Type 1 Diabetes Clinical Trial
Official title:
Clinical Assessment of a Closed-loop System With Glucagon, Exercise and Mixed Meals
The diabetes technology group at Imperial College have developed a bio-inspired artificial
pancreas (BiAP) system which uses a control algorithm based on a mathematical model of
beta-cell physiology. The algorithm is implemented on a miniature silicon microchip within a
portable handheld device, which interfaces the components of the artificial pancreas.
Development of closed-loop insulin delivery devices to intensify control without
hypoglycaemia has been extensively reviewed and have shown encouraging results . However,
they have not yet proven to be robust when challenged with uncertainty and the external
challenges (such as mixed meal contents, physical exercise, physiological stress and
intercurrent illness) that people with Type 1 Diabetes Mellitus (T1DM) may be exposed to
outside the clinical environment.
The principal research objective is to assess the safety and efficacy of a closed-loop system
for T1DM compared to standard insulin pump therapy (open-loop). The primary outcome from the
studies will be % time spent with a glucose concentration in the target range
(3.9-10.0mmol/l). This outcome incorporates safety as it ensures subjects do not have low or
high glucose excursions and is the principal measure of efficacy for closed-loop insulin
delivery systems in the scientific literature. Other measured outcomes will be % time spent
in euglycaemia (3.9-7.8mmol/l), % time spent in hypoglycaemia (<3.9mmol/l), % time spent in
hyperglycaemia (>10mmol/l), mean venous blood and sensor glucose, glycaemic variability as
measured by standard metrics (Standard Deviation, Continuous Overlapping Net Glycaemic
Action, Lability Index, J-Index, Glycaemic Risk Assessment Diabetes Equation, Mean Of Daily
Differences, Mean Amplitude of Glucose Excursion, Average Daily Risk Range, M-VALUE, Mean
Average Glucose), glycaemic risk as measured by Low Blood Glucose Index (LBGI) and High Blood
Glucose Index (HBGI), closed-loop error grid analysis, glucose area under the curve. All
measures have been previously published and validated.
This clinical trial protocol assesses the artificial pancreas system in three separate
sub-studies:
1. In a bi-hormonal (insulin and glucagon) configuration
2. During and after exercise with bi-hormonal closed loop, and standard insulin opened loop
3. During and after meals of mixed composition with bi-hormonal closed loop, and standard
insulin opened loop
Methodology Randomised controlled cross-over open label study
Sub study 1 (n=10)
In sub-study 1 which includes the first bio-inspired artificial pancreas study using
bi-hormonal (insulin and glucagon) control a fasting 6-hour bi-hormonal closed-loop study
will be conducted to assess proof of concept and safety prior to the 25-hour randomised
controlled crossover study
Each subject will then be randomised to attend either a closed-loop visit or an open-loop
visit first. Once either visit is completed each subject will crossover and attend the
remaining visit.
Sub-study 2 (n=20) The aim of sub-study 2 is to challenge the bi-hormonal pump during a
moderate exercise. Subjects will be initially randomised to either the bi-hormonal or the
standard opened loop and then cross over. Each study will last for 25 hours
• Exercise protocol: Subjects will be connected to the gas analyser and heart rate/ECG
monitor as per COSMED manufacturer instructions.
The oxygen consumption (VO2)/Carbon dioxide production (VCO2) and heart rate/ECG trace will
be displayed continuously in real time while the subject is exercising.
Warm-up: 3 minutes of cycling at low resistance (20-30 watts) while maintaining a speed of
60-80 revolutions per minute After the warm-up the subjects will undergo a 30 minutes
moderate intensity exercise session on the bike aiming to maintain their VO2 between 10-20%
above their 1st ventilatory anaerobic threshold. If their VO2 falls below or goes above this
level then the resistance will be increased or decreased accordingly. The target VO2 and the
starting resistance (watts) will be individually set based on their baseline exercise test
outcome.
The estimated time needed to complete the exercise test is 35-40 minutes.
Real-time continuous glucose monitoring alarms will be set at 4mmol/L and 15mmol/L and will
be audible by the subject and the research team.
The glucagon solution will be replaced with a freshly reconstituted glucagon solution every 8
hours throughout the closed-loop study If the venous blood glucose concentrations fall below
3.5mmol/L or if the subject experiences hypoglycaemia symptoms then hypoglycaemia will be
confirmed by an additional venous blood plasma glucose sample and will be treated according
to Imperial College Hospitals National Health Service Trust Guidelines.
After 25 hours of closed-loop, at 12:00 the next day, the subject's own insulin pump will be
primed, reconnected and started as per the subject's usual insulin regime. Once running, the
closed loop system will be disconnected. The subject can then eat and drink freely and may be
discharged after 2 hours, or when glucose concentrations are stable.
The same protocol will be used when subjects cross over for the standard opened loop 25 hour
study for the remaining visit.
Sub-study 3: Bi-hormonal closed-loop control during- and after mixed meals (n=20) A high
fat/high carbohydrate content dinner (45g fat, 80g CHO) will be given at 19:00, a high
glycaemic index breakfast (40g CHO) at 07:00 and a high protein/low carbohydrate lunch ( 30g
protein,10g CHO) at 12:00.
Subjects will be free to gently mobilise around the clinical research unit, smoking will not
be permitted. Subjects may drink unlimited water throughout the visit.
Real-time continuous glucose monitoring alarms will be set at 4mmol/L and 15mmol/L and will
be audible by the subject and the research team.
The glucagon solution will be replaced with a freshly reconstituted glucagon solution every 8
hours throughout the closed-loop studies.
If the venous blood glucose concentrations fall below 3.5mmol/L or if the subject experiences
hypoglycaemia symptoms then hypoglycaemia will be confirmed by an additional venous blood
plasma glucose sample and will be treated according to Imperial College Hospitals National
Health Service Trust Guidelines.
After 25 hours of closed-loop, at 18:00 the next day, the subject's own insulin pump will be
primed, reconnected and started as per the subject's usual insulin regime. Once running, the
closed-loop system will be disconnected. The subject can then eat and drink freely and may be
discharged after 2 hours, or when glucose concentrations are stable.
The same protocol will be applied after cross over but with a standard opened loop insulin
pump for the remaining visit.
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