Abstract
Diabetes mellitus and its complication such as heart disease, stroke, kidney failure, etc. is a serious concern all over the world. Hence, monitoring some important blood parameters non-invasively is of utmost importance, that too with high accuracy. This paper presents an in-house developed system, which will be helpful for diabetes patients with Chronic Kidney Disease (CKD) to monitor blood urea and glucose. This manuscript discusses a comparative study for the prediction of blood urea and glucose using Backpropagation Artificial Neural Network (BP- ANN) and Partial Least Square Regression (PLSR) model. The NVIDIA Jetson Nano board controls the five fixed LED wavelengths in the Near Infrared (NIR) region from n}{}2.0~mu text{m} to n}{}2.5~mu text{m}n with a constant emission power of 1.2 mW. The spectra for 57 laboratory prepared samples conforming with major blood constituents of the blood sample were recorded. From these samples, 53 spectra were used for training/calibration of the BP-ANN/PLSR model and the remaining 4 samples were used for validating the model. The PLSR model predicts blood urea and glucose with a Root Mean Square Error (RMSE) of 0.88 & 12.01 mg/dL, Coefficient of Determination R2 = 0.93 & R2 = 0.97, Accuracy of 94.2 % and 90.14 %, respectively. To improve the prediction accuracy, BP-ANN model is applied. Later the Principal Component Analysis (PCA) technique was applied to these 57 spectra values. These PCA values were used to train and validate the BP-ANN model. After applying the BP-ANN model, the prediction of blood urea & glucose improved remarkably, which achieved RMSE of 0.69 mg/dL, R2 = 0.96, Accuracy of 95.96 % for urea and RMSE of 2.06 mg/dL, R2 = 0.99, and Accuracy of 98.65 % for glucose. The system performance is then evaluated with Bland Altman analysis and Clarke Error Grid Analysis (CEGA).
Highlights
The World Health Organization estimates that there are more than 500 million people worldwide are affected by diabetes and is expected to reach 642 million by 2040 [1], [2]
The Partial Least Square Regression (PLSR) model was successfully developed in python and executed in NVIDIA Jetson Nano for estimating urea/glucose with an accuracy of 94.2%/90.14%, Root Mean Square Error (RMSE) of 0.88 mg/dL /12.01 mg/dL, and coefficient of Determination R2 = 0.93/0.97 for predicting 4 samples
The same dataset was trained with Back propagation (BP)-Artificial Neural Network (ANN) to get an accuracy of 95.96%/98.65%, RMSE of 0.69 mg/dL/ 2.06 mg/dL, and coefficient of Determination R2 = 0.96/0.99 for predicting the same 4 samples
Summary
The World Health Organization estimates that there are more than 500 million people worldwide are affected by diabetes and is expected to reach 642 million by 2040 [1], [2]. Diabetes is caused by poorly controlled blood glucose levels in the blood, if it remains high (hyperglycemia) for quite a long time, result in the development of serious and life-threatening diseases such as stroke, heart attack, heart failure, kidney failure, adult blindness and amputation [3]. About 40% of people with diabetes will develop chronic kidney disease (CKD) [5]. Diabetes is the leading cause of End-Stage Kidney Disease(ESKD) in most of the developed countries and has driven growth in ESKD globally over recent decades [6]–[8].
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