Oats and health
A large body of clinical evidence suggests that the consumption of 3 g or more per d of β-glucan from oats or barley, as part of a diet low in saturated fat and cholesterol, may reduce the risk of CHD( 1 , Reference Thies, Masson and Boffetta 2 ). Examination of these and other grains indicates that oats are a good source of soluble dietary fibre in the form of β-glucan, a key component responsible for the health benefits of oats. The unique physico-chemical properties of oats, relative to other grains, and physiological responses to oat consumption contribute to their spectrum of demonstrated health benefits and possibly other health attributes still under evaluation. Many of these benefits, such as those associated with a reduced risk of CVD, are codified in health claims by several regulatory agencies, such as the Food and Drug Administration in the USA, and by the European Food Safety Authority in Europe( Reference Stewart, Kennedy and Pavel 3 , 4 ). Table 1 summarises the key findings from each article in this supplement.
Table 1 Key messages on the value of and research on oats
Oats (Avena sativa L.) are a cereal grain commodity well known for their health benefits. Despite this, oat production is declining and the challenges associated are ensuring that the future of oats is little known to the public and scientific community. The world's sequencing databases hold about 80 000 accessions of cultivated oat species and preserve about 20 000 accessions of wild Avena species( Reference Badaeva, Shelukhina and Diederichsen 5 ). Extensive knowledge of this diversity of cultivars is critical to ensuring that oats can be grown in changing environments, for example, with respect to climate change and water availability, and to ensuring resources for crop improvement and promoting the attributes of oats that provide health benefits.
Although the epidemiological data are not compelling, the spectrum of clinical studies supports the health benefits and subsequent health claims. These studies demonstrate the direct relationship between oat consumption and reduced risk of several diseases, including CVD, diabetes and possibly some cancers. Surprisingly, no cohort studies that have evaluated the effects of regular consumption of oats specifically either on CVD or diabetes and few studies that have included cancer as an outcome variable have been identified( Reference Boffetta, Thies and Kris-Etherton 6 ). The results of most of the few cohort studies suggest a weak protective effect of high intake of oats on cancer risk (relative risks in the order of 0·9). Overall, very few epidemiological studies have been performed on the effects of oat consumption: there is an urgent need for such studies. An assessment of a Nordic population with regard to whole-grain or oat consumption relative to overall mortality indicates that oatmeal consumption may improve longevity( Reference Olsen, Egebert and Halkjær 7 ). However, these observations deserve additional investigation, particularly among various population groups living in other geographical regions.
β-Glucan, a unique linear carbohydrate in the starchy endosperm that is common to oat grain, is one of the many components that contribute to the health benefits of this cereal. As a form of soluble fibre, the physiological effects on lipid and carbohydrate metabolism may reflect the rheological properties in the gastrointestinal tract( Reference Wolever, Tosh and Gibbs 8 , Reference Tosh 9 ). The concentration of β-glucan is variable, depending on cultivar, growing conditions and processing conditions, storage and purification protocol. The molecular weight (MW) of β-glucan is influenced by cultivars and even by the purification technique( Reference Wang and Ellis 10 ). In fact, the MW and solubility of β-glucan are critical to the ability to form viscous material that may underlie many of its purported health benefits. In fact, recent clinical studies have shown that satiety ratings are increased significantly up to 4 h after oatmeal consumption, which is correlated with increased viscosity, content and MW of β-glucan( Reference van Klinken, Chu and Bordenave 11 – Reference Rebello, Johnson and O'Shea 13 ). Despite these apparent correlations, in most clinical studies, the MW of β-glucan was not controlled for or dissimilar methods were used. It is therefore essential that methods be standardised between research laboratories, enabling accurate determination of the MW and viscosity of β-glucan.
The majority of clinical trials that have assessed the potential health impact of oats indicate that fasting plasma total and LDL-cholesterol, blood pressure and homocysteine levels – all risk factors for CVD – may be significantly reduced. As Thies et al. ( Reference Thies, Masson and Boffetta 2 ) confirmed in their assessment, long-term dietary intake of oats or oat bran has a beneficial effect on blood cholesterol. In addition, evidence from many studies indicates that fasting blood glucose, a risk factor for CVD and associated with diabetes, remains unchanged (albeit postprandial glycaemia may be reduced), whereas oat consumption does not appear to affect insulin sensitivity( Reference Thies, Masson and Boffetta 2 ).
There is a plethora of gut-health pathologies, notably Crohn's disease, coeliac disease, ulcerative colitis, inflammatory bowel disease, irritable bowel syndrome and colorectal cancer. A systematic review of the literature on clinical trials relative to these conditions and oat consumption indicates the absence of any major effect on the course of colorectal cancer, ulcerative colitis (a type of irritable bowel disease) or irritable bowel syndrome( Reference Thies, Masson and Boffetta 14 ), although yet to be established benefits may become evident during long-term consumption of oats. Importantly, however, the data indicate that oat consumption was well tolerated by most of the study subjects. Oats significantly increased stool weight and decreased constipation, although effects did not seem specific to oats and are general to whole grains( Reference Thies, Masson and Boffetta 14 ). Importantly, oat consumption is well tolerated by most coeliac disease patients, and therefore uncontaminated oats may provide an opportunity to consume sufficient whole grains for this population( Reference Thies, Masson and Boffetta 14 ). Some of the mechanisms that may improve clinical outcomes were identified in animal models and human studies for these conditions( Reference Sengupta, Muir and Gibson 15 , Reference Slavin, Martini and Jacobs 16 ). However, well-designed clinical studies investigating the impact of long-term oat consumption on bowel disorders are needed.
Our understanding of the role of the gut microbiota in the health and disease spectrum has increased exponentially over recent decades. The impact of whole grains, including oats, and their components (such as resistant starch, β-glucan, lignins and lipids) may modulate gut microflora, which alters the array of cellular signalling processes that contribute to improved health( Reference Rose 17 ). In vitro and clinical studies indicate that different whole grains, such as oats and barley, have diverse effects on the gut microflora. These effects may reflect unique grain compositions, such as avenanthramides and related substances in oats, that contribute to variations in proximal and distal fermentation products (SCFA), alterations in microenvironment pH, changes in nutrient absorption (decreased cholesterol uptake and increased absorption of some minerals and vitamins), or the synthesis of vitamins (folic acid and vitamin K). The potential impact of the gut microbiome on heart health( Reference Wong, Esfahani and Singh 18 ), immune function( Reference Purchiaroni, Tortora and Gabrielli 19 ), diabetes( Reference Cani, Osto and Geurts 20 ) and obesity( Reference Arora and Sharma 21 ) provides tremendous opportunities for future applications for oats. In addition, increased production of SCFA is correlated with enhanced satiety( Reference Darzi, Frost and Robertson 22 ).
Satiety
Epidemiological evidence suggests that regular consumption of whole-grain foods, such as oats, is correlated with lower BMI( Reference Giacco, Della Pepa and Luongo 23 ). Whole-grain foods are thought to be satiating due to their high fibre content relative to other grains, although a recent systematic review has suggested otherwise( Reference Clark and Slavin 24 ). As has been mentioned earlier, oats are high in β-glucan, which is thought to play an essential role in the elicitation of this acute satiety response( Reference Lyly, Liukkonen and Salmenkallio-Marttila 25 ). However, clinical studies with oat-based foods or beverages provide inconsistent results – for example, in a study, consumption of bars containing up to 0·9 g of β-glucan from barley was found to not demonstrate enhanced satiety compared with that of an isoenergetic control bar( Reference Peters, Boers and Haddeman 26 ). In a study with extruded muesli containing 4 g of β-glucan per serving, no differences were found in short-term satiety compared with cornflakes, which are low in fibre( Reference Hlebowicz, Darwiche and Björgell 27 ). Similarly, consumption of bread containing oats or wheat fibre and that of low-fibre control bread were found to not differ in perceived satiety( Reference Weickert, Spranger and Holst 28 ).
Studies that investigated oats or β-glucan in a beverage, soup or cooked oatmeal seem more consistent in their outcomes related to hunger and fullness, i.e. measures of satiety response. These observations suggest that hydration of the oat fibres may be essential for their satiety response. For example, Juvonen et al. ( Reference Juvonen, Purhonen and Salomenkallio-Marttila 29 ) found that an isoenergetic oat-bran-based beverage with high viscosity elicited enhanced satiety responses compared with a β-glucanase-treated low-viscosity oat-bran beverage. Lyly et al. ( Reference Lyly, Ohls and Lahteenmaki 30 ) demonstrated enhanced satiety of a β-glucan-containing beverage compared with fibre-free controls. In a small study with nineteen participants, a trend in reduced hunger ratings was observed after consumption of cooked oatmeal than after the consumption of a soluble-fibre control cereal( Reference Saltzman, Moriguti and Das 31 ). Also, in a study among school-aged children, a small serving of 43 g of oatmeal was found to significantly decrease hunger ratings compared with an isoenergetic ready-to-eat cereal( Reference Mahoney, Taylor and Kanarek 32 ).
Recently, three independent studies with larger groups of healthy adult volunteers have provided stronger, consistent evidence on the satiating effects of oatmeal. In one study, cooked classic oatmeal (66 g) was compared with isoenergetic ready-to-eat cereal, and visual analogue scale (of hunger) data were obtained from 0 to 240 min after consumption of the test meal. Results indicated significantly increased satiety from 2 to 4 h( Reference Rebello, Johnson and O'Shea 13 ). These findings were corroborated in a similarly designed study that compared cooked oatmeal with the same ready-to-eat cereal( Reference Rebello, Johnson and Martin 12 ), in which the oatmeal-fed volunteers consumed significantly less of a meal that was offered 4 h later. Therefore, a composite of these studies indicates that cooked oatmeal delivers satiating benefits, although a large intervention or clinical study is yet to be undertaken.
In an in vitro study using a model that simulated gastric digestion, the underlying viscosity exerted by β-glucan appeared to be a key factor in this satiating response v. that of the starch content of the oatmeal. Furthermore, cooked oatmeal, but not ready-to-eat cereal, exhibited enhanced gastric gelling in the in vitro model, suggesting that this property may contribute to delayed gastric emptying and subsequent enhanced satiety in vivo ( Reference van Klinken, Chu and Bordenave 11 ).
Agriculture, processing and policy
Maximisation of the physiological benefits of oat consumption requires better understanding and appreciation of agricultural practices and challenges and processing technologies. The cultivation and production of oats involve understanding phenotypic and genetic variations associated with the climate and climate changes, environmental or abiotic stresses, plant pathogens and diseases, and agricultural production issues, wherever the oat crop is grown( Reference Mahoney, Taylor and Kanarek 32 ). Each of these variables affects the composition and nutritive value of the grain. The growing agriculture genebank for oat cultivars indicates that there are still numerous research opportunities to ensure the availability of oats to help meeting the food needs and health demands of a growing global population.
Regardless of the source of the oat grain or kernel, some elements of processing are essential to keep the unique nutritional properties (such as lipids, fibre and β-glucan) physiologically available( Reference Stewart and McDougall 33 ). For example, the extent of oat milling depends on many variables, such as plant genetics, agricultural practices, chemical composition, storage and handling conditions. Grading oats for quality before milling is critical for their ultimate conversion into an array of wholesome food ingredients and products.
Translation of the basic and applied research to global food policies to address contemporary and future health concerns and food supply challenges is essential if oats are to be seen as a priority crop( Reference Stewart, Kennedy and Pavel 3 ). Recent reports from the WHO and FAO indicate a significant intersection between tackling poor nutrition and environmental challenges( 35 , 36 ). The global double public burden of undernutrition and obesity involves a spectrum of challenges for future health. The future of food and farming requires greater research into global crops, such as oats( 37 ), and the concept of sustainable diets( 38 ) for a healthy future. This research, in turn, drives food policy, health claims and consumer-friendly product labelling, which are intended to improve consumer health outcomes through better consumer education, a broader selection of healthy foods, and improved food supply. Although there are variations in dietary guidelines between countries, there is a common recommendation for consumers to increase their consumption of whole grains, including oats( Reference Painter, Rah and Lee 39 ). These publications, and health-orientated and socially conscious consumers, can provide a basis for advocating for agricultural policy for crop improvements and stabilised production. These dynamics also drive regulatory policy and future food products based on clinical evidence and consumer opinion. Current and future agricultural and nutrition policies provide synergistic opportunities that support sustainable agriculture and improved public health.
Conclusion
Oats are cereal grains that are commonly accepted by consumers globally. They appear in a wide range of food products, including low-energy beverages, medical foods, baked goods and granolas. In a time of increasing global food-security issues and dual health burdens of overweight and underweight, oats could be part of inexpensive, nutritious products for the future.
Global dietary guidelines recommend an increased consumption of whole grains for improved health. Oats are a unique type of beneficial whole grains and should be promoted for their evidence-based impact on the risk of CVD and, if the evidence bears out, potentially gut health and some forms of cancers. Effects of acute consumption of oats on satiety and glucose management are more evident in contrast to those of long-term consumption. These arena areas are crucial basic and applied research opportunities in human health and nutrition. The wide-ranging benefits of oats justify the expansion of agricultural practices and cultivar assessments intended to sustain oats in stress-laden environments and in the face of common pathogens and to explore processing technologies that ensure that the nutritional qualities and health attributes of oats are maintained and that oats, a global commodity, remain available to a growing population.
Acknowledgements
R. C. received an honorarium from Quaker Oats Company (a subsidiary of PepsiCo, Inc.) for attending the workshop in May 2012 to discuss the content of the supplement and to function as managing editor of the series of manuscripts. B. J.-W. v. K. is an employee of PepsiCo, Inc. The views expressed in this article are those of the author(s) and do not necessarily reflect the position or policy of PepsiCo, Inc. This article was jointly authored by R. C. and B. J.-W. v. K.
This paper was published as part of a supplement to British Journal of Nutrition, publication of which was supported by an unrestricted educational grant from Quaker Oats Co. (a subsidiary of PepsiCo Inc.). The papers included in this supplement were invited by the Guest Editor and have undergone the standard journal formal review process. They may be cited.
The Guest Editor to this supplement is Roger Clemens. The Guest Editor declares no conflict of interest.
