BiLSTM with Data Augmentation using Interpolation Methods to Improve Early Detection of Parkinson Disease

Abayomi‐Alli, Olusola; Damaševičius, Robertas; Maskeliūnas, Rytis; Abayomi‐Alli, Adebayo

doi:10.15439/2020f188

Cited by 28 publications

(11 citation statements)

References 44 publications

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“…Because deep learning algorithms usually require large datasets for accurate fitting, we also produced an augmented dataset based on the solvent data. Interpolation between measured samples is a common data augmentation method in various domains, − in particular, those which employ deep learning methods on optical records of luminescent materials . Augmentation was done by linear interpolation between two neighboring samples in respect of water content.…”

Section: Methodsmentioning

confidence: 99%

Utilizing Deep Learning to Enhance Optical Sensing of Ethanol Content Based on Luminescent Carbon Dots

Döring

Rogach

2022

ACS Appl. Nano Mater.

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Optical sensing methods have shown their potential in measuring environmental properties such as temperatures and sample concentrations, increasing the convenience and speed of such measurements. Carbon dots (CDs) are readily available, easy-to-synthesize, and non-toxic luminescent colloidal nanoparticles that have gained prominence as optical probes in recent years. A disadvantage of CDs used for optical sensing is their broad emission profile, leading to unspecific sensing and a potential overlap of their luminescence with the autofluorescence of the samples. Machine learning approaches can address these shortcomings and greatly enhance sensing accuracy. In this study, CDs were employed as optical probes, while machine learning methods were applied to optimize ethanol content determination in ethanol/water mixtures as well as in alcohol-containing beverages. A simple neural network was used to understand the importance of different optical parameters on sensing, while a modular deep learning model was developed for increased generalizability towards samples with strong autofluorescence. Drawing from multiple input channels, the deep learning model was able to predict ethanol concentrations with a mean absolute error of 0.4 vol % in pure solvents and 6.7 vol % in beverages (beers, wines, and spirits). While CDs are excellent candidates to demonstrate deep learning for optical sensing, the methods discussed in this work are promising for improving chemical sensing using various luminescent materials.

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Section: Methodsmentioning

confidence: 99%

Utilizing Deep Learning to Enhance Optical Sensing of Ethanol Content Based on Luminescent Carbon Dots

Döring

Rogach

2022

ACS Appl. Nano Mater.

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“…The used dataset was obtained from a medical database, the Pima Indian Database. Moreover, Abayomi-Alli et al [24] developed a system to enhance the early detection of PD using a deep learning network called bidirectional LSTM (BiLSTM) through data augmentation for tiny datasets, while Ogundokun et al [25] used two computational intelligence methods, which are decision tree (DT) and K-nearest neighbor (KNN) for heart disease detection. They utilized the autoencoder feature extraction algorithm to minimize the features required to describe the heart disease dataset.…”

Section: Motivation and Problem Formulationmentioning

confidence: 99%

Hepatitis C Virus prediction based on machine learning framework: a real-world case study in Egypt

2023

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Prediction and classification of diseases are essential in medical science, as it attempts to immune the spread of the disease and discover the infected regions from the early stages. Machine learning (ML) approaches are commonly used for predicting and classifying diseases that are precisely utilized as an efficient tool for doctors and specialists. This paper proposes a prediction framework based on ML approaches to predict Hepatitis C Virus among healthcare workers in Egypt. We utilized real-world data from the National Liver Institute, founded at Menoufiya University (Menoufiya, Egypt). The collected dataset consists of 859 patients with 12 different features. To ensure the robustness and reliability of the proposed framework, we performed two scenarios: the first without feature selection and the second after the features are selected based on sequential forward selection (SFS). Furthermore, the feature subset selected based on the generated features from SFS is evaluated. Naïve Bayes, random forest (RF), K-nearest neighbor, and logistic regression are utilized as induction algorithms and classifiers for model evaluation. Then, the effect of parameter tuning on learning techniques is measured. The experimental results indicated that the proposed framework achieved higher accuracies after SFS selection than without feature selection. Moreover, the RF classifier achieved 94.06% accuracy with a minimum learning elapsed time of 0.54 s. Finally, after adjusting the hyperparameter values of the RF classifier, the classification accuracy is improved to 94.88% using only four features.

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“…T ODAY, clinical practice is an area of interest and research where extensive research and technical recommendations have been developed in response to increasingly complex challenges [1], [2], [3]. Identifying and analyzing diseases is increasingly difficult because they are ever more sophisticated.…”

Section: Introductionmentioning

confidence: 99%

Classification-Segmentation Pipeline for MRI via Transfer Learning and Residual Networks

Duong-Trung¹,

Ha²,

Huynh³

2022

Proceedings of the Sixth International Conference on Research in Intelligent and Computing

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Artificial intelligence association into brain magnetic resonance imaging (MRI) and clinical practices embrace substantial cancer diagnosis improvement. The advancement of deep learning has improved the processing and analysis of MRI, boosting models' performance, decreasing the destructive effects of data sources overload, and increasing accurate detection and time efficacy. However, that specific dataset leads to diverse research fields such as image processing and analysis, detection, registration, segmentation, and classification. This paper proposes a decision-making pipeline for MRI data by combining image classification and segmentation. First, the pipeline should correctly produce a correct decision given an MRI image. If the figure is classified as defective, the pipeline can extract defect regions and highlight them accordingly. We have implemented several advanced convolutional neural networks with transfer learning and residual techniques to address two broad clinical concerns in one decision-making workflow.

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BiLSTM with Data Augmentation using Interpolation Methods to Improve Early Detection of Parkinson Disease

Cited by 28 publications

References 44 publications

Utilizing Deep Learning to Enhance Optical Sensing of Ethanol Content Based on Luminescent Carbon Dots

Utilizing Deep Learning to Enhance Optical Sensing of Ethanol Content Based on Luminescent Carbon Dots

Hepatitis C Virus prediction based on machine learning framework: a real-world case study in Egypt

Classification-Segmentation Pipeline for MRI via Transfer Learning and Residual Networks

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