Effect of ACE Genotype on Cardiovascular Rehabilitation

Phase 2

Terminated

• Conditions: Cardiovascular Disease
• Interventions: Behavioral: eccentric cardiovascular training; Behavioral: concentric cardiovascular training; Genetic: ACE genotyping

• Registration Number: NCT02845063
• Lead Sponsor: Balgrist University Hospital

Brief Summary

The study aims to systematically investigate the interaction between training modality, ACE genotype and disease in heart patients whom complete a cardiovascular rehabilitation program. This is carried out with the goal to improve the benefit of cardiovascular rehabilitation for the patient by maximising adjustments in muscle structure and function with the intervention. A population of healthy individuals will be recruited who will carry out the same training program, in order to compare the training effects respective to the general population.

Detailed Description

Pharmacological inhibition of angiotensin converting enzyme modifies exercise-induced pro-angiogenic and mitochondrial gene transcript expression. Exercise-induced muscle plasticity importantly interacts with the insertion/deletion genotype of ACE and the training modality and intensity. The aim of this study is to systematically investigate the interaction between training modality, ACE genotype and disease in heart patients whom complete a cardiovascular rehabilitation program.

There are two training modalities being used: The first modality involves cardiovascular training by an interval type of protocol that includes a high repetition number of shortening (i.e. concentric) type contractions on a softrobotic device. The second modality includes a high repetition number of lengthening (i.e. eccentric) type contractions on a softrobotic device. In both training modalities the same muscle groups are exercised over the same range of motion, with the same speed of movement, but with widely differing pedal force. Total absolute external mechanical work will be matched.

In order to assess the baseline values and the effect size of the muscle and training adjustments made, healthy male and female volunteers will be included who are matched with respect to age and sex to the patient population and undergo the same training program.

Study Timeline

• Study First Submitted: 2015-11-27
• Study Start: 2016-05-01
• Study First Submitted QC: 2016-07-22
• Study First Posted: 2016-07-27
• Primary Completion: 2019-01-01
• Study Completion: 2020-01-01
• Status Verified: 2023-08
• Last Update Submitted: 2023-08-14
• Last Update Posted: 2023-08-16

Recruitment & Eligibility

• Status: TERMINATED
• Sex: All
• Target Recruitment: 60

Inclusion Criteria

Not provided

Exclusion Criteria

Not provided

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: FACTORIAL

Arm && Interventions

Group	Intervention	Description
eccentric cardiovascular training	eccentric cardiovascular training	Healthy subjects will be enrolled in the intervention 'eccentric cardiovascular training' and evaluated by the intervention 'ACE genotyping'
eccentric cardiovascular training	ACE genotyping	Healthy subjects will be enrolled in the intervention 'eccentric cardiovascular training' and evaluated by the intervention 'ACE genotyping'
eccentric cardiovascular rehabilitation	eccentric cardiovascular training	Heart patients under ACE inhibitor intake will be enrolled in the intervention 'eccentric cardiovascular training' and evaluated by the intervention 'ACE genotyping'
eccentric cardiovascular rehabilitation	ACE genotyping	Heart patients under ACE inhibitor intake will be enrolled in the intervention 'eccentric cardiovascular training' and evaluated by the intervention 'ACE genotyping'
concentric cardiovascular training	ACE genotyping	Healthy subjects will be enrolled in the intervention 'concentric cardiovascular training' and evaluated by the intervention 'ACE genotyping'
concentric cardiovascular rehabilitation	concentric cardiovascular training	Heart patients under ACE inhibitor intake will be enrolled in the intervention 'concentric cardiovascular training' and evaluated by the intervention 'ACE genotyping'
concentric cardiovascular rehabilitation	ACE genotyping	Heart patients under ACE inhibitor intake will be enrolled in the intervention 'concentric cardiovascular training' and evaluated by the intervention 'ACE genotyping'
concentric cardiovascular training	concentric cardiovascular training	Healthy subjects will be enrolled in the intervention 'concentric cardiovascular training' and evaluated by the intervention 'ACE genotyping'

Primary Outcome Measures

Name	Time	Method
Cellular muscle characteristics - fiber type %	975 days: May 2016-January 2019	• Distribution of type I, IIA and IIX fibers \[%\]
Muscle metabolism - hemoglobin ramp	975 days: May 2016-January 2019	• Total hemoglobin during ramp test on ergometer \[%\]
Molecular muscle characteristics - mRNA	975 days: May 2016-January 2019	• mRNA expression of VEGF, HIF-1a, HIF-1b, tenascin-C, Angpt1, Angpt1R, neuropilin, midkine, restin, COX4-1, COX4I-2, CPTI, LPL, LIPE, FATP, CD36 \[relative expression per 28S rRNA\]
Molecular muscle characteristics- phosphorylation	975 days: May 2016-January 2019	• Phosphorylation of proteins phospho-Y397- FAK, phospho-T421/S424-P70S6K, phospho -T183/Y185-JNK, phospho-S2448-mTOR \[pixel counts per actin\]
Cellular muscle characteristics - fiber type CSA	975 days: May 2016-January 2019	• Cross sectional area of type I, IIA and IIX fibers \[micrometer2\]
ACE I/D genotype	975 days: May 2016-January 2019	Genotype of the assessed insertion/deletion gene polymorphism of angiotensin converting enzyme ACE, i.e. ACE-II, ACE-ID or ACE-DD.
Molecular muscle characteristics- protein	975 days: May 2016-January 2019	• Protein content of FAK, FRNK, p70S6K, mTOR, JNK, NDUFA9, SDH, UQCRC1, COX4I1, COX4I2, ATP5A1, VEGF, HIF-1a, CD31, MHC-1, MHC-2A, MHC-2X, MyoD, myogenin, CaMKII \[pixel counts per actin\]
Molecular muscle characteristics- ACE	975 days: May 2016-January 2019	• ACE activity \[fmol min-1\]
Cellular muscle characteristics - fiber area %	975 days: May 2016-January 2019	• Area percentage of type I, IIA and IIX fibers \[% area\]
Cellular muscle characteristics - Capillary density	975 days: May 2016-January 2019	• Capillary density \[capillaries micrometer-2\]
Cellular muscle characteristics - Capillary-to-fiber ratio	975 days: May 2016-January 2019	• Capillary-to-fiber ratio
Functional muscle characteristics - Maximal Power	975 days: May 2016-January 2019	• Maximal power during ramp test on ergometer \[Watt\]
Functional muscle characteristics - Critical Power	975 days: May 2016-January 2019	• Critical power in ramp test on ergometer \[Watt\]
Functional muscle characteristics - Real Power	975 days: May 2016-January 2019	• Real Power as estimated on the soft robotic device \[Watt\]
Functional muscle characteristics - Negative Power	975 days: May 2016-January 2019	• Negative Power as estimated on the soft robotic device \[Watt\]
Muscle metabolism - hemoglobin robot exercise	975 days: May 2016-January 2019	• Total hemoglobin during exercise on soft robot \[%\]
Muscle metabolism - serum glucose	975 days: May 2016-January 2019	• Concentration of glucose in serum during ramp test on ergometer \[mmol l-1\]
Cardiovascular function - Heart rate rest	975 days: May 2016-January 2019	• Heart rate at rest \[beats per minute\]
Cardiovascular function - Heart rate ramp	975 days: May 2016-January 2019	• Heart rate in ramp test on ergometer \[beats per minute\]
Cardiovascular function - ventilation	975 days: May 2016-January 2019	• Ventilation during ramp test on ergometer \[L min-1\]
Functional muscle characteristics - Reactive Power	975 days: May 2016-January 2019	• Reactive Power as estimated on the soft robotic device \[Watt\]
Muscle metabolism - serum lactate	975 days: May 2016-January 2019	• Concentration of lactate in serum during ramp test on ergometer \[mmol l-1\]
Cardiovascular function - ejection fraction	975 days: May 2016-January 2019	• Ejection fraction
Functional muscle characteristics - Maximal force	975 days: May 2016-January 2019	• Maximal force during the reactive power test on the soft robotic device \[Newton\]
Functional muscle characteristics - Maximal velocity	975 days: May 2016-January 2019	• Maximal velocity during the reactive power test on the soft robotic device \[m sec-1\]
Functional muscle characteristics - Rate of force development	975 days: May 2016-January 2019	• Rate of force development as estimated during the Real Power test on the soft robotic device \[meter sec-2\]
Muscle metabolism - muscle oxygenation ramp	975 days: May 2016-January 2019	• Muscle oxygenation (m. vastus lateralis, m. gastrocnemius, m. gluteus maximus) during ramp test on ergometer \[%\]
Muscle metabolism - muscle oxygenation robot exercise	975 days: May 2016-January 2019	• Muscle oxygenation (m. vastus lateralis, m. gastrocnemius, m. gluteus maximus) during exercise on soft robot \[%\]
Muscle metabolism - lipid compounds	975 days: May 2016-January 2019	• Concentration of lipid compounds in m. vastus lateralis muscle during exercise on soft roboter
Muscle metabolism - metabolites	975 days: May 2016-January 2019	• Concentration of metabolites in m. vastus lateralis muscle during exercise on soft roboter
Cardiovascular function - cardiac output	975 days: May 2016-January 2019	• Cardiac output \[L min-1\]
Cardiovascular function - Maximal oxygen uptake	975 days: May 2016-January 2019	• Maximal oxygen uptake (VO2max) during ramp test on ergometer \[ml O2 min-1 kg-1\]
Cardiovascular function - respiration quotient	975 days: May 2016-January 2019	• Respiration quotient during ramp test on ergometer \[ L O2 inspired / L CO2 expired\]
Cardiovascular function - endurance	975 days: May 2016-January 2019	Time-to-exhaustion in constant load on ergometer \[seconds\]
Cardiovascular function - ventilation frequency	975 days: May 2016-January 2019	• Ventilation frequency ramp test on ergometer \[min-1\]

Trial Locations

Locations (2)

University Hospital Zurich; 🇨🇭 Zurich, Switzerland

Balgrist University Hospital; 🇨🇭 Zurich, Switzerland