Clinical Trials Logo

Clinical Trial Summary

Glucagon regulation and response in persons with T1D at the basal state and in response to various stimuli remains unclear. Dr. Philip Cryer has previously reported that, in T1D young adults with a course of the disease of 16+9 years, the absence of endogenous insulin secretion results in increased glucagon secretion after a mixed meal, concluding that endogenous insulin reciprocally regulates the alpha-cell glucagon secretion and also suggesting that glucagon dysregulation may play an important role in post-prandial hyperglycemia in T1D. Interestingly, recent research on human islets have shown that insulin inhibits counter-regulatory glucagon secretion by a paracrine effect mediated by SGLT2-dependent stimulation of somatostatin release. An important gap in our knowledge is whether the timing of prandial insulin doses affects the glucagon response to a hyperglycemic stimulus in patients with T1D who have undetectable C-peptide. Whether appropriately timed exogenous insulin can modify the glucagon response to glucose fluctuations has not been studied. As such, this pilot study aims to characterize the glucagon response to meal-time hyperglycemia and to compare the difference in glucagon secretion when mealtime bolus insulin is given before the meal versus after the meal with the objective of understanding factors that contribute to the peak post-prandial blood glucose and AUC of blood glucose after a mixed meal in this target population.


Clinical Trial Description

Glucagon regulation and response in persons with T1D at the basal state and in response to various stimuli remains unclear. Dr. Philip Cryer has previously reported that, in T1D young adults with a course of the disease of 16+9 years, the absence of endogenous insulin secretion results in increased glucagon secretion after a mixed meal , concluding that endogenous insulin reciprocally regulates the alpha-cell glucagon secretion and also suggesting that glucagon dysregulation may play an important role in post-prandial hyperglycemia in T1D. Interestingly, recent research on human islets have shown that insulin inhibits counter-regulatory glucagon secretion by a paracrine effect mediated by SGLT2-dependent stimulation of somatostatin release. An important gap in our knowledge is whether the timing of prandial insulin doses affects the glucagon response to a hyperglycemic stimulus in patients with T1D who have undetectable C-peptide. T1D course. In general, loss of 80% of beta cell function is needed to develop severe hyperglycemia. Endogenous insulin secretion is almost entirely lost within 3 to 5 years after the diagnosis . In children with new diagnosis of T1D, glucagon levels were highly associated with post prandial blood glucose, but not with HbA1c level. It has also been reported that postprandial hyperglucagonemia worsens significantly while C-peptide secretion declines during the first year of the disease. Also, in children with greater than five years of T1D, postprandial glucagon levels increased 160% from one to sixty months after diagnosis (8) and in those with disease duration of 6.9 + 4 years, glucagon levels were strongly correlated with post-prandial glucose and mildly correlated with HbA1C levels. A study in T1D adults performed in China showed that post-prandial glucagon levels were higher in T1D patients in the first year of the disease compared to those with longer course of the disease, and that hypoglycemic events were lower in newly diagnosed patients, suggesting that glucagon secretory function may become impaired with longer duration of the disease. These studies suggest that glucagon dysregulation could impact glucose control with exogenous insulin, and that this dysregulation may change with disease duration. Post-prandial hyperglycemia adds to glucose variability, difficulty with insulin dosing and overall instability of glucose control. A recent analysis from the T1D Exchange study, that included 4768 participants younger than 26 years with a clinical diagnosis of T1D for at least 1 year showed that 21% of the participants reported administering insulin several minutes before, 44% immediately before, 10% during, and 24% after meal. Interestingly, participants who reported administering insulin during or after a meal were more likely to report missing ≥1 mealtime insulin dose per week compared with those who administered insulin before meals. In addition, a sub-analysis showed that participants who dose mealtime insulin in the postprandial period have poorer glycemic control and greater frequency of severe hypoglycemia. However, despite of these recent results, patients are often advised to give insulin after eating because caloric intake is uncertain. Understanding the mechanisms behind the higher post-prandial peak in glucose with delayed insulin administration may help clinicians guide appropriate timing of insulin administration for T1D patients with long course of the disease. Glucagon Regulation: Different models have been used to study glucagon regulation. Since both hyperglycemia and hypoglycemia stimulate alpha cells to produce glucagon, both the lack of intra-islet insulin and this U-shaped glucagon response contribute to glucose dysregulation in T1D . It has been reported that in T1D patients with a duration of the disease of 26.4+7.5 years, glucagon levels increased in response to the OGTT under euglycemic and hyperglycemic conditions, however the relative contribution of hyperglucagonemia to post-prandial glucose rise in the presence or absence of preprandial insulin has not been clearly elucidated. Whether appropriately timed exogenous insulin can modify the glucagon response to glucose fluctuations has not been studied. As such, this pilot study aims to characterize the glucagon response to meal-time hyperglycemia and to compare the difference in glucagon secretion when mealtime bolus insulin is given before the meal versus after the meal with the objective of understanding factors that contribute to the peak post-prandial blood glucose and AUC of blood glucose after a mixed meal in this target population. Hypothesis 1. Patients with higher glucagon responses to a mixed meal stimulus will have higher peak post-prandial glucoses and greater AUC of post-prandial glucose. 2. Bolus dose insulin given pre-meal (20 min before meal) will result in lower peak post-prandial glucose, lower AUC and lower post-prandial glucagon levels 3. Bolus dose insulin given post-meal (20 min after meal) will result in higher peak post-prandial glucoses, higher AUC of post-meal glucose and higher glucagon levels 4. There will be a correlation between peak post-prandial glucagon response and post-meal glucose AUC, 0 to 180 minutes. Research Plans The study will be conducted in the (Intensive Research Unit, part of the CTSA) Diabetes Center at Barnes Jewish Hospital/Washington University in St Louis. Study Visits - Screening will be done over the phone and with review of medical records if the required labs have been done in the past 6 months - Visits A and B will be performed in random order - Demographics, review of diabetes history, medications and allergies will be recorded at the first study visit. Insulin doses and effectiveness of current carbohydrate ratio will be evaluated and recorded. Mealtime insulin doses will be established at the first study visit. - Mealtime insulin will be given via injection by a study nurse to standardize the administration procedure. - Vital signs, height and weight will be done at each visit - C-peptide will be checked with the fasting labs at the first study visit - Baseline glucose should be 80 to 140 mg/dl. In case baseline glucose is not in the target range, the study visit will be rescheduled. - Whole blood will be collected in vacutainers via an indwelling peripheral venous catheter with nursing supervision. - Samples will be deidentified before sending to the laboratory. - No genetic testing will be performed. Visit A - Glucose levels done fasting, 30, 60, 120, and 180 minutes - Glucagon levels done fasting, 30, 60, 120, and 180 minutes - Usual insulin dose will be administered 20 minutes prior to a mixed meal challenge with Ensure Plus* Visit B - Glucose done fasting, 30, 60, 120, and 180 minutes - Glucagon levels done fasting, 30, 60, 120, and 180 minutes - Usual insulin dose will be administered 20 minutes after the mixed meal challenge with Ensure Plus* *Ensure Plus (Abbott Nutrition) at 6cc/kg (max 360 cc), content per 100 ml: carbohydrate 21.5 grams, protein 5.5 grams, with nursing supervision. Laboratory Measures: Core Laboratory for Clinical Studies at Washington University (https://research.wustl.edu/core-facilities/core-laboratory-clinical-studies, CLCS) will measure glucose on the Roche cobas c510 platform using Roche's coupled enzymatic assay (hexokinase, glucose-6-phosphoate dehydrogenase). The rate of NADPH formation is directly proportional to glucose concentration and measured photometrically. The interday imprecision is typically <2.0% CV. CLCS will also measure C-peptide on the Roche cobas e601platform using Roche's sandwich electrochemiluminescence immunoassay. In this assay a biotinylated monoclonal C-peptide-specific antibody and a monoclonal C-peptide-specific antibody labeled with a ruthenium complex bind to C-peptide to form the sandwich. Then, using streptavidin-coated microparticles, the complex is drawn into the measuring cell and remains while unbound material is washed away. Application of a voltage to the electrode induces chemiluminescent emission that is measured by the instrument. Between run precision typically ranges from 1.9 - 2.7% CV. Glucagon is measured using a radioimmunoassay kit from Millipore. This is a competitive immunoassay which uses I-125 labeled glucagon and a glucagon-specific antibody. Its stated inter-assay precision is 12% CV. Typical within-run precision is 2.0 - 3.0 % CV in our hands. Methods of Data Analysis Data analysis will be performed using STATA 15.1 for Windows (StataCorp LP, College Station, Texas, United States). The sample size calculation assumes that the peak postprandial glucose will increase by 80 +/-20 mg/dl in the pre-meal insulin group and 140 +/-20 mg/dl in the post-meal group. So, the expected mean peak of postprandial glucose will be up to 220 mg/dL for Visit A and mean peak postprandial glucose will be up to 280 mg/dL for Visit B. The sample size will have 80% power to detect a difference between groups at p<0.05. We have assumed correlation between visits A and B of 0.5. The sample size was corrected by an anticipated loss of follow up of 10% of the participants. The calculated sample size is 10 participants with full data sets available for 8 participants. The study randomization is designed as follows: 5 participants will first attend Visit A, and then Visit B. The 5 remaining participants will first attend Visit B and then Visit A. AUC of post-prandial glucose and glucagon and maximum postprandial peak of glucose and glucagon will be analyzed by using paired T student. Relationships between variables were assessed by a Spearman's correlation test. ;


Study Design


Related Conditions & MeSH terms


NCT number NCT04079881
Study type Interventional
Source Washington University School of Medicine
Contact
Status Terminated
Phase Phase 1/Phase 2
Start date February 13, 2020
Completion date July 1, 2020

See also
  Status Clinical Trial Phase
Recruiting NCT05653518 - Artificial Pancreas Technology to Reduce Glycemic Variability and Improve Cardiovascular Health in Type 1 Diabetes N/A
Enrolling by invitation NCT05515939 - Evaluating the InPen in Pediatric Type 1 Diabetes
Completed NCT05109520 - Evaluation of Glycemic Control and Quality of Life in Adults With Type 1 Diabetes During Continuous Glucose Monitoring When Switching to Insulin Glargine 300 U/mL
Recruiting NCT04016987 - Automated Structured Education Based on an App and AI in Chinese Patients With Type 1 Diabetes N/A
Active, not recruiting NCT04190368 - Team Clinic: Virtual Expansion of an Innovative Multi-Disciplinary Care Model for Adolescents and Young Adults With Type 1 Diabetes N/A
Recruiting NCT05413005 - Efficacy of Extracorporeal Photopheresis (ECP) in the Treatment of Type 1 Diabetes Mellitus Early Phase 1
Active, not recruiting NCT04668612 - Dual-wave Boluses in Children With Type 1 Diabetes Insulin Boluses in Children With Type 1 Diabetes N/A
Completed NCT02837094 - Enhanced Epidermal Antigen Specific Immunotherapy Trial -1 Phase 1
Recruiting NCT05414409 - The Gut Microbiome in Type 1 Diabetes and Mechanism of Metformin Action Phase 2
Recruiting NCT05670366 - The Integration of Physical Activity Into the Clinical Decision Process of People With Type 1 Diabetes N/A
Active, not recruiting NCT05418699 - Real-life Data From Diabetic Patients on Closed-loop Pumps
Completed NCT04084171 - Safety of Artificial Pancreas Therapy in Preschoolers, Age 2-6 N/A
Recruiting NCT06144554 - Post Market Registry for the Omnipod 5 System in Children and Adults With Type 1 Diabetes
Recruiting NCT05379686 - Low-Dose Glucagon and Advanced Hybrid Closed-Loop System for Prevention of Exercise-Induced Hypoglycaemia in People With Type 1 Diabetes N/A
Recruiting NCT05153070 - Ciclosporin Followed by Low-dose IL-2 in Patients With Recently Diagnosed Type 1 Diabetes Phase 2
Completed NCT05281614 - Immune Effects of Vedolizumab With or Without Anti-TNF Pre-treatment in T1D Early Phase 1
Withdrawn NCT04259775 - Guided User-initiated Insulin Dose Enhancements (GUIDE) to Improve Outcomes for Youth With Type 1 Diabetes N/A
Active, not recruiting NCT01600924 - Study on the Assessment of Determinants of Muscle and Bone Strength Abnormalities in Diabetes
Completed NCT02750527 - Pediatric Population Screening for Type 1 Diabetes and Familial Hypercholesterolemia in Lower Saxony, Germany
Completed NCT02897557 - Insulet Artificial Pancreas Early Feasibility Study N/A