Oat β-glucans are water-soluble mixed-linkage β-glucans derived from the endosperm of oat kernels known for their dietary contribution as components of soluble fiber. Due to their property to lower serum total cholesterol and low-density lipoprotein cholesterol, and potentially reduce the risk of cardiovascular diseases, oat β-glucans have been assigned a qualified health claim by the European Food Safety Authority and the US Food and Drug Administration.

Oat products have been used for centuries for medicinal and cosmetic purposes; however, the specific role of β-glucan was not explored until the 20th century. β-glucans were first discovered in lichens, and shortly thereafter in barley. After joining Agriculture and Agri-Food Canada in 1969, Peter J Wood played an instrumental role in isolating and characterizing the structure and bioactive properties of oat β-glucan. A public interest in oat β-glucan arose after its cholesterol lowering effect was reported in 1984.

In 1997, after reviewing 33 clinical studies performed over the previous decades, the FDA approved the claim that intake of at least 3 g of β-glucan from oats per day "as part of a diet low in saturated fat and cholesterol, may reduce the risk of heart disease." This marked the first time a public health agency claimed dietary intervention can actually help prevent disease. This health claim mobilized a dietary movement as physicians and dietitians for the first time could recommend intake of a specific food to directly combat disease. Since then, oat consumption has continued to gain traction in disease prevention with noted effects on ischemic heart disease and stroke prevention, but also in other areas like BMI reduction, blood pressure lowering and highly corroborated evidence for reduced blood serum cholesterol.

Cereal β-glucans – including β-glucan from oat, barley and wheat – are linear polysaccharides joined by 1,3 and 1,4 carbon linkages. The majority of cereal β-glucan bonds consist of 3 or 4 beta-1,4 glycosidic bonds (trimers and tetramers) interconnected by 1,3 linkages. In β-glucan, these trimers and tetramers are known as cellotriosyl and cellotetraosyl. Oats and barley differ in the ratio of cellotriosyl to cellotetraosyl, and barley has more 1-4 linkages with a degree of polymerization higher than 4. In oats, β-glucan is found mainly in the endosperm of the oat kernel, especially in the outer layers of that endosperm (a marked difference from barley, which contains β-glucan uniformly throughout the endosperm).

Most oats contain 3–6% β-glucan by weight. Oats can be selectively bred based on favourable β-glucan levels. Often millers only process oat cultivars with at least 4% by weight β-glucan. Oat β-glucans are linear and linked at the 1,3 and 1,4 carbon sites.

Oat β-glucans can form into a random coil structure and flow with Newtonian behaviour until they reach a critical concentration at which point they become pseudoplastic. The gelling ability of oat β-glucan correlates to the percentage of trimers.

β-glucan extraction from oat can be difficult due to tendency of depolymerization – which often occurs in high pH. Thus β-glucan extraction is usually performed under a more neutral pH and generally at temperatures of 60-100 degrees Celsius. Usually β-glucan is solubilized in the extraction process with residual starch, which is then removed by hydrolysis with alpha-amylase. The residual solution usually contains coextracts of hemicelluloses and proteins which can then be separated through selective precipitation. Through wet milling, sieving, and solvent-extraction, oat beta-glucans can achieve up to 95% extraction purity.

In oats, β-glucan makes up the majority of the soluble fibre; however, oat β-glucans do become insoluble above a certain concentration. The total viscosity is determined by the level of solubility, the molecular weight, and the trimer-to-tetramer ratio. The lower the trimer-tetramer ratio, the higher the β-glucan viscosity in solution. A more viscous internal β-glucan solution generally leads to beneficial physiological effects – including a more pronounced hypoglycemic effect and lowered cholesterol levels, and a decrease in postprandial blood glucose levels.