The purpose of this study is to learn if giving multiple doses of a hormone called glucagon can cause a major decrease in liver glycogen (animal starch). Glucagon is currently approved by the Food and Drug Administration to be given as a large dose to treat severe low blood sugar. Our group is studying whether glucagon can be given in repeated small doses to prevent hypoglycemia.
Hypoglycemia remains a barrier to optimal glucose control, which is necessary to prevent diabetes-related complications including eye, kidney, and nerve diseases. Despite treatment advances such as insulin pump therapy and continuous glucose monitoring, hypoglycemia remains a concern, even when insulin is given in a closed-loop system. A closed-loop system consists of a glucose-measuring device, from which data are collected and entered into an algorithm, which in turn controls insulin delivery. The difficulty of delivering regular or analog insulin in such a manner is related to its slow onset and prolonged effect when delivered subcutaneously. Until a more rapidly-acting insulin preparation is available, discontinuation of subcutaneous insulin during impending hypoglycemia, with any algorithm, may be insufficient to prevent hypoglycemia. Glucagon, a hormone secreted from the alpha cells of the normal endocrine pancreas, rapidly raises circulating glucose levels within minutes via glycogenolysis, even when given subcu-taneously. Glucagon is approved for use as a parenteral injection for treatment of severe hypoglycemia. Our group has successfully completed studies in humans using a closed-loop system that delivers insulin (in a nearly continuous fashion) to prevent and treat hyperglycemia as well as glucagon (intermittently) to prevent and treat hypoglycemia. However, it is unknown whether or not repeated doses lead to hepatic glycogen depletion, which would increase the risk of a severe hypoglycemic episode. 13C MRS (magnetic resonance spectroscopy) has been successfully used to quantify hepatic glycogen in a non-invasive fashion. We are proposing to use 13C MRS to compare glycogen stores in subjects with type 1 diabetes after a period without glucagon vs after a period of repeated glucagon dosing. The comparisons will be made when glycogen stores should be replete (after a lunch meal) and when glycogen stores should be lower (after an overnight fast). If repeated doses of glucagon do cause glycogen depletion, then we would revise our dosing strategy in the closed-loop system and/or consider alternative methods for preventing hypoglycemia.
Study Type
INTERVENTIONAL
Allocation
NA
Purpose
BASIC_SCIENCE
Masking
NONE
Enrollment
12
Subjects will receive 8 doses of glucagon, each dose will be 2.0 mcg per kg. Glucagon will be reconstituted immediately prior to administration and each dose will be administered subcutaneously via syringe/needle. The first glucagon dose is at hour 17, second at hour 22, third at hour 24, fourth at hour 27, fifth at hour 29, sixth at hour 31, seventh at hour 33, eighth at hour 35.
Oregon Health and Science University
Portland, Oregon, United States
Assess Difference in Hepatic Glycogen Measured in the Fasting State Before vs. After Repeated Glucagon Administration
The mean difference in estimated hepatic glycogen will be assessed using Carbon 13 Magnetic Resonance Spectroscopy before vs. after glucagon administration in the fasting state.
Time frame: Baseline and 41 hours
Assess Difference in Hepatic Glycogen Measured in the Fed State Before vs. After Repeated Glucagon Administration
The mean difference in estimated hepatic glycogen will be assessed using Carbon 13 Magnetic Resonance Spectroscopy before vs. after glucagon administration in the fed state.
Time frame: Baseline and 41 hours
This platform is for informational purposes only and does not constitute medical advice. Always consult a qualified healthcare professional.