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Diabetes Researching

Exploring Challenges with Hybrid Closed-Loop Insulin Delivery Systems

There are many different options for managing diabetes from manually checking blood sugar and administering insulin to using a hybrid-closed loop insulin delivery system that does the work automatically with some human input. This type of insulin delivery system, also referred to as an artificial pancreas, was designed to improve diabetes management and blood sugar control without as much demand on patients.

However, a recent study found that nearly one-third of children and young adults stopped using the hybrid closed-loop system within six months. Some of them even discontinued use of a continuous glucose monitoring (CGM) system. The study involved 92 participants with type 1 diabetes who had an average age of 16. Each participant began using the Medtronic 670G system in manual mode for two weeks before switching to auto mode. They received follow-up training via phone within one month after starting auto mode, then were seen in a clinic every three months during the next six months.

The Medtronic 670G system uses CGM data to automatically control basal insulin delivery. This can help manage changes in blood sugar more quickly and administer the correct amount of insulin without patient input. If boluses are needed, however, the individual must enter their carb count and blood glucose number manually.

Researchers found that use of auto mode continued to decrease over the 6-month trial period, dropping from 65.5% during the first month to 51.2% by the sixth month. In total, 28 youth stopped using the hybrid closed-loop system within the first six months, and 21 of those 28 stopped using CGM as well. This raises the question as to whether CGM use posed some barriers to success and continued use of the hybrid closed-loop system.

The study did show that while participants used the artificial pancreas, their time spent within range for blood glucose improved from 50.7% to 56.9%, and their HbA1c levels decreased from 8.7% to 8.4%.

Understanding the strengths and challenges of artificial pancreas use in children and young adults can help researchers to make improvements and adjust systems for better results and continued use. Hybrid closed-loop therapy is just one option for managing type 1 diabetes, and it is important for individuals to find what works best for their situation.

Diabetes Research Connection is committed to providing early-career scientists with the funding necessary to support research designed to prevent, cure, and better manage type 1 diabetes. Funding is critical to continue advancing understanding and therapies for the disease. Click to learn more about current projects and provide support.

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Role of the integrated stress response in type 1 diabetes pathogenesis
In individuals with type 1 diabetes (T1D), the insulin-producing beta cells are spontaneously destroyed by their own immune system. The trigger that provokes the immune system to destroy the beta cells is unknown. However, accumulating evidence suggest that signals are perhaps first sent out by the stressed beta cells that eventually attracts the immune cells. Stressed cells adapt different stress mitigation systems as an adaptive response. However, when these adaptive responses go awry, it results in cell death. One of the stress response mechanisms, namely the integrated stress response (ISR) is activated under a variety of stressful stimuli to promote cell survival. However, when ISR is chronically activated, it can be damaging to the cells and can lead to cell death. The role of the ISR in the context of T1D is unknown. Therefore, in this DRC funded study, we propose to study the ISR in the beta cells to determine its role in propagating T1D.
Wearable Skin Fluorescence Imaging Patch for the Detection of Blood Glucose Level on an Engineered Skin Platform
zhang
A Potential Second Cure for T1D by Re-Educating the Patient’s Immune System
L Ferreira
Validating the Hypothesis to Cure T1D by Eliminating the Rejection of Cells From Another Person by Farming Beta Cells From a Patient’s Own Stem Cells
Han Zhu
Taming a Particularly Lethal Category of Cells May Reduce/Eliminate the Onset of T1D
JRDwyer 2022 Lab 1
Can the Inhibition of One Specific Body Gene Prevent Type 1 Diabetes?
Melanie
Is Cholesterol Exacerbating T1D by Reducing the Functionality and Regeneration Ability of Residual Beta Cells?
Regeneration Ability of Residual Beta Cells
A Call to Question… Is T1D Caused by Dysfunctionality of Two Pancreatic Cells (β and α)?
Xin Tong
Novel therapy initiative with potential path to preventing T1D by targeting TWO components of T1D development (autoimmune response and beta-cell survival)
flavia pecanha