AI Article Synopsis
- There are ongoing efforts to use surface water for power, materials, and food, but contamination from human activities, like agriculture and electronics, poses significant challenges.
- Herbicides and emerging contaminants, such as rare earth elements, are particularly harmful to aquatic environments, with duckweed being a useful species for testing toxicity.
- This study utilizes a machine learning tool, StarDist, integrated with ImageJ and Python, to automate the counting of duckweed fronds and assess the toxicity of different contaminants, revealing Dysprosium as the most toxic and Samarium as the least toxic.
Article Abstract
In recent years, there have been efforts to utilize surface water as a power source, material, and food. However, these efforts are impeded due to the vast amounts of contaminants and emerging contaminants introduced by anthropogenic activities. Herbicides such as Glyphosate and Glufosinate are commonly known to contaminate surface water through agricultural industries. In contrast, some emerging contaminants, such as rare earth elements, have started to enter the surface water from the production and waste of electronic products. Duckweeds are angiosperms from the family and have been used for toxicity tests in aquatic environments, mainly those from the genus , and have been approved by OECD. In this study, we used duckweed from the genus , which is smaller and considered a good indicator of metal pollutants in the aquatic environment. The growth rate of duckweed is the most common endpoint in observing pollutant toxicity. In order to observe and mark the fronds automatically, we used StarDist, a machine learning-based tool. StarDist is available as a plugin in ImageJ, simplifying and assisting the counting process. Python also helps arrange, manage, and calculate the inhibition percentage after duckweeds are exposed to contaminants. The toxicity test results showed Dysprosium to be the most toxic, with an IC value of 14.6 ppm, and Samarium as the least toxic, with an IC value of 279.4 ppm. In summary, we can provide a workflow for automatic frond counting using StarDist integrated with ImageJ and Python to simplify the detection, counting, data management, and calculation process.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10457735 | PMC |
| http://dx.doi.org/10.3390/toxics11080680 | DOI Listing |
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