Mitochondrial Energy Metabolism in Obese Women
27. april 2019 oppdatert av: Julio Sergio Marchini, University of Sao Paulo
Mitochondrial Energy Metabolism in Obese Women Undergoing Concurrent Physical Training
Considering that the failure of the treatment of obesity is justified by the multifactorial pathophysiology of this morbidity, the present project has the following hypotheses:
- The occurrence of obesity is due to the derange,ent of mitochondrial energy metabolism ;
- The unbalance is therapeutically modified through physical training ;
- Obesity courses with the break-down in energy metabolism mitochondrial disease associated with systemic inflammatory characteristics that can be corrected through a combined long-term physical training program.
This study have as objective : to analyse changes in mitochondrial function, inflammatory profile, oxidative stress and energy metabolism caused by concurrent physical training in obese women.
Studieoversikt
Status
Fullført
Intervensjon / Behandling
Detaljert beskrivelse
Specific objectives:
Body composition by deuterium oxide; Metabolic rate of resting and oxidation of substrates by indirect calorimetry; Proinflammatory cytokines Anti-inflammatory cytokines Oxidative Stress: Malondialdehyde, Superoxide Dismutase, Glutathione-Peroxidase; Fatty acids: ceramide and palmitate; Mitochondrial respiration and citrate synthase enzyme; Quantify and qualify: mitochondrial number, endoplasmic reticulum structure, adipose cell size; Gene expression, quantify by microscopy and analyze the protein by western blot.
The study began with 20 women, however, there was withdrawal of 6, ending with 14 women.
Studietype
Intervensjonell
Registrering (Faktiske)
14
Fase
- Ikke aktuelt
Kontakter og plasseringer
Denne delen inneholder kontaktinformasjon for de som utfører studien, og informasjon om hvor denne studien blir utført.
Studiesteder
-
-
SP
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Ribeirao Preto, SP, Brasil, 14.048-900
- Camila Fernanda Cunha Brandão
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-
Deltakelseskriterier
Forskere ser etter personer som passer til en bestemt beskrivelse, kalt kvalifikasjonskriterier. Noen eksempler på disse kriteriene er en persons generelle helsetilstand eller tidligere behandlinger.
Kvalifikasjonskriterier
Alder som er kvalifisert for studier
20 år til 40 år (Voksen)
Tar imot friske frivillige
Nei
Kjønn som er kvalifisert for studier
Hunn
Beskrivelse
Inclusion Criteria:
- This study included women with obesity (BMI of 30 to 40 kg / m²), sedentary, with no associated comorbidity, convenience sample
Exclusion Criteria:
- Women who have undergone bariatric surgery, menopause, cancer or any metabolic disease, smokers, alcoholics, who are in use of drugs that act directly on the metabolism and that have medical impediment to the practice of physical exercise.
Studieplan
Denne delen gir detaljer om studieplanen, inkludert hvordan studien er utformet og hva studien måler.
Hvordan er studiet utformet?
Designdetaljer
- Primært formål: Behandling
- Tildeling: N/A
- Intervensjonsmodell: Enkeltgruppeoppdrag
- Masking: Ingen (Open Label)
Våpen og intervensjoner
Deltakergruppe / Arm |
Intervensjon / Behandling |
|---|---|
|
Annen: Physical Training
There was concurrent physical training intervention: strength and aerobic exercises in the same session. Duration: 2 weeks of adaptation and learning to exercise, 8 weeks of physical training. Frequency: 3 times per week Duration: 55 minutes each session. Intensity: 75 to 90% of maximum heart rate. |
Intervention with concurrent physical training: strength and aerobic exercises in the same session. Duration: 2 weeks of adaptation to physical exercise, 8 weeks of training. Frequency: 3 times a week. Time: 55 minutes each session. Intensity: 75 to 90% of maximum heart rate. |
Hva måler studien?
Primære resultatmål
Resultatmål |
Tiltaksbeskrivelse |
Tidsramme |
|---|---|---|
|
Changes Body weight
Tidsramme: Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
Body weight was measured by digital balance before and after the intervention
|
Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
|
Changes Body composition
Tidsramme: Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
The change in body composition through deuterium oxide was evaluated.
|
Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
|
Changes White adipose tissue biopsy
Tidsramme: Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
A subcutaneous tissue sample was collected for analysis of: mitochondrial respiration, citrate synthase enzyme, gene expression (UCP1, 2 and 3).
|
Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
|
Changes Indirect calorimetry
Tidsramme: Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
With a gas analyzer (indirect calorimeter), we evaluated the metabolic rate and rest (REE) and oxidation of substrates (Lipids and carbohydrates).
|
Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
|
Changes in fatty acids
Tidsramme: Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
Collected in lithium heparin tubes, they were centrifuged.
|
Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
|
Changes oxidative stress
Tidsramme: Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
Collected in lithium heparin tubes, they were centrifuged.
|
Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
|
Changes inflammatory cytokines
Tidsramme: Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
Collected in lithium heparin tubes, they were centrifuged.
|
Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
|
Changes in total cholesterol
Tidsramme: Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
Collected in lithium heparin tubes, they were centrifuged.
|
Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
|
Changes Physical Performance
Tidsramme: Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
Based on the Shuttle Walking Test adaptation.
|
Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
|
Changes in Determination of Lactate
Tidsramme: Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
Blood samples were collected by manual puncture of the earlobe in previously calibrated and heparinized capillary tubes, stored in eppendorf with sodium fluoride.
Analyzed by electrochemical lactate analyser.
|
Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
|
Changes Food intake
Tidsramme: Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
Food registry of 3 days, the quantification of the daily intake of nutrients will still be made using software.
|
Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
|
Changes Nitrogen Balance
Tidsramme: Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
Through the collection of urine of 24 hours the dosage of urinary nitrogen will be made by the chemiluminescence method for determination of protein nitrogen.
|
Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
|
Changes Telomere length
Tidsramme: Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
peripheral blood in ethylenediaminetetraacetic acid tubes and genomic DNA was automatically extracted from Peripheral Blood Mononuclear Cell.
The relative quantification of Telomere length was determined using the telomere to single copy gene ratio by Quantitative Polymerase Chain Reaction (qPCR).
|
Two times: (1) First day and (2) 10 weeks after adaptation and intervention
|
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Sponsor
Publikasjoner og nyttige lenker
Den som er ansvarlig for å legge inn informasjon om studien leverer frivillig disse publikasjonene. Disse kan handle om alt relatert til studiet.
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Studierekorddatoer
Disse datoene sporer fremdriften for innsending av studieposter og sammendragsresultater til ClinicalTrials.gov. Studieposter og rapporterte resultater gjennomgås av National Library of Medicine (NLM) for å sikre at de oppfyller spesifikke kvalitetskontrollstandarder før de legges ut på det offentlige nettstedet.
Studer hoveddatoer
Studiestart (Faktiske)
1. april 2016
Primær fullføring (Faktiske)
1. juli 2016
Studiet fullført (Faktiske)
15. september 2016
Datoer for studieregistrering
Først innsendt
10. april 2017
Først innsendt som oppfylte QC-kriteriene
13. april 2017
Først lagt ut (Faktiske)
18. april 2017
Oppdateringer av studieposter
Sist oppdatering lagt ut (Faktiske)
30. april 2019
Siste oppdatering sendt inn som oppfylte QC-kriteriene
27. april 2019
Sist bekreftet
1. april 2019
Mer informasjon
Begreper knyttet til denne studien
Ytterligere relevante MeSH-vilkår
Andre studie-ID-numre
- Process HCRP: 1.387.040/2016
Plan for individuelle deltakerdata (IPD)
Planlegger du å dele individuelle deltakerdata (IPD)?
NEI
Legemiddel- og utstyrsinformasjon, studiedokumenter
Studerer et amerikansk FDA-regulert medikamentprodukt
Nei
Studerer et amerikansk FDA-regulert enhetsprodukt
Nei
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