Abstract
In classical approaches for an artificial pancreas, continuous glucose monitoring (CGM) is the only measured variable used for insulin dosing and additional control functions. The CGM values are subject to time delays and slow dynamics between blood and the sensing location. These time lags compromise the controller’s performance in maintaining (near to) normal glucose levels. Meal information could enhance the control outcome. However, meal announcement by the user is not reliable, and it takes 30 min to 40 min from meal onset until a meal is detected by methods based on CGM. In this pilot study, the use of bowel sounds for meal detection was investigated. In particular, we focused on whether bowel sounds change qualitatively during or shortly after meal ingestion. After fasting for at least 4 h, 11 healthy volunteers ingested a lunch meal at their usual time. Abdominal sound was recorded by a condenser microphone that was attached to the right upper quadrant of the abdomen by medical tape. Features that describe the power distribution over the frequency spectrum were extracted and used for classification by support vector machines. These classifiers were trained in a leave-one-out cross-validation scheme. Meals could be detected on average 10 min (std: 4.4 min) after they had started. Half of these were detected without false alarms. This shows that abdominal sound monitoring could provide an early meal detection. Further studies should investigate this possibility on a larger population in more general settings.
Highlights
IntroductionThe manual insulin therapy is a time-consuming daily task that often dominates the life of affected people
The most advanced systems rely on continuous glucose monitoring (CGM) by sensors that are placed in the subcutaneous (SC) tissue
Based on the CGM value, algorithms decide on the amount of insulin that will be injected into the SC tissue
Summary
The manual insulin therapy is a time-consuming daily task that often dominates the life of affected people. To reduce this burden, worldwide research efforts focus on the development of a so-called artificial pancreas, a fully automated system that controls the BGL [1]. A more recent study confirmed that only 0.5 % of the signal’s power spectrum density occurs at frequencies above 1000 Hz [18]. The same study revealed that the largest part of the power spectrum density of abdominal sounds is located between 100 Hz and 500 Hz [18], while a minimum frequency of 80 Hz has been chosen by others before [14]
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