STARchy Staples: a Randomised Controlled Trial on Cardiometabolic Health

Not Applicable

Recruiting

• Conditions: Cardiometabolic Health
• Interventions: Dietary Supplement: Habitual non-nutrient-dense staple consumption; Dietary Supplement: Habitual potato consumption

• Registration Number: NCT05994313
• Lead Sponsor: King's College London

Brief Summary

An investigation into habitual potato consumption (mashed, boiled, baked) on sleep quality and chronic glycaemic control, established risk factors for cardiometabolic diseases, versus habitual consumptions of non-nutrient-dense starchy staples (white rice, pasta, and couscous).

Detailed Description

In the last few years, researchers have undergone efforts to conduct well-controlled trials to investigate the cardiometabolic health effect of consuming potatoes as part of a healthy diet. None to our knowledge, however, have investigated the harmful dyad of poor sleep and adverse glycaemic control, 2 interrelated factors which can exacerbate cardiometabolic (CM) health outcomes. The nutrient density of potatoes, namely being the single richest source of potassium per serving, provides a plausible mechanism in which the potatoes may act to improve health markers.

The primary objective of this study is to investigate whether consuming a portion of nutrient-dense potatoes in the evening meal, in place of other refined carbohydrates, can improve sleep quality, and improve nocturnal, and 24-hour, glycaemic control, both risk factors for CM diseases. Secondly, this study aims to investigate the effects of potato consumption on endothelium-dependent vasodilation, which can further interrelate to this web of interactions, and other measures of CM health.

Study design: A randomised, two-parallel arm, in-clinic and remote, 12-week dietary intervention study.

Study population: Healthy male and female 40-80-year-olds, who consume ≤4 fruits and vegetables per day and have sub-optimal sleep quality.

The study aims to recruit a total of 80 participants, allowing for an estimated 15% dropout rate, to reach 80% power at a significance level of 0.025 (based on two outcomes). The allocation ratio is 1:1 intervention to control.

Locations:

Metabolic Research Unit, 4th floor, Franklin Wilkins Building, Waterloo campus, Kings College London, SE1 9NH.

Screening assessment: Participants will be initially assessed for suitability against the inclusion-exclusion criteria via an online questionnaire. The outputs of the questionnaire will be assessed by the study team. Some exclusion criteria will be assessed at the baseline clinic visit before any baseline measures are provided.

Study duration: There will be a 2-week run-in period, followed by a 12-week dietary intervention.

Dietary intervention: The intervention (potato group) will consume at least 220 g of white potatoes (25% of energy intake from carbohydrates, or 12.5% of total energy intake, including fresh and frozen baked, boiled, and mashed potato products) in their evening meal, providing \~800 mg potassium, enough to increase national median intakes up to recommended intakes. The control group will consume isoenergetic amounts of non-nutrient-dense starchy staples (white pasta, white rice, or couscous).

Although participants cannot be blinded to what they're consuming, they will be blinded to whether they are in the control or the intervention group, to reduce the risk of bias.

Participants will be required to source the potatoes and make these meals themselves, however, they will be provided with rotating 4-weekly recipe cards, with instructions on how to prepare meals.

Participants will be required to attend several virtual one-to-ones with the study team, including an introductory call, a virtual run-in induction where they will be run through the study equipment, and 2 in-person clinic visits. Participants will be responsible for applying some study equipment from home, to reduce clinic visits and improve study retention.

Compliance: Compliance will be monitored via several methods. Firstly, 24 h urinary potassium excretion, which is shown to recover 75% of potassium intake, secondly self-reported compliance will be measured through evening meal checklists. We also plan to use dietary recalls at weeks 2, 4, and 8 to reinforce dietary advice, and to make adaptations to rotating menus based on individual needs, if participants are struggling with adherence. Detailed dietary intake will be assessed through 4-day food diaries at weeks 0, 6, and 12- this data will be used for analysis.

Flow-mediated dilation: A Doppler ultrasound will be utilised to capture continuous ultrasound videos to measure flow-mediated dilation. These will be analysed with automated software provided by Maastricht University.

Anthropometry: Weight, height, waist and hip circumference, blood pressure, and body fat will be taken using standard procedures, in duplicates by a trained researcher at baseline and endline clinic visits.

Blood samples: Fasting blood samples will be collected from a superficial antecubital vein via venepuncture before and after the dietary intervention, by a trained researcher.

Participants will be asked to record and monitor the following information:

Self-reported compliance with dietary intervention, weekly weight (data diaries), and habitual dietary intake (4-day diet diaries).

Study Timeline

• Status Verified: 2023-07
• Study First Submitted: 2023-08-01
• Study First Submitted QC: 2023-08-15
• Study First Posted: 2023-08-16
• Study Start: 2023-09-09
• Last Update Submitted: 2023-10-05
• Last Update Posted: 2023-10-06
• Primary Completion: 2024-12-01
• Study Completion: 2025-08-01

Recruitment & Eligibility

• Status: RECRUITING
• Sex: All
• Target Recruitment: 80

Inclusion Criteria

• Self-reported healthy adults
• Aged 40-80 years old
• Intake of ≤4 portions of fruits and vegetables (excluding potatoes) per day
• Low sleep quality index of >5 (Pittsburgh sleep quality index).

Exclusion Criteria

• Shift workers and those with multiple jobs or carers who are required to wake through the night
• Unwilling to refrain from dietary supplements
• Unwilling to follow protocol and/or give informed consent
• Diagnosed with Cardiovascular Disease (CVD), Type 2 Diabetes, Celiac disease, Insomnia, Sleep apnoea
• Presence of gastrointestinal disorder
• Users of drugs that are likely to alter gastrointestinal motility or nutrient absorption
• History of substance abuse or alcoholism
• Currently pregnant, planning pregnancy, breastfeeding, or having had a baby 12 months prior
• Weight change of >3kg in the preceding 2 months
• BMI <18.5kg/m2 or > 35kg/m2,
• Current smokers, or individuals who quit smoking in the last 6-months
• Frequently consume wholemeal products (1-2 times per day, in the short screening FFQ)
• Never consumed refined starchy staples, such as white pasta or rice (rarely or never, in the short screening FFQ)
• High potato consumption (4-6 times per week, in the short screening FFQ)
• High risk of obstructive sleep apnoea (answer yes to >3 questions, in STOP-Bang questionnaire)
• Vegetarian, Vegan, or pescatarian dietary preferences.
• Diagnosed with mental health disorders, and/or on medicine for their mental health (antipsychotics, antidepressants, beta-blockers)
• Chronic user of antihistamines
• Fasting glucose >7mmol/l (finger prick test at baseline clinic)
• Is taking weight loss, or glucose regulating medications.
• Has been unstable on blood pressure lowering medications for at least 3-months prior to enrollment.

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
Habitual non-nutrient-dense staple consumption	Habitual non-nutrient-dense staple consumption	Isocaloric amounts of non-nutrient-dense starchy staples, such as white rice, white pasta, and white couscous, will be consumed in the evening meal for 12 weeks.
Habitual potato consumption	Habitual potato consumption	At least 220g of white potatoes, including fresh and frozen, baked, boiled, and mashed potatoes, will be consumed in the evening meal, in replacement of non-nutrient-dense starchy staples, for 12 weeks.

Primary Outcome Measures

Name	Time	Method
Change in 12-day nocturnal glycaemic control	Pre- and post-intervention: 12 weeks	Differences in glycaemic variability, time in range and continuous glucose data, calculated using the total area under the curve (tAUC) model. Measured with a continuous glucose monitor.
Change in 7-day sleep efficiency	12 weeks	Differences in % sleep efficiency at endline vs baseline. Sleep efficiency % is described as the total time spent asleep/ total time spent in bed x 100.

Secondary Outcome Measures

Name	Time	Method
Change in Endothelial function	Pre- and post-intervention: 12 weeks	Mean differences in flow mediated dilation.
Change in heart rate variability during mental stress	Pre- and post-intervention: 12 weeks	A combination of time domain, frequency domain and non-linear methods (NN intervals, Heart rate, rMSSD, SDNN, SD1/SD2, High frequency, Low frequency: high frequency ratio) will be compared from pre- to post-mental stress. The differences will be compared to pre- and post-intervention.
Change in fasting HbA1C	Pre- and post-intervention: 12 weeks	Fasting HbA1C concentration
Change in diet quality	Pre- and post-intervention: 12 weeks	Measured by several indices: plant-based diet index, alternative Mediterranean score, alternative healthy eating index and high-fat index.
Change in 24-hour heart rate variability	Pre- and post-intervention: 12 weeks	A combination of time domain, frequency domain and non-linear methods (NN intervals, Heart rate, rMSSD, SDNN, SD1/SD2, High frequency, Low frequency: high frequency ratio) will be compared to pre- and post-intervention.
12-week daytime continuous blood pressure	Whole 12 week period.	Measured with an Aktiia Photoplethysmography watch.
Change in fasting plasma glucose	Pre- and post-intervention: 12 weeks	Fasting plasma glucose concentration
Change in BMI kg/m2	Pre- and post-intervention: 12 weeks	BMI kg/m2, measured using a stadiometer and TANITA scales
Change in blood pressure	Pre- and post-intervention: 12 weeks	Diastolic and systolic blood pressure, measured by oscillometry.
Change in fasting insulin	Pre- and post-intervention: 12 weeks	Fasting insulin concentration
Change in 12-day daytime glycaemic control	Pre- and post-intervention: 12 weeks	Differences in glycaemic variability, time in range and continuous glucose data, calculated using the total area under the curve (tAUC) model. Measured with a continuous glucose monitor.
Change in 24-hour nocturnal glycaemic control	Pre- and post-intervention: 12 weeks	Differences in glycaemic variability, time in range and continuous glucose data, calculated using the total area under the curve (tAUC) model. Measured with a continuous glucose monitor.
Change in plasma lipids	Pre- and post-intervention: 12 weeks	Including: total lipids, HDL and LDL-cholesterol, and Triacylglycerols.
Change in sleep duration, in minutes	Pre- and post-intervention: 12 weeks	Sleep duration (minutes)
12-week nighttime continuous blood pressure	Whole 12 week period.	Measured with an Aktiia Photoplethysmography watch.
Change in sleep duration, in %	Pre- and post-intervention: 12 weeks	Sleep duration (%)
Change in sleep latency	Pre- and post-intervention: 12 weeks	Sleep latency is defined as the time it takes to fall asleep from the time intended to fall asleep.
Change in body fat %	Pre- and post-intervention: 12 weeks	Body fat % measured using TANITA bioelectrical impedance scales
Change in waist circumference (cm)	Pre- and post-intervention: 12 weeks	Waist circumference (cm)

Trial Locations

Locations (1)

Department of Nutritional Sciences, Franklin Wilkins Building, Waterloo campus.; 🇬🇧 Lambeth, London, United Kingdom