Deep-learning enabled rapid and low-cost detection of microplastics in consumer products following on-site extraction and image processing
Md. Zayed Bin Zahir Arju, Nafisa Amin Hridi, Lamiya Dewan, Suhaila Suhaila, Md. Nurul Amin, Taslim Ur Rashid, Abul Kalam Azad, Sejuti Rahman, Mainul Hossain, Ahsan Habib
Abstract
) to oxidize organic matter. A commercially available miniaturized microscopy attachment (TinyScope, $10) is fixed on top of an ordinary cell phone camera and is used to capture about 2490 images of MPs obtained from five different product categories. The YOLOv5 deep learning model was used to detect microplastics in images. It was trained on a dataset of 1990 images, validated with 250 images, and tested on a separate set of 250 images. The presence of plastic content in the detected samples was confirmed by performing attenuated total reflectance-Fourier transform infrared (ATR-FTIR) spectroscopy and the morphologies of the MPs were determined using the field-emission scanning electron microscopy (FE-SEM). Results show that the deep-learning enabled image processing approach can identify MPs with an accuracy of 98%. Overall, the fast, accurate, and affordable detection of MPs in low-resource settings can lead to the monitoring of MP content in consumer products on a more frequent basis.