Feasibility of Automating Insulin Delivery for the Treatment of Type 1 Diabetes

Steil, Garry M.; Rebrin, Kerstin; Darwin, Christine; Hariri, Farzam; Saad, Mohammed F.

doi:10.2337/db06-0419

Cited by 431 publications

(368 citation statements)

References 27 publications

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“…Peak postprandial glucose levels declined from ~250 to 180 mg/dl, and levels 3-4 h postprandial became more stable. Meal responses obtained with MPC by teams comprising investigators at the University of Virginia and Padova and at Boston University and Massachusetts General Hospital [13][14][15][16] (Figure 1B) generally showed the peak breakfast response to be similar to the initial PID study 2 . Still, comparing meal responses across studies can be confounded by differences in meal size, and averaging data inevitably results in peak postprandial values lower than the average of individual peak values.…”

Section: Review Of Available Clinical Datamentioning

confidence: 99%

“…The group at Boston University/Massachusetts General Hospital has advocated the use of glucagon throughout development of their MPC algorithm, 15,16 whereas the PID algorithm developed at Medtronic, [2][3][4] and variations evaluated at Boston Children's Hospital/Joslin Diabetes Center, 5,6 have been developed for use with insulin alone. The use of glucagon is not strictly speaking an MPC versus PID question, as glucagon can be used with PID control.…”

Section: Review Of Available Clinical Datamentioning

confidence: 99%

“…This article will focus on the PID algorithms I have developed with my colleagues. [2][3][4][5][6][7][8] This version did not originate as a "PID" algorithm per se, 9 but rather as a model of β-cell insulin secretion, 10,11 referred to as "physiologic insulin delivery." It was, however, first implemented 2 using only the proportional, integral, and derivative terms needed to fit the β-cell response to a hyperglycemic clamp.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Algorithms for a Closed-Loop Artificial Pancreas: The Case for Proportional-Integral-Derivative Control

Steil

2013

J Diabetes Sci Technol

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106

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Abbreviation: (eCTR) enhanced control-to-range, (IQR) interquartile range, (MPC) model-predictive control, (PID) proportional integral derivative, (PD) pharmacodynamic, (PID IFB ) proportional integral derivative with insulin feedback, (PK) pharmacokinetic, (RLS) recursive least squares, (sCTR) standard control-to-range Journal of Diabetes Science and TechnologyVolume 7, Issue 6, November 2013 © Diabetes Technology Society AbstractClosed-loop insulin delivery continues to be one of most promising strategies for achieving near-normal control of blood glucose levels in individuals with diabetes. Of the many components that need to work well for the artificial pancreas to be advanced into routine use, the algorithm used to calculate insulin delivery has received a substantial amount of attention. Most of that attention has focused on the relative merits of proportionalintegral-derivative versus model-predictive control. A meta-analysis of the clinical data obtained in studies performed to date with these approaches is conducted here, with the objective of determining if there is a trend for one approach to be performing better than the other approach. Challenges associated with implementing each approach are reviewed with the objective of determining how these approaches might be improved. Results of the meta-analysis, which focused predominantly on the breakfast meal response, suggest that to date, the two approaches have performed similarly. However, uncontrolled variables among the various studies, and the possibility that future improvements could still be effected in either approach, limit the validity of this conclusion. It is suggested that a more detailed examination of the challenges associated with implementing each approach be conducted.

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Section: Review Of Available Clinical Datamentioning

confidence: 99%

Section: Review Of Available Clinical Datamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Algorithms for a Closed-Loop Artificial Pancreas: The Case for Proportional-Integral-Derivative Control

Steil

2013

J Diabetes Sci Technol

Self Cite

106

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“…Two main categories of control algorithms have been employed, the proportional-integral-derivative (PID) controller [48,49], and the model predictive controller (MPC) [50]. Other approaches include controllers based on fuzzy logic (‘MD logic’) [51] or a combination of MPC and PID for insulin and glucagon codelivery [52].…”

Section: Glucose Responsive Suspension Of Insulin Deliverymentioning

confidence: 99%

Insulin delivery and nocturnal glucose control in children and adolescents with type 1 diabetes

Tauschmann

Hovorka

2017

Expert Opinion on Drug Delivery

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Introduction: Nocturnal glucose control remains challenging in children and adolescents with type 1 diabetes due to highly variable overnight insulin requirements. The issue may be addressed by glucose responsive insulin delivery based on real-time continuous glucose measurements.Areas covered: This review outlines recent developments of glucose responsive insulin delivery systems from a paediatric perspective. We cover threshold-based suspend application, predictive low glucose suspend, and more advanced single hormone and dual-hormone closed-loop systems. Approaches are evaluated in relation to nocturnal glucose control particularly during outpatient randomised controlled trials.Expert opinion: Significant progress translating research from controlled clinical centre settings to free-living unsupervised home studies have been achieved over the past decade. Nocturnal glycaemic control can be improved whilst reducing the risk of hypoglycaemia with closed-loop systems. Following the US regulatory approval of the first hybrid closed-loop system in non-paediatric population, large multinational closed-loop clinical trials and pivotal studies including paediatric populations are underway or in preparation to facilitate the use of closed-loop systems in clinical practice.

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“…A variety of PID control strategies have been developed for diabetes and described in survey papers and articles [7][8][9]11,[37][38][39]. Most of the related evaluations have been based on simulation studies but experimental applications to dogs and humans have also been reported.…”

Section: A Pid Switching Control Strategymentioning

confidence: 99%

A feedforward–feedback glucose control strategy for type 1 diabetes mellitus

Marchetti

Barolo

Jovanovič

et al. 2008

Journal of Process Control

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As the "artificial pancreas" becomes closer to reality, automated insulin delivery based on real-time glucose measurements becomes feasible for people with diabetes. This paper is concerned with the development of novel feedforward-feedback control strategies for real-time glucose control and type 1 diabetes. Improved post-meal responses can be achieved by a pre-prandial snack or bolus, or by reducing the glucose setpoint prior to the meal. Several feedforward-feedback control strategies provide attractive alternatives to the standard meal insulin bolus and are evaluated in simulations using a physiological model.

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Feasibility of Automating Insulin Delivery for the Treatment of Type 1 Diabetes

Cited by 431 publications

References 27 publications

Algorithms for a Closed-Loop Artificial Pancreas: The Case for Proportional-Integral-Derivative Control

Algorithms for a Closed-Loop Artificial Pancreas: The Case for Proportional-Integral-Derivative Control

Insulin delivery and nocturnal glucose control in children and adolescents with type 1 diabetes

A feedforward–feedback glucose control strategy for type 1 diabetes mellitus

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