Exogenous Ketosis During Bed Rest in Older Adults

Not Applicable

Completed

• Conditions: Insulin Sensitivity; Muscle Strength; Muscle Atrophy; Cognitive Function; Functional Capacity; Mitochondrial Function; Physical Inactivity; Muscle Protein Synthesis
• Interventions: Dietary Supplement: ketone monoester (R)-3-hydroxybutyl (R)-3- hydroxybutyrate

• Registration Number: NCT05679596
• Lead Sponsor: McGill University

Brief Summary

The goal of this randomized, double-blind, parallel group interventional study is to evaluate the effect of ketone bodies on healthy older adults (65-85 y) during 5 days of bed rest. The main questions it aims to answer are:

Does supplementation of ketone bodies prevent the typical decline in muscle protein synthesis, muscle size, muscle function, insulin sensitivity, and muscle mitochondrial function that occurs in response to bed rest?

Researchers will compare ketone supplements (KET) to an energy matched control beverage (carbohydrates and fats) to see if the ketones can rescue the decline in muscle protein synthesis rates, muscle loss, muscle function, insulin sensitivity, and mitochondrial function due to 5 days of bed rest.

This may positively impact the heath of older adults subjected to bed rest.

Detailed Description

Bed rest is a common feature of many clinical environments such as hospitals and long-term care facilities. However, physical inactivity due to bed rest decreases muscle size, muscle strength, and physical performance (i.e. rising from a chair) that can lead to a reduced quality of life and a higher risk of disease and death. Eating protein-rich foods and exercising normally helps to maintain muscle size by building proteins found in muscle. However, during bed rest there is a reduction in the rate at which proteins found in muscle are made and this leads to smaller muscles. Bed rest leads to problems with blood glucose regulation and insulin resistance which can increase the risk for diabetes. Both the loss of muscle size and insulin resistance are linked to problems with parts of our cells called mitochondria. Mitochondria do a lot of important things including keeping our cells full of energy. Bed rest occurs more frequently in older adults and also negatively impacts their health more than in younger adults. Sadly, there are limited options to prevent the problems associated with bed rest. Ketone bodies are molecules that come from fat that are normally produced in the body in response to reduced carbohydrate intake (i.e. a ketogenic diet). Recently ketone supplements have become available, which increase the amount of ketone bodies in the body without the need to limit carbohydrate intake from food. Elevated ketone bodies may help protect muscle size and health during bed rest by enhancing the process of building muscle proteins, improving blood glucose regulation, and helping mitochondria work optimally.

Study Timeline

• Study First Submitted: 2022-12-12
• Study First Submitted QC: 2022-12-23
• Study First Posted: 2023-01-11
• Study Start: 2023-02-27
• Primary Completion: 2023-11-15
• Study Completion: 2023-11-15
• Status Verified: 2024-02
• Last Update Submitted: 2024-02-06
• Last Update Posted: 2024-02-07

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 30

Inclusion Criteria

• Healthy, male, and female, older adults.
• Healthy will be defined as screen by the 2020 PAR-Q+, medical screening questionnaire, GAQ, and COVID-19 symptom questionnaire patient screening.
• 'Older' will be defined as being 65-85 years of age.
• Participants are required to not engage in structured resistance training for at least 6 months prior to participation in the study.
• Participants are willing to abide by the compliance rules of this study.

Exclusion Criteria

• Pre-menopausal females: Women must be postmenopausal having not menstruated for at least 1 year prior to study participation. Hormonal fluctuations associated with the menstrual cycle have been reported to alter protein metabolism and may influence indices of muscle protein synthesis and breakdown (69-71).
• BMI <18.5 or > 30 kg ∙ m-2.
• Self-reported regular tobacco use and vaping products.
• Self-reported illicit drug use (e.g., growth hormone, testosterone, etc.)
• Individuals who have participated in studies within the past year involving a stable isotope of 2H.
• A history of thrombosis, diagnosed with type 2 diabetes mellitus by physician or HbA1c values of > 7.0%, dementia, coronary artery disease, musculoskeletal/orthopedic disorders, and severe allergies.
• The use of medications known to modulate skeletal muscle metabolism (e.g., corticosteroids, hormone replacement therapy, non-steroidal anti-inflammatory drugs, metformin).
• The use of over-the-counter supplements (protein supplements, creatine, fish oil).
• Inability to adhere to any of the compliance rules judged by the principal investigator or medical doctor.

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
Exogenous ketone monoester (KET)	ketone monoester (R)-3-hydroxybutyl (R)-3- hydroxybutyrate	KET will be provided at a dose of 360 mg kg-1 body mass per serving at 2 servings per day between each main meal (ΔG®; TΔS Ltd, UK, Oxford, UK).

Primary Outcome Measures

Name	Time	Method
Changes in integrated fractional synthesis rate (%/d) in response to bed rest with and without ketone monoester (KET) supplementation.	Day 0-5 and day 5-10	Integrative myofibrillar fractional synthesis rate will be calculated during baseline (day 0-5) and bed rest (day 5-10) phases.

Secondary Outcome Measures

Name	Time	Method
Changes in quadriceps muscle volume in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Measurements taken before and after bed rest via magnetic resonance imaging (MRI).
Changes in whole body insulin sensitivity in response to bed rest with and without ketone monoester (KET) supplementation.	Day-3 and Day 10.	Measurements taken in the fasted state before and after bed rest. Will measure blood glucose and insulin concentration during a hyperinsulinemic-euglycemic clamp.
Changes in maximal voluntary isometric contraction (N/m) of the knee extensors in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Measurements taken before and after bed rest using a Biodex dynamometer.
Changes in leg lean mass (kg) in response to bed rest with and without ketone monoester (KET) supplementation	Day -3 and Day 10.	Measurements taken in the fasted state using dual-energy x-ray absorptiometry (DXA) following urinary void before and after bed rest.
Changes in physical performance (numerical score) as determined by 5-item physical performance test in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Measurements taken before and after bed rest
Changes in mitochondrial respiration in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Assessed using standard substrate and inhibitor addition protocols in O2k high resolution Respirometer. Measurements taken before and after bed rest.
Changes in whole-body lean mass (kg) in response to bed rest with and without ketone monoester (KET) supplementation	Day-3 and Day 10.	Measurements taken in the fasted state using dual-energy x-ray absorptiometry (DXA) following urinary void before and after bed rest.
Changes in physical performance (numerical score) as determined by short physical performance battery (SPPB) in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Measurements taken before and after bed rest
Changes in skeletal muscle fiber size in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Muscle cross-sections analyzed for cross-sectional area.
Changes in mitochondrial time to the permeability transition pore opening (marker of mitochondrial propensity to trigger apoptosis) in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Determined spectrofluorometrically using the Calcium Green probe. Measurements taken before and after bed rest.
Changes in muscle area in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Peripheral quantitative computed tomography (pQCT). Measurements taken before and after bed rest.
Changes in muscle density in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Peripheral quantitative computed tomography (pQCT). Measurements taken before and after bed rest.
2H enrichments in body water before and during bed rest with and without ketone monoester (KET) supplementation.	Day -1 to Day 10.	Throughout the baseline and bed rest period.
Changes in handgrip strength (kg) in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Measurements taken before and after bed rest using a Jamar hand dynamometer.
Changes in skeletal muscle phenotype in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Muscle cross-sections immunolabeled for type I, IIa, and IIx myosin heavy chains. Measurements taken before and after bed rest.
Changes in mitochondrial calcium retention capacity (marker of mitochondrial propensity to trigger apoptosis) in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Determined spectrofluorometrically using the Calcium Green probe. Measurements taken before and after bed rest.
Changes in mitochondrial reactive oxygen species (ROS) production in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Assessed using standard substrate and inhibitor addition protocols in O2k high resolution Respirometer. Measurements taken before and after bed rest.
Changes in the phosphorylation status of anabolic signaling molecules modulating muscle protein synthesis (MPS) in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Western blotting - membranes will be probed with phospho-specific antibodies against IRS-1S527/Thr446, AktSer473, mTORSer2448, 4E-BP1Thr37/46, rpS6Ser240/244, p70S6KThr389. Measurements taken before and after bed rest.
Blood beta-hydroxybutyrate concentrations (mmol/L) in response to bed rest with and without ketone monoester (KET) supplementation.	Day 5 and Day 10	Measurements taken at the start and end of bed rest.
Changes in markers of inflammation in systemic circulation in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Markers of inflammation including: IL-1 beta, NF-K beta 1, IL-6, TNF-alpha, IFNY, MIP-1 beta will be evaluated. Measurements taken before, during, and after bed rest.
Changes in mitochondrial content in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Via the assessment in succinate dehydrogenase activity.
Changes in subjective pain via visual analog scale in response to bed rest with and without ketone monoester (KET) supplementation.	Day 5-10.	Throughout the 5 day bed rest period.
Physical activity level via accelerometer before bed rest.	Day 0-4.	Throughout the baseline period
Changes in cognitive status in response to bed rest with and without ketone monoester (KET) supplementation.	Day 4 and Day 9.	NIH Toolbox Cognition Battery (computerized). Measurements taken before and after bed rest
Changes in muscle mRNA expression of inflammatory regulators will be assessed in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Muscle mRNA expression of NFKB1, TLR-4,IL-6, TNF-alpha, and IL-1Beta will be evaluated. Measurements taken before and after bed rest
Changes in the phosphorylation status of catabolic signaling molecules modulating muscle protein breakdown (MPB) in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Western blotting - membranes will be probed with phospho-specific antibodies against FoxO3aThr32, MuRF1, and MAFbx. Measurements taken before and after bed rest.
Changes in resting metabolic rate (RMR) in response to bed rest with and without ketone monoester (KET) supplementation.	Day -3 and Day 10.	Measurements taken before and after bed rest.
Changes in sleep disturbance (numerical score) during bed rest with and without ketone monoester (KET) supplementation.	Day 5-10.	Via Patient-Reported Outcomes Measurement Information System (PROMIS) Short form 8a. Measured throughout the 5 day bed rest period.
Changes in Thigh Absolute Protein Breakdown Rate (ABR) in response to bed rest with and without ketone monoester (KET) supplementation.	Day 0-5 and day 5-10	Changes in Thigh Absolute Protein Breakdown Rate (ABR) will be calculated during baseline (day 0-5) and bed rest (day 5-10) phases.
Changes in Thigh Absolute Synthetic Rate (ASR) in response to bed rest with and without ketone monoester (KET) supplementation.	Day 0-5 and day 5-10	Changes in Thigh Absolute Synthetic Rate (ASR) will be calculated during baseline (day 0-5) and bed rest (day 5-10) phases.
2H-alanine enrichment in venous blood before and during bed rest with and without ketone monoester (KET) supplementation.	Day -1 to Day 10.	Throughout the baseline and bed rest period.
Changes in sleep quality (numerical score) during bed rest with and without ketone monoester (KET) supplementation.	Day 5-10.	Via Pittsburgh Sleep Quality Index (PSQI). Measured throughout the 5 day bed rest period.
Average habitual dietary intake assessed using Keenoa for 3 days (a food tracker application).	Measured before bed rest.	Dietary intake will be assessed for total energy (kcals) and macronutrient (protein, carbohydrate, and fat consumption; g) intake.

Trial Locations

Locations (1)

Research Institute - McGill University Health Centre; 🇨🇦 Montréal, Quebec, Canada