundberg, B., Kamal‐Eldin, A., et al. (2004). Yeast‐leavened oat breads with high or low molecular weight beta‐glucan do not differ in their effects on blood concentrations of lipids, insulin, or glucose in humans. J. Nutr., 134, 1384–1388.
8 8 Ross, A.B., Pineau, N., Kochhar, S., et al. (2009). Validation of a FFQ for estimating whole‐grain cereal food intake. Br. J. Nutr., 102, 1547–1551.
9 9 Hollaender, P.L., Ross, A.B., and Kristensen, M. (2015). Whole‐grain and blood lipid changes in apparently healthy adults: A systematic review and meta‐analysis of randomized controlled studies. Am. J. Clin. Nutr., 102, 556–572.
10 10 Thane, C.W., Jones, A.R., Stephen, A.M., et al. (2007). Comparative whole‐grain intake of British adults in 1986–7 and 2000–1. Br. J. Nutr., 97, 987–992.
11 11 Bazzano, L.A., Song, Y., Bubes, V., et al. (2005). Dietary intake of whole and refined grain breakfast cereals and weight gain in men. Obes. Res., 13, 1952–1960.
12 12 Thane, C.W., Jones, A.R., Stephen, A.M., et al. (2005). Whole‐grain intake of British young people aged 4–18 years. Br. J. Nutr., 94, 825–831.
13 13 Lang, R., Thane, C.W., Bolton‐Smith, C., et al. (2003). Consumption of whole‐grain foods by British adults: Findings from further analysis of two national dietary surveys. Public Health Nutr., 6, 479–484.
14 14 O'Donovan, C.B., Devlin, N.F., Buffini, M., et al. (2019). Whole grain intakes