Viewing Study NCT02065895

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Ignite Creation Date: 2025-12-24 @ 2:07 PM

Ignite Modification Date: 2026-02-22 @ 10:30 AM

Study NCT ID: NCT02065895

Status: COMPLETED

Last Update Posted: 2018-05-17

First Post: 2014-02-07

Is NOT Gene Therapy: True

Has Adverse Events: True

Brief Title: Effect of Gain on Closed-Loop Insulin

Sponsor: Joslin Diabetes Center

Organization:

Overview Dates Organization Conditions Design Enrollment Locations Outcomes Modules Raw JSON

Study Overview

Official Title: Effect of Gain on Closed-Loop Insulin

Status: COMPLETED

Status Verified Date: 2018-05

Last Known Status: None

Delayed Posting: No

If Stopped, Why?: Not Stopped

Has Expanded Access: False

If Expanded Access, NCT#: N/A

Has Expanded Access, NCT# Status: N/A

Acronym: None

Brief Summary: The purpose of this study is to test the ability of an advanced external Physiologic Insulin Delivery (ePID) algorithm (a step by step process used to develop a solution to a problem) to get acceptable meal responses over a range of gain. Gain is defined as how much insulin is given in response to a change in a patient's glucose level.

This study also examines the effectiveness of the external Physiologic Insulin Delivery (ePID) closed-loop insulin delivery computer software. The investigators would like to assess whether fasting target levels can be achieved as the closed-loop gain increases or decreases, and to evaluate the system's ability to produce an acceptable breakfast meal response.

Detailed Description: There have been significant advances in diabetes management technology, including more sophisticated insulin pumps and more accurate real-time continuous glucose monitors. The next technological development is widely thought to be the introduction of an algorithm linking the pump and sensor to form a closed-loop insulin delivery system. The algorithm used for this purpose needs to be robust to changes in an individual's insulin sensitivity, and the sensor's sensitivity to glucose. Insulin sensitivity (how much the patient's glucose level changes in response to a change in insulin delivery) and algorithm gain (how much insulin is delivered in response to a change in glucose) determine the systems overall closed-loop gain. Ideally, the overall gain can be set to achieve the lowest possible peak postprandial glucose response without postprandial hypoglycemia. However, if the algorithm's gain is set to a fixed value and the subject's insulin sensitivity changes, the overall-gain will change. Some degradation in closed-loop performance might be acceptable during periods whenever the subject's insulin sensitivity is low (i.e., the subject is insulin resistant) and the risk of hypoglycemia may actually be reduced. However, if the subject becomes more sensitive the system may become less stable and the risk of postprandial hypoglycemia may increase. In addition to changes in insulin sensitivity, glucose sensors will sometimes over- or under-read blood glucose as sensor sensitivity increases or decreases. This will result in a change in the closed-loop algorithm's effective target. The purpose of this study is to evaluate the ability of an advanced Physiologic Insulin Delivery algorithm to achieve an acceptable breakfast response as the gain and effective target glucose level changes. Specifically:

1. to assess the fasting glucose levels achieved as the overall closed-loop gain and effective target is increased or decreased, and
2. determine the system's ability to produce an acceptable breakfast meal response under these conditions

Study Oversight

Has Oversight DMC: False

Is a FDA Regulated Drug?: None

Is a FDA Regulated Device?: None

Is an Unapproved Device?: None

Is a PPSD?: None

Is a US Export?: None

Is an FDA AA801 Violation?: