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Trials / Completed

CompletedNCT03789045

Metabolic Thresholds and Fat Utilization Points Correlation

New Methodological Approach to Metabolic Thresholds Detection; Examining Fat Utilization Points and Metabolic Thresholds Correlation Strength

Status
Completed
Phase
Study type
Observational
Enrollment
250 (actual)
Sponsor
Sport Studio Banja Luka · Academic / Other
Sex
All
Age
18 Years – 60 Years
Healthy volunteers
Accepted

Summary

To examine existence of connection between fat utilization points, both maximal and minimal with individual metabolic thresholds in different subjects. As a consequence, this innovative approach could offer a supplementary method for both aerobic and anaerobic thresholds detection as well as useful and practical exercise intensity selection marker.

Detailed description

This study aims to examine the existence of connection between metabolic thresholds and fat oxidation points in diverse group of subjects. From the physiological perspective, during exercise with increasing intensity, three phases of the body's energy utilization and two threshold points can be defined. These threshold points have been named metabolic thresholds and as such are considered as indicators of exercise capacities. Several authors have suggested, that the first threshold should be called the 'aerobic threshold' (AeT) and the second the 'anaerobic threshold' (AnT). The energy contribution from fat oxidation increases during low-to-moderate exercise intensities and then markedly declines when the intensity becomes high, at which point carbohydrates (CHO) remain the dominant energy substrate. A term used to describe exercise intensity where fat oxidation reaches optimum, is maximal fat oxidation point (FATmax) whereas exercise intensity matching the negligible fat oxidation is labelled FATmin. During physical activity, due to limited availability of CHO, subjects are more dependent on energy originating from fat when aiming to optimize endurance performance, body composition, optimize weight control and the metabolic rate. Exercise at the intensity eliciting FATmax revealed best results in treatment and prevention of obesity-associated conditions, cardio-vascular and pulmonary diseases by means of increase in maximal fat oxidation rates (MFO), insulin sensitivity, improvements in ventilator efficiency and cardiac output, demonstrating a significant role in the treatment of these impairments. As a follow-up, studies demonstrated how the lowest beneficial effect was observed when exercise was performed above intensity matching negligible fat oxidation rate (FATmin), contributing to diminished protection of exercise therapy. In consequence, increased cardio-metabolic demands of exercise performed above FATmin also have a higher impact on mortality rates in comparison to low-moderate aerobic exercise. Therefore, choosing appropriate exercise intensity may play a decisive role in decreasing risk factors accompanying obesity-associated conditions. Investigators aim to determine metabolic thresholds and fat oxidation points by using non-invasive breath-by-breath gas analysis during either treadmill or cycle ergometry. Metabolic thresholds will be detected by using gas analysis, via ventilatory parameters. Fat oxidation points will be determined using indirect calorimetry. Participants will perform graded ergometry test (2min stages and 1km/h or 50 W load increase), on either cycle or treadmill ergometer, till exhaustion to determine maximal oxygen uptake (VO2max), with gases being collected at the mouth level by using spiroergometry. The strength of the relationship between intensities matching VO2 at AeT and VO2 at FATmax will be assessed using the Pearson product moment (r) correlation coefficient with same being done for AnT and FATmin correlation. A coefficient of determination (R2) will be used to detect the proportion of existing variance. A paired t-test will be used to asses' differences between measured variables. Associated heart rate at the AeT/FATmax and AnT/FATmin will be used as training mean to identify proper training intensity. The time frame of the study is about 3 years, depending on the availability of the subjects. Planed study begin is early 2016. Participants will be every day clients of the Institution and will be recruited on a voluntary basis as they arrive to the testing facilities through this 3 years period.Through this 3 years period, statistical analysis of the collected data for each group of subjects will be performed and observations will be published. Up to 7 publications are expected to result from this research.

Conditions

Interventions

TypeNameDescription
DIAGNOSTIC_TESTMetabolic thresholds and fat oxidation points relationshipInvestigators aim to determine exercise intensity at which metabolic thresholds and fat oxidation points occur by using non-invasive breath-by-breath gas analysis during either graded treadmill or cycle ergometry test (2min stages and 1km/h or 50 W load increase) till exhaustion to determine maximal oxygen uptake (VO2max), with gases being collected at the mouth level. The strength of the relationship between AeT and at FATmax will be assessed using the Pearson product moment (r) correlation coefficient with same being done for AnT and FATmin correlation. A coefficient of determination (R2) will be used to detect the proportion of existing variance. A paired t-test will be used to asses' differences between measured variables. Bland-altman will be used to determine levels of agreement.

Timeline

Start date
2016-05-01
Primary completion
2022-12-30
Completion
2022-12-30
First posted
2018-12-28
Last updated
2023-01-20

Locations

1 site across 1 country: Bosnia and Herzegovina

Source: ClinicalTrials.gov record NCT03789045. Inclusion in this directory is not an endorsement.