Pulses are annual leguminous crops that include lentils, beans, chickpeas and yellow peas. Pulse crops are high in protein, antioxidants and fibre, and low in fat and energy, all these factors contribute to the reduction of CVD and type 2 diabetes mellitus risk(Reference Hu and Willett1, Reference Willett2). The United States Department of Agriculture (USDA) recommends that adults consume half a cup of legumes/d, including pulses, as part of a healthy diet. Typically, pulse consumption is recommended to diabetics as a means of controlling postprandial glycaemia. However, animal and human studies have noted that the consumption of chickpeas, beans and lentils also reduces circulating lipid and glucose concentrations, while improving body composition by decreasing percentage fat mass(Reference Anderson and Major3–Reference Yang, Zhou and Gu5). Although satiety and reduced food intake are believed to contribute to health benefits associated with pulse crops(Reference Venn and Mann6), the effects of individual pulse crops remain poorly characterised.
Health benefits of yellow peas have been given little attention in human clinical trials, despite being a low-cost commodity with widespread consumption worldwide. Yellow peas consist of an outer layer known as the seed coat or hull and an inner portion termed as the cotyledon. The seed coat contains 85–90 % fibre, while the cotyledon is higher in protein and unsaturated fat. In addition, yellow peas are a source of secoisolariciresinol(Reference Mazur7), a phyto-oestrogen that is metabolised by colonic microflora to enterolactone(Reference Valentin-Blasini, Sadowski and Walden8). Investigating how sub-components of yellow peas have an impact on indices of health is likely to shed light on which portion of yellow peas possesses the most health benefits, bringing awareness about yellow peas as a dietary approach for CVD and diabetes prevention.
Evaluating and classifying how various fractions of pulse crops have an impact on health will serve as a rationale for isolating and concentrating their components for inclusion into diets that do not utilise pulse crops as staple foods. The production of novel pulse-derived flours serves as a new platform for administering pulse fractions, enabling new and flexible approaches for incorporating pulse-derived components into North American diets. As such, the objective of the present study was to evaluate the efficacy of whole and fractionated yellow pea flours in reducing risk factors associated with CVD and diabetes while controlling food and energy intake.
Methods
Subjects
Twenty-nine hypercholesterolaemic, overweight (BMI 25–40 kg/m2) men and women were recruited from the Winnipeg area using newspaper and radio advertisements. Baseline characteristics of the participants are summarised in Table 1. Exclusion criteria included smoking, the use of prescription and natural lipid-lowering therapies, history of myocardial infarction, coronary artery bypass, angina, congestive heart failure, inflammatory bowel disease, pancreatitis, renal disease, diabetes and a history of chronic alcohol usage (>2 drinks/d). Individuals with cancer, eating disorders and those who reported expending>16 747 kJ/week through exercise were also excluded from the participation. The participants taking medications for other ailments were included providing their daily dose of medication remained stable for the duration of the study. The present study was conducted according to the guidelines laid down in the Declaration of Helsinki, and all procedures involving human subjects/patients were approved by the University of Manitoba's Biomedical Research Ethics Board (B2006: 129). A written informed consent was obtained from all the participants. The present study was registered at www.clincialtrials.gov, ID NCT00839774 (6 February 2009).
TC, total cholesterol; LDL-C, LDL-cholesterol; HDL-C, HDL-cholesterol.
Treatments
Treatments consisted of whole pea flour (WPF), fractionated pea flour (FPF; hulls only) and white wheat flour (WF; control). Treatment flours were administered with banana and apple muffins to subjects. Muffin recipes were developed at the Richardson Centre for Functional Foods and Nutraceuticals clinical kitchen. WPF and FPF flours were obtained from Best Cooking Pulses, Inc. (Portage la Prairie, MB, Canada), while the WF was obtained from a local supermarket. Pea treatment flours were analysed by Medallion Labs (Minneapolis, MN, USA) to determine their nutrient composition (Table 2). The composition of WF was determined by available food analysis tables(Reference Brault Dubuc and Caron-Lahaie9). The current USDA recommendations for pulse consumption are half a cup/d, which is approximately 50 g dry whole yellow peas(10). Each WPF treatment muffin was formulated to contain approximately 25 g, 50 % the USDA recommended daily serving of pulses. Given that two WPF treatments were equivalent to 1/2 cups/d dry yellow peas (50 g), the subjects were required to eat two treatment muffins/d. The FPF treatment muffins were formulated based on the total pea-derived fibre content of the WPF muffin since the pea hull flour used in the present study was approximately 84·2 % fibre (Table 2). Hence, the amount of fractionated flour added to the FPF muffin recipe was adjusted to equal the amount of fibre in the WPF treatment (Table 3). The balance of the muffin weight was white wheat flour. Adjusting FPF treatments to contain the same amount of pea fibre as the WPF treatment enabled distinguishing of whether it was the fibre component of the USDA's recommended intake of pulses that conferred health benefits or the cotyledon component of WPF. The WF muffin was solely comprised of white wheat flour. Xanthin gum was added to all the muffin recipes at 2·0 % of total flour weight to compensate for WPF and FPF flours lacking gluten.
WPF, whole pea flour; FPF, fractionated pea flour; WF, white wheat flour.
* Treatment flours analysed at Medallion Labs (Minneapolis, MN, USA).
† Flour composition determined using available nutritional tables(Reference Brault Dubuc and Caron-Lahaie9).
* Nutritional summary is based on a 12·56 MJ/d diet.
† Values in parentheses denote percentage of total energy.
Study design
The present study used a single-blind, cross-over design. The study consisted of three 4-week study phases, each followed by a 4-week washout. To determine the treatment order within each subject, the participants were randomly assigned to one of the six possible treatment sequences.
Diet and treatment protocol
For the duration of each study phase, the subjects only consumed food provided by the Richardson Centre for Functional Foods and Nutraceuticals clinical research kitchen. The nutrient composition of the study diet was analysed using Food Processor version 7.71 (ESHA Research, Portland, OR, USA) as is summarised in Table 3. The background diet was in accordance with the American Heart Association's National Cholesterol Education Program (NCEP)-Step 1 diet. Diets did not contain any pulse products apart from the treatment muffins. To prevent body weight change for the duration of each study phase, daily energy requirements for each subject were determined by calculating individual RMR using the Mifflin equation(Reference Mifflin, St Jeor and Hill11), then by applying an activity factor of 1·7. The amount of food the each participant received was based on individual calculated energy requirements. The average energetic content of two treatment muffins (approximately 1675 kJ) was subtracted from the total calculated energy requirements to compensate for the energy intake from WPF, FPF and WF. Body weights were assessed daily. If a subject's weight increased or decreased in the first week of each study phase, the energy intake was adjusted accordingly. Each morning, the study participants were required to visit the Richardson Centre for Functional Foods and Nutraceuticals clinical research unit to consume breakfast and one banana-flavoured treatment muffin under supervision. The participants would then leave the unit with a cooler containing the remainder of their meals and snacks along with an apple-flavoured treatment muffin to consume with dinner. Returned empty, unwashed food containers were used to monitor compliance.
Blood collection protocol
Twelve-hour fasting serum and plasma blood samples were collected on days 1, 2, 28 and 29 of each study phase. Blood was centrifuged at 3000 rpm at 4°C to separate serum and plasma from erythrocytes, which were then stored at − 80°C until analysed.
Fasting insulin values and insulin homeostasis modelling assessment
Fasting plasma insulin concentrations were determined using ELISA (Millipore, Linco Research, St Charles, MO, USA). The average CV % between duplicate samples was 1·0 %. The resultant insulin values were transformed from μU/ml to pmol/ml by multiplying values by a factor of 6·0(Reference Volund12). Insulin homeostasis modelling assessment (HOMA) was utilised as an estimate for %β-cell function and insulin resistance (IR). The HOMA values were calculated using methods outlined by Matthews et al. (Reference Matthews, Hosker and Rudenski13). Baseline and endpoint insulin parameters were reported as the average between day 1 and 2 and day 28 and 29 values, respectively.
Glucose response protocol
Glucose responses to the breakfast meal and treatment were determined during the first and last weeks of each study phase. Fasting glucose concentrations were determined using a finger-prick blood glucose monitor (Accu-chek plus; Roche Diagnostics, Laval, QC, Canada). The subjects had 40 min to eat their energetically calculated breakfast and one treatment muffin (approximately a quarter cup of peas). Glucose concentrations were assessed before and at 40, 70, 130 and 190 min following the initiation of breakfast. For logistic reasons, we were unable to assess blood glucose across 15 min intervals, the period typically used when assessing glucose response(Reference Brouns, Bjorck and Frayn14). In addition to assessing postprandial glucose response, the subjects were simultaneously undergoing postprandial energetic responses via indirect calorimetry at 30 and 60 min increments. Hence, blood glucose measurements were assessed after the subjects completed an energetic measurement interval. If blood glucose measurements were taken during indirect calorimetry intervals, the finger-prick utilised to take blood samples would have induced stress and skewed O2 consumption and CO2 production and jeopardised the integrity of data collected during the assessment of energy expenditure. At least two blood glucose readings were taken at each time point. A third measurement was taken if glucose values were >0·3 mmol/l apart. Finally, two quality assurance solutions containing known amounts of either high glucose or low glucose levels were used daily to ensure glucose monitors produced accurate results.
Incremental areas under the curve for glucose response curves were determined using the methodologies outlined by Wolever & Jenkins(Reference Wolever and Jenkins15). Briefly, the area below baseline was subtracted from the total incremental areas under the curve values. If the data points fell below baseline, only areas above the baseline value were considered.
Body composition protocol
Body composition, including percentage of total fat mass (%TFM), TFM and total lean mass, as well as percentage android and gynoid fat, were assessed on days 1 and 29 of each study phase using fan beam dual-energy X-ray absorptiometry (Lunar Prodigy Advance; GE Healthcare, Madison, WI, USA). Body composition data including %TFM, TFM, total lean mass, android fat and gynoid fat deposition were determined using Encore 2005 software version 9.30.044 (GE Healthcare). Encore 2005 also calculated android:gynoid fat ratios by dividing % android fat by % gynoid fat.
Urinary enterolactone levels
Morning-fasted urine samples were collected on day 29 of each study phase. The subjects were instructed not to void their bladder at home before arriving at the Richardson Centre for Functional Foods and Nutraceuticals. The urine samples were aliquoted and stored at − 80°C until analysis. Urinary enterlactone levels were analysed by competitive enzyme immunoassay (Cayman Chemical, Ann Arbor, MI, USA). All the samples were diluted 1000 × before enzyme immunoassay analysis. Urinary creatinine levels were determined enzymatically (Vitros 350; Ortho-clinical Diagnostics, Inc., Rochester, NY, USA) and used to normalise urinary enterolactone values.
Fasting lipid and glucose profile
Day 1, 2, 28 and 29 serum total cholesterol (TC), HDL-cholesterol (HDL-C), TAG and glucose concentrations were analysed enzymatically (Vitros 350; Ortho-clinical Diagnostics, Inc.). LDL-cholesterol (LDL-C) concentrations were calculated using the Friedewald equation(Reference Friedewald, Levy and Fredrickson16). Baseline and endpoint lipid and glucose parameters were reported as the average between days 1 and 2 and days 28 and 29 values, respectively.
Statistics
The results are presented as means with their standard errors. Differences in endpoint values between treatment groups for body composition, TC, LDL-C, TAG, HDL-C, glucose, insulin and HOMA data were analysed using linear mixed-model ANOVA with subject as a random factor. Normality was assessed using the Shapiro–Wilk test, as well as evaluating linearity and clustering in normal and disturbed Q–Q plots, respectively. Circulatory TAG, HDL-C concentrations, HOMA variables and urinary entrolactone levels did not follow a normal distribution, and they were log-transformed for statistical analysis. For reporting purposes, means with their standard errors were back-transformed to physiological values. For glucose response, total effect of treatment over time was assessed using repeated measures. For all ANOVA, estimated means were compared using the Bonferroni post hoc test when significant differences were noted. Intra-treatment differences between start-phase and end-phase values were determined using paired t tests. A level of significance at P < 0·05 was used in all the analyses. The data were analysed using SPSS software version 11.5 (SPSS, Inc., Chicago, IL, USA).
Results
Subject dropout and compliance
Of the twenty-nine individuals who participated in the study, twenty-three subjects completed the entire 12-week trial. Two subjects discontinued the study for medical reasons, while four subjects dropped out for personal reasons. After dropouts, the number of men and women in the study were seven and sixteen, respectively. One subject was taking aspirin over the course of the study. No other subject was consuming over-the-counter or prescription medications over the course of the study. Statistical analysis for all measurements revealed no effect of sex, age or an age × sex interaction.
Fasting insulin and insulin homeostasis modelling assessment for insulin resistance and %β-cell function
End-phase fasting insulin concentrations were reduced during WPF (P = 0·021) and FPF (P = 0·037) treatments, respectively, compared with WF (Table 4). No differences were observed for endpoint insulin concentrations between WPF and FPF treatments. Furthermore, within-phase analysis revealed that WPF and FPF significantly reduced fasting insulin by 13·5 (sem 4·8) % (P = 0·009) and 9·8 (sem 4·8) % (P = 0·045) from baseline compared with WF (Table 4). No differences in percentage change between baseline and endpoint were observed between WPF and FPF.
WF, white wheat flour; WPF, whole pea flour; FPF, fractioned pea flour; HOMA, insulin homeostasis modelling assessment; IAUC, incremental area under the curve.
a,b Mean values within a row with unlike superscript letters were significantly different: *P < 0·05, **P < 0·1.
† Treatment effect for ANOVA or ANCOVA across treatments.
HOMA for insulin revealed that estimates of IR were reduced to 25 % in the WPF and FPF groups, respectively, compared with the WF group (Table 4). However, estimates of %β-cell function were not different between the groups. Percentage differences from baseline did not significantly differ between WPF, FPF and WF treatments for HOMA-based markers of %β-cell function and IR, respectively.
Body composition
Intra-phase body weights between days 1 and 29 were stable at 84·9 (sem 0·6), 85·7 (sem 0·6) and 84·3 (sem 0·6) kg for WPF, FPF and WF, respectively. Dual-energy X-ray absorptiometry analysis revealed that WPF, FPF and WF had no effect on endpoint values or calculated intra-treatment percentage differences for %TFM, android fat or gynoid fat. While no changes were noted between WF and WPF compared to FPF, there was a trend towards a reduction (P = 0·059) in the android:gynoid ratio for WPF v. WF. However, when stratified by sex, females (n 16) administered with WPF demonstrated a 4·7 % reduction (P = 0·027) in android:gynoid ratios compared with when they received WF (Table 4).
Postprandial glucose response
No treatment differences were observed in postprandial glucose incremental areas under the curve for endpoint and percentage change from baseline.
Urinary enterolactone levels
Urinary enterolactone levels tended to be higher (P = 0·084) in the WPF group compared with those in the WF group (Table 4).
Fasting serum lipid and glucose concentrations
Within-group reductions in TC and LDL-C were observed in all three treatment groups, along with decreases in HDL-C in the WPF and WF groups compared with baseline (Table 5). Fasting glucose decreased in the FPF group compared with baseline. However, no effect on fasting serum TC, LDL-C, HDL-C, TAG or glucose concentrations were observed between the treatment groups (Table 5).
WPF, whole pea flour; FPF, fractioned pea flour; WF, white wheat flour, TC, total cholesterol; LDL-C, LDL-cholesterol; HDL-C, HDL cholesterol.
Mean values were significantly different from those of the days 1 and 2: * P < 0·05, ** P < 0·002, *** P < 0·001.
† Treatment effect for ANOVA across treatments. Statistical significance was set at P < 0·05.
‡ Percentage change is based on individual data.
Discussion
The novel findings presented demonstrate that under conditions that control for food and energy intake, the USDA's recommended dose of 50 g/d WPF (half a cup) and FPF, normalised to the fibre content in the WPF treatment, effectively reduced fasting insulin concentrations, and IR in hypercholesterolaemic, overweight individuals. In addition, women consuming WPF showed lower android:gynoid fat ratios compared with WF.
The observation that both the pea treatments produced the same effect on fasting insulin concentrations suggests that pea fibre was the efficacious bioactive substance responsible for that action. It is likely that the effect of WPF and FPF on fasting insulin was secondary to a reduction in IR as indicated by the 25 % in HOMA-IR, an estimate of IR. The data suggest that less insulin was needed to maintain fasting glucose concentrations. Other studies have observed similar effects in canned chickpeas(Reference Pittaway, Robertson and Ball17) and cereal fibre(Reference Weickert, Mohlig and Schofl18). Insulin resistance is considered a major risk factor for diabetes, CVD, hypertension, obesity and inflammation(Reference Ginsberg19, Reference Watson, Peters Harmel and Matson20). Moreover, whole yellow peas and fractionated yellow peas are high in insoluble fibre. A prospective cohort study demonstrated that diets rich in insoluble fibre reduced the risk of type 2 diabetes by 25 %(Reference de Munter, Hu and Spiegelman21). Similarly, a meta-analysis by Schulze et al. (Reference Schulze, Schulz and Heidemann22) revealed that cereal-derived fibre, a good source of insoluble fibre, was associated with a lower relative risk ratio for diabetes of 0·67 compared with soluble fibres from fruits and vegetables at 0·96 and 1·07, respectively. SCFA production in the gastrointestinal tract secondary to microbial fermentation of fibres has been shown to increase insulin sensitivity(Reference Thorburn, Muir and Proietto23–Reference Robertson26). Researchers propose that SCFA reduce levels of circulating NEFA, a known inducer of IR(Reference Savage, Petersen and Shulman27). The notion of whole and fractionated yellow peas evoking a prebiotic effect serves as a plausible mechanism to explain observed changes in insulin parameters. Why this effect occurred without acting on fasting glucose and/or postprandial glucose responses cannot, however, be reconciled using the present data.
The present study attempted to define the effect of pea treatments on body composition in the context of an energy-balanced paradigm. By preventing the changes in body weight, we demonstrated that WPF and FPF do not affect %TFM, independent of the changes in body mass. The lack of effect on body composition was most likely due to controlling energy intake and maintaining body weight over the duration of each study phase. Furthermore, the results from the present study suggest that WPF or FPF do not contain bioactive compounds that up-regulate energy expenditure. Moreover, since subjects were required to consume all food provided by the study personnel during each study phase, a negligible effect on body composition with WPF and FPF treatments in the present study was observed in the absence of pulses triggering satiety-related suppression of food intake, a potential mechanism of action of yellow peas, and ultimately pulses, on body composition(Reference Pittaway, Robertson and Ball17, Reference Delargy, O'Sullivan and Fletcher28, Reference Salas-Salvado, Farres and Luque29).
Increased android adiposity is associated with CVD risk factors including IR, inflammation and atherosclerosis(Reference Carey, Jenkins and Campbell30, Reference Tanko and Christiansen31). In the present study, women demonstrated a shift in fat distribution from android to gynoid with WPF, suggesting that bioactives other than fibre are responsible for the effects observed. WPF contains the cotyledon which houses various proteins and phytochemicals including secoisolariciresinol, a lignan-type phyto-oestrogen at 13 μg/100 g(Reference Mazur7). Pea-derived secoisolariciresinol is converted to enterolactone by colonic microflora and subsequently absorbed. While oestrogen helps to regulate regional fat deposition by interacting with oestrogen receptor α (ERα) and β (ERβ) and up-regulating α2- and β-adrenergic receptors, studies indicate that various phyto-oestrogens exhibit different affinities for ERα and ERβ. For example, soya-derived phyto-oestrogens demonstrate ERβ-binding specificity(Reference Morito, Hirose and Kinjo32), while coumestrol has been shown to be an ERα-specific agonist(Reference Morito, Aomori and Hirose33, Reference Wu, Wang and Wei34). Although the biological effects of secoisolariciresinol are understudied, physiological levels of enterolactone were able to induce oestrogen-dependent reporter gene expression via ERα receptors(Reference Penttinen, Jaehrling and Damdimopoulos35). Studies suggest that women express higher levels of subcutaneous ERα(Reference Rodriguez-Cuenca, Monjo and Proenza36) and α2-adrenergic receptors(Reference Richelsen37) compared with men. Since oestrogen favours subcutaneous fat deposition via ERα- and α2-adrenergic receptors via lower lipolytic activity in subcutaneous adipose tissue(Reference Richelsen37, Reference Pedersen, Kristensen and Hermann38), we hypothesise that pea-derived secoisolariciresinol could be acting as an ERα agonist in women through its conversion to enterolactone. Few studies have examined the effects of phyto-oestrogens on body composition. However, Sites et al. (Reference Sites, Cooper and Toth39) demonstrated that soya isoflavones reduced abdominal subcutaneous fat deposition in post-menopausal women and suggested that the preferential affinity of soya-derived phyto-oestrogens for ERβ may explain their results. The observation that urinary enterolactone levels tended to be higher in the WPF group compared with those in the WF group in the present study augurs for further exploration of the effects of enterolactone on body fat distribution.
Failure for WPF and FPF to reduce fasting glucose concentrations is most likely secondary to the fact that most individuals were already normoglycaemic with fasting glucose concentrations < 5·6 mmol/l. Similar negative results have been observed with chickpea-fortified bread products(Reference Nestel, Cehun and Chronopoulos40) and high-fibre rye bread(Reference Juntunen, Laaksonen and Poutanen41). WPF and FPF also failed to change postprandial glucose responses when combined with an energetically balanced breakfast. Foods high in dietary fibre are thought to reduce postprandial glucose responses by interfering with glucose absorption(Reference Jenkins, Axelsen and Kendall42). High levels of insoluble fibre found in yellow peas may have contributed to yellow peas inefficacy at reducing postprandial glycaemia since insoluble fibres are less effective than soluble fibres at blunting glycaemic responses(Reference Jenkins, Kendall and Axelsen43). However, Guevin et al. (Reference Guevin, Jacques and Nadeau44) noted that 10 g dietary fibre at 1:4 and 2:3 ratios of soluble to insoluble fibre failed to produce any effect on postprandial glycaemia, suggesting that factors other than fibre type are responsible for the varied results regarding the effect of pulses on glycaemic response. It should be emphasised that in the present study, in order to eliminate the confounding effects of fibre from the diet, some fibre was removed from the background diet, as breads were all composed of white flour. Hence, the energy density and amount of simple carbohydrates of the breakfast meal may have been in excess for some subjects, such that the dose of WPF or FPF did not reduce glucose absorption. On the other hand, the calculated glycaemic index of the breakfast meal excluding treatment was low at approximately 39·6 and was secondary to the high proportion of egg protein relative to carbohydrate content. Given that the glycaemic index of the breakfast meal was already reduced, postprandial glucose concentrations may have been blunted such that the quarter cup of peas during breakfast failed to exert any observable effect on glucose response. Finally, it has been suggested that traditionally cooked pulses, i.e. boiled, exert a greater effect on glucose response because of the lower surface area compared with equivalent amounts of pulse flour(Reference Araya, Pak and Vera45). Smaller particles, as found in flours, would have allowed greater surface exposure to digestive enzymes and hence a higher rate of absorption(Reference Araya, Contreras and Alvina46). Hence, using flours as a vehicle for administering WPF and FPF in the present study may have prevented a blunting in postprandial glycaemic response.
The observation that within-group reductions in lipid concentrations for TC, LDL-C and HDL-C did not translate into changes between treatment groups suggests that alterations in fasting lipids were secondary to the NCEP-Step 1 diet provided to volunteers during each treatment phase. The present results show no changes in lipid levels secondary to the WPF and FPF treatments. Previous studies suggest that the dose of pulses used in the present study was insufficient to induce a lipid-lowering effect. Fruhbeck et al. (Reference Fruhbeck, Monreal and Santidrian47) noted significant reductions in TC, LDL-C and TAG with 90 g/d raw and cooked bean flour, a dose that was almost double the 50 g WPF provided to the volunteers in the present study. Conversely, Calvert et al. (Reference Calvert, Blight and Illman48) failed to observed a change in TC, LDL-C HDL-C and TAG when subjects received 50 g/d defatted soyabean flour for 28 d. The results from Calvert et al. (Reference Calvert, Blight and Illman48), together with the present findings, suggest that the dose administered may have been insufficient to elicit a significant change in circulating lipid concentrations.
Conclusions
In summary, the present results suggest that the fibre content of half a cup/d yellow peas (approximately 50 g) in the form of WPF and FPF improves CVD and diabetes risk factors by reducing fasting insulin concentrations and markers of IR independent of food and energy intake. The observation that women demonstrated a shift in subcutaneous fat deposition with WPF warrants further investigation into the phyto-oestrogenic effects of yellow peas.
Acknowledgements
We would like to thank Pulse Canada for funding the present study. The present study has no conflicts of interest. C. P. F. M. was responsible for conducting the research, analysing data and writing the manuscript. Moreover, C. P. F. M. provided input in designing the study. P. J. H. J. was instrumental in conceptualising and designing the research project. P. J. H. J. also contributed to writing the manuscript. We would also like to thank Kim Robinson, Xin Wang, Katherine Leung, Darren Speziale, Yen Ming Chan and kitchen staff for their assistance with the clinical trial, Gerber® for their generous donation of the baby food used for flavouring the treatment muffins, Roche Diagnostics for providing glucose monitors and Best Cooking Pulses, Inc., for providing the whole and fractionated pea flours. Finally, we acknowledge Dr Edward Kesselman for his medical expertise.