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Trials / Terminated

TerminatedNCT02722902

Carnitine Infusion and Insulin Resistance

Impact of L-Carnitine Infusion on Lipid Induced Insulin Resistance

Status
Terminated
Phase
N/A
Study type
Interventional
Enrollment
17 (actual)
Sponsor
Maastricht University Medical Center · Academic / Other
Sex
Male
Age
18 Years – 40 Years
Healthy volunteers
Accepted

Summary

Insulin resistant subjects and type 2 diabetic patients are characterized by a decreased metabolic flexibility: a reduced capability to switch from fat oxidation in the basal state to carbohydrate oxidation in the insulin-stimulated state. This metabolic inflexibility is an early hallmark in the development of diabetes. Recent evidence suggests that a low carnitine availability may limit acetylcarnitine formation, thereby reducing metabolic flexibility. Thus, when substrate flux in the muscle is high, acetyl-CoA concentrations increase, leading to inhibition of pyruvate dehydrogenase (PDH) and thereby reducing glucose oxidation. The conversion of acetyl-CoA to acetylcarnitine relieves this acetyl-CoA pressure on PDH. To provide more direct insight into the effect of carnitine in preventing metabolic inflexibility and insulin resistance and to further explore the mechanism of action is the focus of this research. Here, we hypothesize that the capacity to form acetylcarnitine may rescue lipid-induced insulin resistance. To this end, insulin resistance will be induced by lipid infusion in healthy volunteers and it will be tested whether carnitine co-infusion can alleviate insulin resistance.

Detailed description

Rationale: Insulin resistant subjects and type 2 diabetic patients are characterized by a decreased metabolic flexibility: a reduced capability to switch from fat oxidation in the basal state to carbohydrate oxidation in the insulin-stimulated state. This metabolic inflexibility is an early hallmark in the development of diabetes. Recent evidence suggests that a low carnitine availability may limit acetylcarnitine formation, thereby reducing metabolic flexibility. Thus, when substrate flux in the muscle is high, acetyl-CoA concentrations increase, leading to inhibition of pyruvate dehydrogenase (PDH) and thereby reducing glucose oxidation. The conversion of acetyl-CoA to acetylcarnitine relieves this acetyl-CoA pressure on PDH. To provide more direct insight into the effect of carnitine in preventing metabolic inflexibility and insulin resistance and to further explore the mechanism of action is the focus of this research. Here, we hypothesize that the capacity to form acetylcarnitine may rescue lipid-induced insulin resistance. To this end, insulin resistance will be induced by lipid infusion in healthy volunteers and it will be tested whether carnitine co-infusion can alleviate insulin resistance. Objective: The primary objectives are to investigate whether L-carnitine infusion may rescue lipid-induced insulin resistance and whether L-carnitine infusion is improving metabolic flexibility in the state of lipid-induced insulin resistance. Furthermore, a secondary objective is to examine the molecular pathways of carnitine and acetylcarnitine, responsible for muscle insulin sensitivity. Study design: The current study is an interventional randomized crossover trial in which each subject serves as it owns control. Subjects will be blinded for the intervention. Study population: n=10, healthy young (18-40 years) male subjects will be included. Intervention (if applicable): Ten healthy subject will be subjected to the intervention of L-carnitine infusion. To investigate whether L-Carnitine infusion may rescue lipid induced insulin resistance and improve metabolic flexibility three intervention trials are included. The first trial includes lipid infusion combined with L-Carnitine infusion (=LIPID + CAR). In the second trial, L-carnitine infusion will be replaced by placebo infusion in the form of saline (= LIPID + PLAC) in order to investigate the effect of L-Carnitine. During the third trial, lipid infusion will be replaced by infusion of saline and will serve as a control for the lipid infusion (=SALINE + PLAC) and is necessary to investigate to what extend L-carnitine can rescue lipid induced insulin resistance. All three trials will be separated by at least one week. Subjects will be blinded, so no information about the infused substances will be provided to them. The three different trials will be allocated in a random order. Main study parameters/endpoints: The primary study endpoint is whole body insulin sensitivity, measured by the hyperinsulinemic-euglycemic clamp. Secondary endpoints are maximal acetylcarnitine concentrations after exercise, metabolic compounds in the blood and measurements regarding skeletal muscle metabolism in skeletal muscle tissue obtained by needle biopsies.

Conditions

Interventions

TypeNameDescription
DRUGCarnitorCARNITOR® (levocarnitine) is a carrier molecule in the transport of long-chain fatty acids L-Carnitine will be administrated intravenously as continuous infusion during the 6-hour hyperinsulinemic euglycemic clamp. The administration will start with a bolus of 15mg/kg for 10 minutes. Subsequently, continuous L-carnitine infusion of 10mg/kg will start for the remaining 350 minutes. across the inner mitochondrial membrane.
DIETARY_SUPPLEMENTIntraLipidLipid emulsion for infusion
DIETARY_SUPPLEMENTPlaceboSaline will be used as placebo

Timeline

Start date
2016-05-01
Primary completion
2017-06-01
Completion
2017-06-01
First posted
2016-03-30
Last updated
2018-04-26

Locations

1 site across 1 country: Netherlands

Source: ClinicalTrials.gov record NCT02722902. Inclusion in this directory is not an endorsement.