Type 1 Diabetes Clinical Trial
Official title:
EEG-Changes During Insulininduced Hypoglycemia in Type 1 Diabetes
The aim of this study is based on recent pilot studies carried out at Odense University
Hospital showing that the acute changes in electroencephalographic (EEG) signals (i.e.
electrical activity inthe brain) elicited by insulin-induced hypoglycemia in patients with
type 1 diabetes can be reliable detected by real-time processing of these EEG signals using
mathematical algorithms and state of the art noise and artifact reduction. These preliminary
results also showed that the hypoglycemia-induced EEG changes are detectable 15-30 min
before deterioration in cognitive function impedes an adequate response to warning. We
hypothesize that these observations apply to the majority of patients with type 1 diabetes,
and therefore, that it is possible to develop an automated device to detect hypoglycemic
episodes by continuous real-time monitoring and processing of EEG signals. To test our
hypothesis, the specific aims of the present proposal are:
1. Detection of hypoglycemia-induced EEG changes using subcutaneous electrodes
2. Ambulatory EEG monitoring using subcutaneous electrodes
The near-normalization of glycemic control has become an established treatment goal in
diabetes in order to reduce late complications such as nephropathy, neuropathy, retinopathy
and cardiovascular disease (1,2). However, the frequency of insulin-induced hypoglycemia
increases several-fold during intensified insulin therapy (2,3). Thus, hypoglycemia is the
most common acute complication in the treatment of diabetes with insulin. During
hypoglycemia the cognitive function is disturbed, and may progress to unconsciousness and
seizures. This can lead to high-risk situations, e.g. while driving or operating a machine.
Estimates of deaths in patients with type 1 diabetes attributed to hypoglycemia vary between
2% and 6% (4,5). Moreover, the risk of hypoglycemia limits everyday activities of diabetic
patients decreasing their quality of life. It is therefore not surprising that hypoglycemia
is the most feared acute complication of insulin therapy in diabetic patients. This fear of
hypoglycemia discourages diabetic subjects from attempting to maintain tight glycemic
control, which in turn leads to a higher incidence of late complications and consequently
increased mortality rate (1,6,7) In the first years of type 1 diabetes, most patients are
able to sense the characteristic symptoms of hypoglycemia, which can then be relieved by
consuming appropriate food. The symptoms of hypoglycemia can roughly be classified as
autonomic (warning) symptoms caused by the release of catecholamines, and neuroglycopenic
symptoms caused by the lack of glucose in the brain. In many patients symptoms are often
compromised at night (nocturnal asymptomatic hypoglycemia) due to impaired glucose
counterregulatory response by adrenaline and glucagon. The chronic form of hypoglycemia
unawareness is very common. A quarter of all insulin-treated diabetic patients have some
degree of diminished symptomatic awareness, but this proportion increases to almost 50% in
patients who have had diabetes for more than 20 years (8). Strict control of diabetes by
intensive insulin therapy is associated with increased risk of the hypoglycemia unawareness
syndrome with loss of autonomic warning symptoms (2,6,9). This seems to involve diminished
hormonal glucose counterregulation due to recurrent hypoglycemic episodes (6,9).
For these reasons, a number of studies have been carried out with the aim of developing
automatic detection systems, which can warn the diabetic patients before blood glucose
levels are reduced to the level at which severe neuroglycopenia develops, typically about
2.0-2.5 mmol/l. Most studies have evaluated the potential of continuous glucose monitoring
(CMG) to decrease the frequency of hypoglycemia. Although, smaller studies have reported a
lower risk of hypoglycemia using CMG compared with conventional glucose measurements
(10,11), larger multi-center studies have failed to reproduce these findings (11-14). This
could be explained by a low accuracy in the low range of glucose values and delay in
detection time during rapid changes using CMG (11,13,14). In fact, CMG only recognizes less
than 50% of hypoglycemic events (15). Thus, even with a marginal improvement compared with
conventional glucose measurements, CMG is far from the goal of completely avoiding severe
hypoglycemic episodes.
The EEG signal reflects the functional state and metabolism of the brain. The brain is
almost totally dependent on a continuous supply of glucose, and when this is lower than the
metabolic requirements of the brain, its function deteriorates. Indeed, neuroglycopenic
hypoglycemia in insulin-treated diabetic patients is associated with characteristic changes
in EEG with a decrease in alpha activity, an increase in delta activity, and in particular
an increase in theta activity (16-19). These changes are clearly seen at ~2.0 mmol/l
(16,17), but may be present already at higher glucose levels (~3.0 mmol/l), in particular in
type 1 diabetic patients with hypoglycemic unawareness (19,20). It has been shown that the
most characteristic changes, the increase in theta activity, appears 19 min before severe
cognitive impairment (20). This suggests a "window" between hypoglycemia-induced EEG changes
and severe neuroglycepenia, which is an important prerequisite in developing an automatic
detection system capable of warning the patient.
A number of studies have characterized the changes in the EEG that results from hypoglycemia
(16-20), but none have proposed a method of processing and testing in real-time. With a
device, which can perform real-time monitoring and processing of EEG signals and
automatically detect and warn the patient of hypoglycemia-induced EEG changes, it would be
possible for the patient to avoid severe neuroglypenic symptoms e.g. by ingestion of
carbohydrates. The construction of an EEG-based hypoglycemia alarm system must fulfill the
following criteria. First, the device should be able to distinguish hypoglycemia-induced EEG
changes from normal changes in EEG, noise and artifacts with high sensitivity and
specificity using a mathematical algorithm that classifies the EEG in real-time. Second,
these EEG changes should be observed in the majority of insulin-treated diabetic patients
during hypoglycemia. Third, there should be a "window" between hypoglycemia-induced EEG
changes and severe cognitive impairment. Moreover, the device should be fully compatible
with normal everyday activities. Thus, the electrodes should be thin and implanted
subcutaneously, and the monitoring and processing unit should be small, have sufficient
battery power, and capable of communicating with a PDA or cell phone.
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