Assessing the Potential of PlanetScope Satellite Imagery to Estimate Particulate Matter Oxidative Potential

TL;DR

This study explores using PlanetScope satellite imagery combined with deep learning to estimate particulate matter's oxidative potential, a key indicator of air pollution toxicity, at high spatial resolution.

Contribution

It introduces a novel approach employing satellite images and neural networks to estimate oxidative potential, expanding monitoring capabilities beyond traditional methods.

Findings

Model explains over 50% of OP variation with satellite data.

Achieves around 32-37% relative MAE in predictions.

Potential for low-cost, high-resolution OP monitoring.

Abstract

Oxidative potential (OP), which measures particulate matter's (PM) capacity to induce oxidative stress in the lungs, is increasingly recognized as an indicator of PM toxicity. Since OP is not routinely monitored, it can be challenging to estimate exposure and health impacts. Remote sensing data are commonly used to estimate PM mass concentration, but have never been used to estimate OP. In this study, we evaluate the potential of satellite images to estimate OP as measured by acellular ascorbic acid (OP AA) and dithiothreitol (OP DTT) assays of 24-hour PM10 sampled periodically over five years at three locations around Grenoble, France. We use a deep convolutional neural network to extract features of daily 3 m/pixel PlanetScope satellite images and train a multilayer perceptron to estimate OP at a 1 km spatial resolution based on the image features and common meteorological variables. The model captures more than half of the variation in OP AA and almost half of the variation in OP DTT (test set R2 = 0.62 and 0.48, respectively), with relative mean absolute error (MAE) of about 32%. Using only satellite images, the model still captures about half of the variation in OP AA and one third of the variation in OP DTT (test set R2 = 0.49 and 0.36, respectively) with relative MAE of about 37%. If confirmed in other areas, our approach could represent a low-cost method for expanding the temporal or spatial coverage of OP estimates.