IoT based lung cancer detection using machine learning and cuckoo search optimization

Venkatesh, C.; Bojja, Polaiah

doi:10.1108/ijpcc-10-2020-0160

Cited by 6 publications

(1 citation statement)

References 26 publications

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“…Overall achieved results for distinguishing patients from healthy control with 94% and 76%, while Covid-19 and other patients with lung infection classification rates were 90% and 95% respectively. In the study [17], the authors proposed a method to diagnose lung cancer using the Cuckoo search algorithm. Otsu thresholding, along with local binary patterns, is used to extract the features from CT images.…”

Section: Literature Reviewmentioning

confidence: 99%

The IOMT-Based Risk-Free Approach to Lung Disorders Detection from Exhaled Breath Examination

Ghani¹,

Gilanie²

2023

Intelligent Automation &Amp; Soft Computing

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The lungs are the main fundamental part of the human respiratory system and are among the major organs of the human body. Lung disorders, including Coronavirus , are among the world's deadliest and most life-threatening diseases. Early and social distance-based detection and treatment can save lives as well as protect the rest of humanity. Even though X-rays or Computed Tomography (CT) scans are the imaging techniques to analyze lungrelated disorders, medical practitioners still find it challenging to analyze and identify lung cancer from scanned images. unless COVID-19 reaches the lungs, it is unable to be diagnosed. through these modalities. So, the Internet of Medical Things (IoMT) and machine learning-based computer-assisted approaches have been developed and applied to automate these diagnostic procedures. This study also aims at investigating an automated approach for the detection of COVID-19 and lung disorders other than COVID-19 infection in a non-invasive manner at their early stages through the analysis of human breath. Human breath contains several volatile organic compounds, i.e., water vapor (5.0%-6.3%), nitrogen (79%), oxygen (13.6%-16.0%), carbon dioxide (4.0%-5.3%), argon (1%), hydrogen (1 ppm) (parts per million), carbon monoxide (1%), proteins (1%), isoprene (1%), acetone (1%), and ammonia (1%). Beyond these limits, the presence of a certain volatile organic compound (VOC) may indicate a disease. The proposed research not only aims to increase the accuracy of lung disorder detection from breath analysis but also to deploy the model in a real-time environment as a home appliance. Different sensors detect VOC; microcontrollers and machine learning models have been used to detect these lung disorders. Overall, the suggested methodology is accurate, efficient, and non-invasive. The proposed method obtained an accuracy of 93.59%, a sensitivity of 89.59%, a specificity of 94.87%, and an AUC-Value of 0.96.

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Section: Literature Reviewmentioning

confidence: 99%