Fish Oil and Adaptations to Resistance Exercise in Older People

Not Applicable

Completed

• Conditions: Ageing
• Interventions: Behavioral: Resistance Exercise Training; Dietary Supplement: Supplementation

• Registration Number: NCT02843009
• Lead Sponsor: University of Glasgow

Brief Summary

Skeletal muscle is the largest organ in the human body and has many important roles in determining our physical abilities and overall wellbeing. One major function of skeletal muscle is to carry out many daily tasks, such as rising from a chair or getting on a bus, tasks often referred to as functional abilities. During healthy ageing muscle size is reduced by approximately 0.5-2% a year (known as sarcopenia), with concurrent reductions in functional abilities. This can result in a reduction in quality of life and loss of independence, both of which are clearly not desirable. The incidence of sarcopenia is around 20% between 50-70 years and around 50% in those over 80 years, with the absolute numbers and the average age of the population rising. One method through which muscle function can be enhanced and retard the progression of sarcopenia, across all age groups, is through exercise. The effectiveness of exercise will depend on a number of genetic and environmental factors, with nutritional intake being one of the most important and easily altered. Recent research has suggested that altering the type of fatty acids consumed may have a positive effect on muscle function. Little research is yet to be carried out in elderly humans. This is important as that findings from animal models are not definitively transferrable to humans. The main aim of the current proposal, therefore, is to investigate the effect the consumption of eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA), long chain polyunsaturated fatty acids found in oily fish, on the response to a resistance training programme in the elderly. A further aim is to determine the mechanisms which result in these adaptive responses. The project will be centred round a large 18 week resistance training/nutritional (EPA/DHA) intervention with both males and females over the age of 65 years. There are three main research questions and experiments stemming from this intervention. 1) Does the consumption of EPA and DHA result in a greater increase in strength, power and functional abilities in response to resistance training? To answer this question a series of measures of muscular performance and functional abilities will be assessed. 2) Does the consumption of EPA and DHA increase the size and quality of muscles, reduce the amount of fat found within the muscle and decrease inflammation? To address this question the participants will have MRI images of their muscles and blood samples taken before and after the intervention. This will allow the calculation of muscle mass/fat content and circulating levels of inflammatory markers. 3) Does the consumption of EPA and DHA enhance the activity of the molecules involved in controlling muscle mass after a single bout of resistance exercise? For this question muscle samples will be obtained before and after a single training session and measure changes in molecules previously identified as important in the changes in muscle mass in response to exercise. A fourth aim running throughout the proposal is 4) Do males and females respond differently to the combination of EPA/DHA and resistance exercise? Differences in protein metabolism have previously been noted between genders and yet the investigation of these differences is often overlooked. The investigators will investigate this by studying responses in groups of males and females. In summary, the aim of the proposed project is to test the hypothesis that the consumption of fatty acids found in oily fish will improve the response of an elderly population to a resistance training intervention. The major outcome of the proposal would be in establishing a beneficial effect of fish oil on muscular adaptation in the elderly, opening up a widely available therapeutic strategy for an improvement in the quality of life in the elderly population. Such strategies are of particular importance due to the increasing age of the UK population.

Detailed Description

Not available

Study Timeline

• Study Start: 2012-09
• Primary Completion: 2015-09
• Study Completion: 2015-09
• Status Verified: 2016-07
• Study First Submitted: 2016-07-18
• Study First Submitted QC: 2016-07-20
• Last Update Submitted: 2016-07-20
• Study First Posted: 2016-07-25
• Last Update Posted: 2016-07-25

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 58

Inclusion Criteria

• Over 65 years of age
• Not consuming oily fish regularly
• Not consuming nutritional supplements
• Not participating in resistance exercise training

Exclusion Criteria

• History of myocardial infarction within previous 2 years
• Cardiac illness: moderate/ severe aortic stenosis, acute pericarditis, acute myocarditis, aneurysm, severe angina, clinically significant valvular disease, uncontrolled dysrhythmia, claudication within the previous 10 years
• Thrombophlebitis or pulmonary embolus within the previous 2 years
• History of cerebrovascular disease (CVA or TIA) within the previous 2 years
• Acute febrile illness within the previous 3 months
• Severe airflow obstruction
• Uncontrolled metabolic disease (e.g., thyroid disease or cancer)
• Significant emotional distress, psychotic illness or depression within the previous 2 years
• Lower limb fracture sustained within the previous 2 years; upper limb fracture within the previous 6 months; non arthroscopic lower limb joint surgery within the previous 2 years
• Any reason for loss of mobility for greater than 1 week in the previous 2 months or greater than 2 weeks in the previous 6 months
• Poorly controlled atrial fibrillation
• Poor (chronic) pain control
• Resting systolic pressure >200 mmHg or resting diastolic pressure >100 mmHg
• Moderate/ severe cognitive impairment (MMSE <23)
• Impaired tissue viability (defined by a Waterlow risk assessment score >15).

Based on Greig C.A. et al. Age Ageing 1994, 23: 185-9

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
Fish Oil plus Resistance Exercise Training	Resistance Exercise Training	3.0g of fish oil taken daily alongside twice weekly resistance exercise training sessions for 18 weeks
Safflower Oil plus Resistance Exercise Training	Resistance Exercise Training	3.0g of safflower oil taken daily alongside twice weekly resistance exercise training sessions for 18 weeks
Safflower Oil plus Resistance Exercise Training	Supplementation	3.0g of safflower oil taken daily alongside twice weekly resistance exercise training sessions for 18 weeks
Fish Oil plus Resistance Exercise Training	Supplementation	3.0g of fish oil taken daily alongside twice weekly resistance exercise training sessions for 18 weeks

Primary Outcome Measures

Name	Time	Method
Maximal Isometric Knee Extensor Torque	Change from baseline at 18 weeks

Secondary Outcome Measures

Name	Time	Method
Muscle protein synthesis	18 weeks
Short Performance Physical Battery Test	Change from baseline at 18 weeks
Maximal Isokinetic Knee Extensor Torque (30,90 and 120 degrees/s)	Change from baseline at 18 weeks
Quadriceps Cross Sectional Area (MRI)	Change from baseline at 18 weeks
Circulating markers of inflammation (IL-6 and TNF-alpha)	Change from baseline at 18 weeks
Muscle P70s6k activity	Change from baseline to 2h post-exercise
Erythrocyte fatty acid composition	Change from baseline at 18 weeks
Muscle membrane fatty acid composition	18 weeks

Trial Locations

Locations (1)

University of Aberdeen; 🇬🇧 Aberdeen, United Kingdom