Modern living is associated with an epidemic of type 2 diabetes mellitus (T2DM). Sleep disturbances such as insomnia or frequent awakenings are strong risk factors for T2DM with several studies indicating a central role of melatonin. Additionally, a certain single nucleotide polymorphism in the melatonin receptor gene, MTNR1B rs10830963, with an allele frequency of 30 %, is associated with increased fasting plasma glucose and T2DM. Due to treatment of, among other things, insomnia, the use of melatonin is increasing rapidly in Denmark with a 100-fold increase from 2007-2012 in children and adolescents. No previous studies have thoroughly assessed changes in glucose and fatty acid metabolism after 3 months of melatonin treatment in patients with T2DM.
Modern living is associated with an epidemic of type 2 diabetes mellitus (T2DM). Sleep disturbances such as insomnia or frequent awakenings are strong risk factors for T2DM with several studies indicating a central role of melatonin. Additionally, a certain single nucleotide polymorphism in the melatonin receptor gene, MTNR1B rs10830963, with an allele frequency of 30 %, is associated with increased fasting plasma glucose and T2DM. Due to treatment of, among other things, insomnia, the use of melatonin is increasing rapidly in Denmark with a 100-fold increase from 2007-2012 in children and adolescents. No previous studies have thoroughly assessed changes in glucose and fatty acid metabolism after 3 months of melatonin treatment in patients with T2DM. Main research questions: 1. Does chronic melatonin treatment change insulin secretion in T2DM patients? 2. Does chronic melatonin treatment change insulin sensitivity in T2DM patients? 3. Does the MTNR1B rs10830963 risk allele alter the insulin secretion and insulin sensitivity compared with carries of the normal variant after chronic melatonin treatment? 4. Does chronic melatonin treatment change insulin signalling in muscle - and adipose tissue? Design: A randomized, double-blinded, placebo controlled, crossover study, including 18 participants with T2DM. We aim to recruit 9 homozygous carriers of the normal allele and 9 hetero - or homozygous for the risk allele. Participants will be examined on two occasions, 1) after 3 months of daily melatonin treatment before bedtime (10 mg), and 2) after 3 months of daily placebo treatment before bedtime. On the study days, participants will initially undergo a basal period with glucose - and palmitate tracer infusions to assess endogenous glucose production and free fatty acid production. Afterwards a Botnia clamp, which combines an intravenous glucose tolerance test and a hyperinsulinemic euglycemic clamp, will be performed to assess β-cell function and insulin sensitivity. On both study days muscle - and fat biopsies will be performed under both basal and hyperinsulinemic euglycemic conditions. Perspectives: It is highly relevant to evaluate the chronic effects of melatonin on glucose - and fat metabolism given the increase in melatonin consumption. Furthermore, the study may open for new treatment options of T2DM if beneficial effects of oral melatonin are detected.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
TRIPLE
Enrollment
17
Melatonin treatment
Placebo treatment
Medical Research Laboratory
Aarhus, Denmark
Change of insulin sensitivity
Insulin sensitivity is assessed by a hyperinsulinemic euglycemic clamp, unit: mg/kg/min (mg of glucose to maintain euglycemia per kilogram of weight per minuts)
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment and compared afterwards with a paired T-tes
Change of insulin secretion change
Insulin secretion is assessed by an intravenous glucose tolerance test, unit: pmol/L (insulin)
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
MTNR1a rs10830963 influence on change in insulin sensitivity and insulin secretion
MTNR1a rs10830963 genotype influence on insulin sensitivity and insulin secretion (see outcome 1 + 2)
Time frame: The outcome will be measured after 3 months of placebo treatment and again after 3 months of melatonin treatment
Change of insulin signalling
Insulin signalling in muscle and adipose tissue assessed by western blot
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
Change of ambulatory blood pressure
Ambulatory blood pressure assessed with Mobil-O-graph, I.E.M., Stolberg, Germany (Unit: mmHg)
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
Change of arterial stiffness
Arterial stiffness assessed with Mobil-O-graph, I.E.M., Stolberg, Germany (unit: m/s)
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
Change of gut microbiome
Feces analysis of microbial mRNA
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
Change of sleep evaluation 1
Pittsburg Sleep Quality Index Questionnaire (Points on a scale: range 0-57)
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
Change of sleep evaluation 2
Epworth Sleepiness Scale Questionnaire (Points on a scale: range 0-24)
Time frame: After 3 months treatmentThe outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
Change of psychological health 1
Major Depression Inventory Questionnaires (points on a scale: range 0-65)
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
Change of psychological health 2
World Health Organization 5 Questionnaires (points on a scale: range 0-25)
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
Hormonal changes
Ghrelin, HbA1c, GLP-1, GLP-2, GIP, free fatty acids (FFA), leptin, cytokines, adiponectin, growth hormone, cortisol, hsCRP, CD163, MBL, IGF-1 and proinsulin measured by ELISA, RIA, or routine biochemical analysis. Unit: pmol/L
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
Change of glucose and palmitate kinetics
Tracer technique with infusion of radioactive labeled glucose and palmitate for determination of rate of appereance. Unit: mikromol/min
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
Change of regional glucose and palmitate uptake
Forearm model with arteriovenous differences of glucose and palmitate (Arterial glucose minus venous glucose = forearm uptake (unit mmol/l). The same applies for palmitate
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
Change of DEXA-scans
Evaluation of body composition and bone mineral density by DEXA-scan
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
Change of assessment of respiratory quotient (RQ)
Assessment of respiratory quotient (RQ) with indirect calorimetry (unit: VCO2/VO2)
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
Change of assessment of resting energy expenditure (REE)
Assessment of resting energy expenditure (REE) with indirect calorimetry (Unit J/s)
Time frame: The outcome will be measured after 3 months of placebo treatment and after 3 months of melatonin treatment
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