RibOSE - Glucose and Resistance Exercise Training

Not Applicable

Completed

• Conditions: Healthy
• Interventions: Dietary Supplement: Glucose

• Registration Number: NCT04545190
• Lead Sponsor: Inland Norway University of Applied Sciences

Brief Summary

The aim of the study is to investigate the effects of ingesting glucose during five bouts of resistance exercise on muscle biological charateristics in m. vastus lateralis of moderately trained healthy individuals (20-45 years of age, n=20)

Detailed Description

Muscular responses to resistance training vary extensively between humans, with many showing impaired growth. In such individuals, cellular plasticity is compromised, leading to reduced functional and health-beneficial outcomes of training. While this is likely due to a range of determinants, including epigenetic, genetic and physiological variables, recent studies suggest that it involves reduced ability to produce novel ribosomes in response to training. This eventually leads to less pronounced increases in protein synthesis, and thus decreased growth rates, and makes ribosomal content in muscle a potential proxy marker for training-associated muscle hypertrophy.

In a recent study, the investigators showed that increased resistance training volume was associated with more pronounced muscle growth, a trait that was associated with increased ribosomal biogenesis. Despite this, \~50 % of the participants did not exhibit true beneficial effects of increased training volume, which in turn coincided with reduced abilities to accumulate ribosomes. In such individuals, other means are likely necessary to circumvent the negative influence of genetic and epigenetic predispositions on muscle plasticity. Nutrient supplementation stand out as a potential therapy. However, at present, knowledge with regard to this perspective is limited to a selected few nutrients, with protein ingestion being the best studied potential adjuvant, for which adequate intake seems to be essential for achieving optimal muscle growth, potentially being interconnected with ribosomal synthesis. For other nutrients, such as glucose, little is know about their importance for muscle plasticity and ribosomal biogenesis.

In cell types such as cultivated kidney cells, exposure to high levels of glucose is an efficient mean to increase ribosomal biogenesis (and growth rates). This suggests that glucose is an important signaling molecule for increasing ribosomal production per se, perhaps acting as a ligand for signaling proteins or by acting to increase energy availability. In the human body (as opposed to cultured cells), glucose may also exert growth-stimulating effects by increasing insulin levels in blood. Overall, it thus seems plausible that glucose intake during resistance training may stimulate ribosomal biogenesis, in turn having beneficial effects for protein synthesis and muscle plasticity, perhaps acting in an additive manner to protein supplementation. At present, we do not know if this is the case, though studies have suggested that glucose ingestion during acute resistance training sessions may reduce training-induced muscle damage without affecting within-session work output (i.e. volume). This lack of knowledge is surprising given the long-standing appreciation of the beneficial effects of glucose intake for endurance performance, acting to delay muscular fatigue.

Study Timeline

• Study First Submitted: 2020-08-24
• Study Start: 2020-09-01
• Study First Submitted QC: 2020-09-07
• Study First Posted: 2020-09-10
• Primary Completion: 2020-12-20
• Study Completion: 2020-12-20
• Status Verified: 2021-02
• Last Update Submitted: 2021-02-03
• Last Update Posted: 2021-02-04

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 16

Inclusion Criteria

• Non-smoking
• Moderately trained (i.e. having performed 2-8 resistance training sessions per 14 days for the last six months)

Exclusion Criteria

• Not able to understand Norwegian
• Unstable cardiovascular disease
• Illness or injury contradicting heavy strength training
• Disabling musculoskeletal disease
• Serious mental illness
• Allergy to local anaesthesia
• Impaired glucose tolerance

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: CROSSOVER

Arm && Interventions

Group	Intervention	Description
Glucose	Glucose	Glucose will be ingested at three time points during resistance training (RT): 30 min prior to RT (30 g glucose mixed with 300 ml sugar-free Fun light lemonade), immediately prior to RT (30 g, 300 ml), and immediately after completion of training (30 g, 300 ml). Protein supplement will be ingested at two time points: 2 hours prior to RT (e.g. at 0700 hrs, 25 g) and immediately after completion of training (25 g). Placebo will be ingested during the afternoon (i.e. not during training; between 1800 hrs and 1900 hrs): 3 x 100 mg Stevia powder mixed with 3 x 300 ml sugar-free Fun light lemonade. (The dietary intervention spans from 2200 hrs on the evening prior to RT sessions to \~2.5 hrs after completion of RT. During this time frame, participants will ingest glucose and protein supplements only)
Placebo	Glucose	Placebo will be ingested at three time points during resistance training (RT): 30 min prior to RT (100 mg Stevia powder mixed with 300 ml sugar-free Fun light lemonade), immediately prior to RT (100 mg, 300 ml), and immediately after completion of training (100 mg, 300 ml). Protein supplement will be ingested at two time points: 2 hours prior to RT (e.g. at 0700 hrs, 25 g) and immediately after completion of training (25 g). Glucose will be ingested during the afternoon (i.e. not during training; between 1800 hrs and 1900 hrs): 3 x 30 g glucose mixed with 3 x 300 ml sugar-free Fun light lemonade. (The dietary intervention spans from 2200 hrs on the evening prior to RT sessions to \~2.5 hrs after completion of RT. I.e.: during this period, participants will ingest placebo and protein supplements only)

Primary Outcome Measures

Name	Time	Method
Total RNA in muscle tissue	Before the intervention and immediately after the intervention (i.e. after 5 training sessions of each leg)	Total RNA content in m. vastus lateralis (ug per mg tissue)

Secondary Outcome Measures

Name	Time	Method
Gene expression in skeletal muscle	Before the intervention and immediately after the intervention (i.e. after 5 training sessions of each leg)	Abundances of mRNA species in m. vastus lateralis measured using qPCR
Muscle fractional synthesis rate	Immediately after the intervention	Protein synthesis rate measured using heavy water (deuterium) and chromatography/spectrometry
Glucose in blood, after glucose/placebo intake	Immediately before glucose/placebo intake and 30 min, 45 min, 60 min and 195 min after initial glucose/placebo intake	Glucose concentrations in blood (area under the curve), measured before and after intake of glucose/placebo on the two final days of the intervention (one day = glucose; one day = placebo)
Glucose in blood (after protein intake)	Immediately before protein intake and 45 min and 90 min after protein intake	Glucose concentrations in blood (area under the curve), measured before and after intake of protein on the two final days of the intervention
Perceived muscle soreness (during the intervention)	Before the intervention and 24 hours after each training session	Muscular soreness measured before the intervention and at three time points during the intervention (\~24 hours after training sessions) using a VAS-scale from 0 to 10 (0 = no soreness; 10 = maximal soreness)
Ribosomal RNA in skeletal muscle	Before the intervention and immediately after the intervention (i.e. after 5 training sessions of each leg)	Abundances of ribosomal RNA species in m. vastus lateralis measured using qPCR
Protein in skeletal muscle	Before the intervention and immediately after the intervention (i.e. after 5 training sessions of each leg)	Abundances of protein species in m. vastus lateralis measured using Western blotting (e.g. ECM proteins)
Hormone concentrations in blood (after glucose/placebo intake)	Immediately before glucose/placebo intake and 30 min and 60 min after the initial glucose/placebo intake	Abundances of insulin, c-peptide, testosterone, growth hormone, cortisol and inflammatory markers in blood (area under the curve), measured before and after intake of glucose/placebo on the two final days of the intervention (one day = glucose; one day = placebo)
Unilateral lower body isometric muscle strength (during the intervention)	Before the intervention and after the second, fourth and sixth training session	The ability of the knee extensors to exert maximal force during isometric actions (recovery/strength), measured before the intervention and at three time points during the intervention (\~24 hours after training sessions)
Perceived feeling of the legs (during the intervention)	30 min after each training session	Feeling of the legs measured immediately after each training session using a 9-point scale (1 = very very good, 9 = very very heavy)
Hormone concentrations in blood (after protein intake)	Immediately before protein intake and 90 min after protein intake	Abundances of insulin, c-peptide, testosterone, growth hormone, cortisol and inflammatory markers in blood, measured after intake of protein on the two final days of the intervention
Unilateral lower body isokinetic muscle strength (during the intervention)	Before the intervention and after the second, fourth and sixth training session	The ability of the knee extensors to exert maximal force during isokinetic movements (recovery/strength), measured before the intervention and at three time points during the intervention (\~24 hours after training sessions)
Unilateral lower body isokinetic muscle strength (last days of the intervention)	Before the last training session and 30 min, 120 min and 24 hours after the last training session	The ability of the knee extensors to exert maximal force during isokinetic movements (recovery/strength), measured before and at three time points after the last two training sessions (one day = glucose; one day = placebo)
Unilateral lower body isometric muscle strength (last days of the intervention)	Before the last training session and 30 min, 120 min and 24 hours after the last training session	The ability of the knee extensors to exert maximal force during isometric actions (recovery/strength), measured before and at three time points after the last two training sessions (one day = glucose; one day = placebo)

Trial Locations

Locations (1)

Inland Norway University of Applied Sciences; 🇳🇴 Lillehammer, Norway