An advisory protocol for rapid- and slow-acting insulin therapy based on a run-to-run methodology
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Background: Emerging technology, such as an artificial pancreatic β-cell, is not likely to be affordable to people who live in developing nations in the next 20-30 years. However, multiple-daily injection (MDI) therapy can be improved using similar advanced control algorithms designed for continuous glucose monitoring and continuous insulin infusion pumps. Methods: A simulation study of run-to-run control was developed for MDI therapy. Rapid- and slow-acting insulins were used in the protocol, which uses pre- and postprandial glucose measurements. The key information for the synthesis of the control algorithm is the subject insulin sensitivity that is calculated for two cases: (a) when the subject%27s glycemia and insulin dosing information is known (sensitivity response) and (b) when there is no previous information about the subject%27s response to the insulin protocol. In the latter case, this information needs to be estimated recursively using online data. After the sensitivity is recalculated, the run-to-run correction scheme is updated, obtaining an adaptive MDI therapy. The robustness of the advisory algorithm was evaluated by constant random parameter variations and superimposing sinusoidal oscillations on glucose-insulin model parameters to simulate intra-individual variability of the glucoregulatory system. Results: Optimal glycemic control has been achieved for both cases (a and b) despite variable meals (15%25 variation in carbohydrate content and 15-min variation in timing) and parametric variations in the glucose-insulin model. In Case (b), no profound hypoglycemic (<60mg/dL) or hyperglycemic (>180mg/dL) events were observed on average during all evaluations. Conclusions: This work shows that the run-to-run framework for insulin updating can be successfully extended to an adaptive MDI protocol. These results motivate the practical implementation of this scheme in portable units such as personal digital assistants or smartphones. © 2010, Mary Ann Liebert, Inc.
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Background: Emerging technology, such as an artificial pancreatic β-cell, is not likely to be affordable to people who live in developing nations in the next 20-30 years. However, multiple-daily injection (MDI) therapy can be improved using similar advanced control algorithms designed for continuous glucose monitoring and continuous insulin infusion pumps. Methods: A simulation study of run-to-run control was developed for MDI therapy. Rapid- and slow-acting insulins were used in the protocol, which uses pre- and postprandial glucose measurements. The key information for the synthesis of the control algorithm is the subject insulin sensitivity that is calculated for two cases: (a) when the subject's glycemia and insulin dosing information is known (sensitivity response) and (b) when there is no previous information about the subject's response to the insulin protocol. In the latter case, this information needs to be estimated recursively using online data. After the sensitivity is recalculated, the run-to-run correction scheme is updated, obtaining an adaptive MDI therapy. The robustness of the advisory algorithm was evaluated by constant random parameter variations and superimposing sinusoidal oscillations on glucose-insulin model parameters to simulate intra-individual variability of the glucoregulatory system. Results: Optimal glycemic control has been achieved for both cases (a and b) despite variable meals (15%25 variation in carbohydrate content and 15-min variation in timing) and parametric variations in the glucose-insulin model. In Case (b), no profound hypoglycemic (<60mg/dL) or hyperglycemic (>180mg/dL) events were observed on average during all evaluations. Conclusions: This work shows that the run-to-run framework for insulin updating can be successfully extended to an adaptive MDI protocol. These results motivate the practical implementation of this scheme in portable units such as personal digital assistants or smartphones. © 2010, Mary Ann Liebert, Inc.
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glucose; insulin aspart; insulin glargine; glargine; glucose blood level; insulin; insulin lispro; long acting insulin; algorithm; article; clinical protocol; glucose blood level; glycemic control; hyperglycemia; hypoglycemia; insulin sensitivity; insulin treatment; mathematical model; meal; priority journal; simulation; analogs and derivatives; analysis; biological model; blood; computer simulation; Diabetes Mellitus, Type 1; human; immunology; subcutaneous drug administration; Algorithms; Blood Glucose; Computer Simulation; Diabetes Mellitus, Type 1; Humans; Injections, Subcutaneous; Insulin; Insulin Lispro; Insulin, Long-Acting; Models, Immunological
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