Non-invasive platform to estimate fasting blood glucose levels from salivary electrochemical parameters

Abstract

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Diabetes is a metabolic disorder that affects more than 400 million people worldwide. Most existing approaches for measuring fasting blood glucose levels (FBGLs) are invasive. This work presents a proof-of-concept study in which saliva is used as a proxy biofluid to estimate FBGL. Saliva collected from 175 volunteers was analysed using portable, handheld sensors to measure its electrochemical properties such as conductivity, redox potential, pH and K^+, Na^+ and Ca^2+ ionic concentrations. These data, along with the person's gender and age, were trained and tested after casewise annotation with their true FBGL values using a set of mathematical algorithms. An accuracy of 87.4 ± 1.7% and a mean relative deviation of 14.1% (R^2 = 0.76) was achieved using a mathematical algorithm. All parameters except the gender were found to play a key role in the FBGL determination process. Finally, the individual electrochemical sensors were integrated into a single platform and interfaced with the authors’ algorithm through a simple graphical user interface. The system was revalidated on 60 new saliva samples and gave an accuracy of 81.67 ± 2.53% (R^2 = 0.71). This study paves the way for rapid, efficient and painless FBGL estimation from saliva.

Keywords

• electrochemical sensors
• graphical user interfaces
• blood
• diseases
• sugar
• calcium
• patient diagnosis
• potassium
• sodium
• pH measurement
• medical computing
• electrochemical properties
• FBGL determination process
• painless FBGL estimation
• noninvasive platform
• fasting blood glucose levels
• salivary electrochemical parameters
• metabolic disorder
• proxy biofluid
• portable sensors
• ionic concentrations
• electrochemical sensors
• diabetes
• K^+
• Na^+
• Ca^2+