Exercise-related Fuel Metabolism and Glucose Stability in Individuals With Type 1 Diabetes Mellitus
Overview
- Phase
- Not Applicable
- Intervention
- Not specified
- Conditions
- Type 1 Diabetes Mellitus
- Sponsor
- Insel Gruppe AG, University Hospital Bern
- Enrollment
- 27
- Locations
- 1
- Primary Endpoint
- Amount of exogenous glucose required to maintain glycemia within a range between 7-10mM
- Status
- Completed
- Last Updated
- 9 years ago
Overview
Brief Summary
Whereas physical activity clearly results in improvements in glycemic control in type 2 diabetes, in individuals with type 1 diabetes (T1DM) the impact of exercise on blood sugar control is more complex. In type 1 diabetes T1DM the inability to reduce exogenous insulin levels during exercise is a key factor that contributes to an increased risk of exercise-induced hypoglycemia. Since rapid adaptation of insulin dosage may be especially difficult in patients on a multiple daily injection regimen, alternative strategies are required to improve exercise-associated glucose stability. There is increasing evidence that the combination of steady state continuous low to moderate intensity exercise with short bursts of high intensity exertion (eg in the form of sprints) is an effective, well tolerated, novel strategy to prevent exercise-related hypoglycemia. A further promising option to stabilize blood sugar levels during and after exercise may be the ingestion of fructose in addition to glucose in form of a sport drink.
Detailed Description
Background Regular physical activity enhances insulin sensitivity in both healthy subjects and patients with diabetes mellitus. However, while the effects of physical activity on glucose control are undoubtedly beneficial in patients with type 2 diabetes, exercise can cause major disturbances in blood glucose levels in type 1 diabetic individuals. Hypoglycemia is a common complication in patients with T1DM engaging in endurance activities such as running and cycling. So far there are limited strategies suggested to improve exercise-related blood sugar self-management. Current recommendations focus on variation in timing and dosage of insulin administration and adjustments in carbohydrate intake. Since rapid adaptation of insulin dosage may be difficult, alternative strategies to improve exercise-related glucose stability are required. Increasing evidence suggests that intermittent high intensity exercise (IHE), by triggering a counterregulatory hormone response, may counter-balance the risk of exercise-associated hypoglycemia. However, previous studies investigating IHE in T1DM were limited by heterogeneous study populations, comparably short exercise protocols, and deficits in standardization procedures. In addition, a comprehensive assessment of the underlying fuel metabolism has not been performed so far. As a consequence, the results remain controversial and their interpretation as well as applicability are restricted. A further alternative strategy to maintain stable glycemia during exercise may be deduced from recent studies in non-diabetic individuals suggesting that the combined ingestion of fructose and glucose during exercise provides the liver with an increased amount of gluconeogenic precursors, thereby reducing consumption of endogenous glycogen stores.Moreover, conversion of fructose into glucose and lactate may provide constant and efficient fuel for working muscles. However, studies assessing the impact of fructose ingestion during exercise in patients with T1DM have not been performed so far. Objective The investigators aim to assess the impact of two novel non-pharmaceutical and easily feasible approaches on exercise-related blood glucose stability and its underlying exercise-related fuel metabolism in patients with T1DM. Substudy A will assess the influence on exercise-related glycemia and fuel metabolism of an IHE protocol compared to an iso-energetic continuous exercise (CONT). It will be investigated whether individuals reach more stable blood glucose levels when engaging in IHE compared to CONT. Substudy B will investigate whether fueling the patients with a mixed oral 1:1 glucose-fructose carbohydrate solution will maintain glucose values within a more stable range when compared to carbohydrate supplementation by glucose alone. Methods Blood glucose levels, counterregulatory hormones, metabolites such as lactate and free fatty acids as well as inflammatory biomarkers will be assessed by regular blood samplings. By means of oral and intravenously given stable isotopes (U-13 C glucose and 2H glucose) exercise-related glucose kinetics will be investigated. Exercise-induced glycogen consumption will be measured using magnetic resonance spectroscopy technology. Late glycemic excursions will be recorded by continuous glucose monitoring systems. In order to validate 13C magnetic resonance spectroscopy (MRS) measurement of hepatic and myocellular glycogen content a pre-study involving 10 patients and an equal number of matched healthy controls will be performed (validation and reproducibility study).
Investigators
Eligibility Criteria
Inclusion Criteria
- •Aged 18 to 35 years
- •Diabetes mellitus duration for at least 5 years
- •No change in insulin regimen for at least 3 months prior to the study
- •Under acceptable to good metabolic control
- •Normal insulin sensitivity
- •Regular physical activity
- •BMI in the range of 18-25 kg/m2
- •Written informed consent
- •Exclusion Criteria
- •Diabetes-related complications (macro and microvascular)
Exclusion Criteria
- Not provided
Outcomes
Primary Outcomes
Amount of exogenous glucose required to maintain glycemia within a range between 7-10mM
Time Frame: 30 minutes (last 30 minutes of 90 min exercise period)
Secondary Outcomes
- Glucose kinetics(180 minutes)
- Counterregulatory hormones, metabolites, and inflammatory response(300 minutes)
- Heart rate variability(90 minutes)
- Exercise - related glycogen consumption(90 minutes)
- Spiroergometric parameters(180 minutes)
- Pre- and post-exercise glycemic excursions(72 h pre-exercise and 72 h post-exercise respectively)