Terri Grassby

Effect of mastication on lipid bioaccessibility of almonds in a randomized human study and its implications for digestion kinetics, metabolizable energy, and postprandial lipemia

Background: The particle size and structure of masticated almonds have a significant impact on nutrient release (bioaccessibility) and digestion kinetics. Objectives: The goals of this study were to quantify the effects of mastication on the bioaccessibility of intracellular lipid of almond tissue and examine microstructural characteristics of masticated almonds. Design: In a randomized, subject-blind, crossover trial, 17 healthy subjects chewed natural almonds (NAs) or roasted almonds (RAs) in 4 separate mastication sessions. Particle size distributions (PSDs) of the expectorated boluses were measured by using mechanical sieving and laser diffraction (primary outcome). The microstructure of masticated almonds, including the structural integrity of the cell walls (i.e., dietary fiber), was examined with microscopy. Lipid bioaccessibility was predicted by using a theoretical model, based on almond particle size and cell dimensions, and then compared with empirically derived release data. Results: Intersubject variations (n = 15; 2 subjects withdrew) in PSDs of both NA and RA samples were small (e.g., laser diffraction; CV: 12% and 9%, respectively). Significant differences in PSDs were found between these 2 almond forms (P < 0.05). A small proportion of lipid was released from ruptured cells on fractured surfaces of masticated particles, as predicted by using the mathematical model (8.5% and 11.3% for NAs and RAs, respectively). This low percentage of lipid bioaccessibility is attributable to the high proportion (35–40%) of large particles (>500 μm) in masticated almonds. Microstructural examination of the almonds indicated that most intracellular lipid remained undisturbed in intact cells after mastication. No adverse events were recorded. Conclusions: Following mastication, most of the almond cells remained intact with lipid encapsulated by cell walls. Thus, most of the lipid in masticated almonds is not immediately bioaccessible and remains unavailable for early stages of digestion. The lipid encapsulation mechanism provides a convincing explanation for why almonds have a low metabolizable energy content and an attenuated impact on postprandial lipemia. This trial was registered at isrctn.org as ISRCTN58438021.

Role of polysaccharides in food, digestion, and health

ABSTRACT Polysaccharides derived from plant foods are major components of the human diet, with limited contributions of related components from fungal and algal sources. In particular, starch and other storage carbohydrates are the major sources of energy in all diets, while cell wall polysaccharides are the major components of dietary fiber. We review the role of these components in the human diet, including their structure and distribution, their modification during food processing and effects on functional properties, their behavior in the gastrointestinal tract, and their contribution to healthy diets.

Manipulation of starch bioaccessibility in wheat endosperm to regulate starch digestion, postprandial glycemia, insulinemia, and gut hormone responses: a randomized controlled trial in healthy ileostomy participants

Background: Cereal crops, particularly wheat, are a major dietary source of starch, and the bioaccessibility of starch has implications for postprandial glycemia. The structure and properties of plant foods have been identified as critical factors in influencing nutrient bioaccessibility; however, the physical and biochemical disassembly of cereal food during digestion has not been widely studied. Objectives: The aims of this study were to compare the effects of 2 porridge meals prepared from wheat endosperm with different degrees of starch bioaccessibility on postprandial metabolism (e.g., glycemia) and to gain insight into the structural and biochemical breakdown of the test meals during gastroileal transit. Design: A randomized crossover trial in 9 healthy ileostomy participants was designed to compare the effects of 55 g starch, provided as coarse (2-mm particles) or smooth (<0.2-mm particles) wheat porridge, on postprandial changes in blood glucose, insulin, C-peptide, lipids, and gut hormones and on the resistant starch (RS) content of ileal effluent. Undigested food in the ileal output was examined microscopically to identify cell walls and encapsulated starch. Results: Blood glucose, insulin, C-peptide, and glucose-dependent insulinotropic polypeptide concentrations were significantly lower (i.e., 33%, 43%, 40%, and 50% lower 120-min incremental AUC, respectively) after consumption of the coarse porridge than after the smooth porridge (P < 0.01). In vitro, starch digestion was slower in the coarse porridge than in the smooth porridge (33% less starch digested at 90 min, P < 0.05, paired t test). In vivo, the structural integrity of coarse particles (∼2 mm) of wheat endosperm was retained during gastroileal transit. Microscopic examination revealed a progressive loss of starch from the periphery toward the particle core. The structure of the test meal had no effect on the amount or pattern of RS output. Conclusion: The structural integrity of wheat endosperm is largely retained during gastroileal digestion and has a primary role in influencing the rate of starch amylolysis and, consequently, postprandial metabolism. This trial was registered at isrctn.org as ISRCTN40517475.

A third mode of surface-associated growth: immobilization of Salmonella enterica serovar Typhimurium modulates the RpoS-directed transcriptional programme

Although the growth of bacteria has been studied for more than a century, it is only in recent decades that surface-associated growth has received attention. In addition to the well-characterized biofilm and swarming lifestyles, bacteria can also develop as micro-colonies supported by structured environments in both food products and the GI tract. This immobilized mode of growth has not been widely studied. To develop our understanding of the effects of immobilization upon a food-borne bacterial pathogen, we used the IFR Gel Cassette model. The transcriptional programme and metabolomic profile of Salmonella enterica serovar Typhimurium ST4/74 were compared during planktonic and immobilized growth, and a number of immobilization-specific characteristics were identified. Immobilized S.Typhimurium did not express motility and chemotaxis genes, and electron microscopy revealed the absence of flagella. The expression of RpoS-dependent genes and the level of RpoS protein were increased in immobilized bacteria, compared with planktonic growth. Immobilized growth prevented the induction of SPI1, SPI4 and SPI5 gene expression, likely mediated by the FliZ transcriptional regulator. Using an epithelial cell-based assay, we showed that immobilized S.Typhimurium was significantly less invasive than planktonic bacteria, and we suggest that S.Typhimurium grown in immobilized environments are less virulent than planktonic bacteria. Our findings identify immobilization as a third type of surface-associated growth that is distinct from the biofilm and swarming lifestyles of Salmonella.

In vitro and in vivo modeling of lipid bioaccessibility and digestion from almond muffins: The importance of the cell-wall barrier mechanism

Highlights • We investigated the mechanisms of lipid bioaccessibility from almond muffins.• An in vitro dynamic gastric model was used to simulate human digestion.• A pilot ileostomy study was performed to define the rate of lipid release.• Microstructural analysis proved that some lipid remained encapsulated within matrix.• The cell-wall is the main factor regulating the lipid bioaccessibility.

Compositional analysis of Chinese water chestnut (Eleocharis dulcis) cell-wall material from parenchyma, epidermis, and subepidermal tissues.

Chinese water chestnut (Eleocharis dulcis (Burman f.) Trin ex Henschel) is a corm consumed globally in Oriental-style cuisine. The corm consists of three main tissues, the epidermis, subepidermis, and parenchyma; the cell walls of which were analyzed for sugar, phenolic, and lignin content. Sugar content, measured by gas chromatography, was higher in the parenchyma cell walls (931 μg/mg) than in the subepidermis (775 μg/mg) or epidermis (685 μg/mg). The alkali-extractable phenolic content, measured by high-performance liquid chromatography, was greater in the epidermal (32.4 μg/mg) and subepidermal cell walls (21.7 μg/mg) than in the cell walls of the parenchyma (12.3 μg/mg). The proportion of diferulic acids was higher in the parenchyma. The Klason lignin content of epidermal and subepidermal cell walls was ~15%. Methylation analysis of Chinese water chestnut cell-wall polysaccharides identified xyloglucan as the predominant hemicellulose in the parenchyma for the first time, and also a significant pectin component, similar to other nongraminaceous monocots.

4:Functional Components and Mechanisms of Action of ‘Dietary Fibre’ in the Upper Gastrointestinal Tract: Implications for Health

Dietary fibre is a generic term for a chemically diverse group of carbohydrates that are resistant to endogenous enzymes of the human digestive tract. The major component of dietary fibre consists of plant cell walls, which are supramolecular structures, composed of complex heterogeneous networks of cellulose, hemicelluloses and pectic substances. The amounts and relative proportions of these carbohydrates vary depending on the type and maturity of the plant tissue. Some plant cell walls, especially those from leguminous seeds, are rich in water-soluble non-starch polysaccharides (NSP).Intact plant cell walls and NSP affect the rate and extent of nutrient digestion, with important implications for health and disease. Certain types of fibre reduce the rate of starch digestion, which in turn can significantly attenuate the postprandial rise in blood glucose and insulin concentrations. This is potentially beneficial in the prevention and treatment of diseases, including diabetes mellitus and cardiovascular disease. However, the mechanisms of action of NSP in relation to the digestive process are still not well understood. They are thought to include formation of viscous solutions, encapsulation of nutrients and inhibition of digestive enzymes.These mechanisms are illustrated using specific examples. Oat β-glucan is used to show the effects of various processing techniques on β-glucan molecular weight, and hence viscosity, on risk factors for diabetes and cardiovascular disease. Evidence for guar galactomannan acting as an inhibitor of α-amylase, in addition to forming viscous solutions, is presented. Finally, the effect of intact plant cell walls on the bioaccessibility of nutrients is discussed.

Understanding the Effect of Particle Size and Processing on Almond Lipid Bioaccessibility through Microstructural Analysis: From Mastication to Faecal Collection

We have previously reported on the low lipid bioaccessibility from almond seeds during digestion in the upper gastrointestinal tract (GIT). In the present study, we quantified the lipid released during artificial mastication from four almond meals: natural raw almonds (NA), roasted almonds (RA), roasted diced almonds (DA) and almond butter from roasted almonds (AB). Lipid release after mastication (8.9% from NA, 11.8% from RA, 12.4% from DA and 6.2% from AB) was used to validate our theoretical mathematical model of lipid bioaccessibility. The total lipid potentially available for digestion in AB was 94.0%, which included the freely available lipid resulting from the initial sample processing and the further small amount of lipid released from the intact almond particles during mastication. Particle size distributions measured after mastication in NA, RA and DA showed most of the particles had a size of 1000 µm and above, whereas AB bolus mainly contained small particles (<850 µm). Microstructural analysis of faecal samples from volunteers consuming NA, RA, DA and AB confirmed that some lipid in NA, RA and DA remained encapsulated within the plant tissue throughout digestion, whereas almost complete digestion was observed in the AB sample. We conclude that the structure and particle size of the almond meals are the main factors in regulating lipid bioaccessibility in the gut.

Functional components and mechanisms of action of ‘dietary fibre’ in the upper gastrointestinal tract

Dietary fibre is a generic term for a chemically diverse group of carbohydrates that are resistant to endogenous enzymes of the human digestive tract. The major component of dietary fibre consists of plant cell walls, which are supramolecular structures, composed of complex heterogeneous networks of cellulose, hemicelluloses and pectic substances. The amounts and relative proportions of these carbohydrates vary depending on the type and maturity of the plant tissue. Some plant cell walls, especially those from leguminous seeds, are rich in water-soluble non-starch polysaccharides (NSP).Intact plant cell walls and NSP affect the rate and extent of nutrient digestion, with important implications for health and disease. Certain types of fibre reduce the rate of starch digestion, which in turn can significantly attenuate the postprandial rise in blood glucose and insulin concentrations. This is potentially beneficial in the prevention and treatment of diseases, including diabetes mellitus and cardiovascular disease. However, the mechanisms of action of NSP in relation to the digestive process are still not well understood. They are thought to include formation of viscous solutions, encapsulation of nutrients and inhibition of digestive enzymes.These mechanisms are illustrated using specific examples. Oat β-glucan is used to show the effects of various processing techniques on β-glucan molecular weight, and hence viscosity, on risk factors for diabetes and cardiovascular disease. Evidence for guar galactomannan acting as an inhibitor of α-amylase, in addition to forming viscous solutions, is presented. Finally, the effect of intact plant cell walls on the bioaccessibility of nutrients is discussed.

Stability of complex carbohydrate structures

Dietary fibre is a generic term for a chemically diverse group of carbohydrates that are resistant to endogenous enzymes of the human digestive tract. The major component of dietary fibre consists of plant cell walls, which are supramolecular structures, composed of complex heterogeneous networks of cellulose, hemicelluloses and pectic substances. The amounts and relative proportions of these carbohydrates vary depending on the type and maturity of the plant tissue. Some plant cell walls, especially those from leguminous seeds, are rich in water-soluble non-starch polysaccharides (NSP).Intact plant cell walls and NSP affect the rate and extent of nutrient digestion, with important implications for health and disease. Certain types of fibre reduce the rate of starch digestion, which in turn can significantly attenuate the postprandial rise in blood glucose and insulin concentrations. This is potentially beneficial in the prevention and treatment of diseases, including diabetes mellitus and cardiovascular disease. However, the mechanisms of action of NSP in relation to the digestive process are still not well understood. They are thought to include formation of viscous solutions, encapsulation of nutrients and inhibition of digestive enzymes.These mechanisms are illustrated using specific examples. Oat β-glucan is used to show the effects of various processing techniques on β-glucan molecular weight, and hence viscosity, on risk factors for diabetes and cardiovascular disease. Evidence for guar galactomannan acting as an inhibitor of α-amylase, in addition to forming viscous solutions, is presented. Finally, the effect of intact plant cell walls on the bioaccessibility of nutrients is discussed.