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RESEARCH ARTICLE (Open Access)
Contents Vol 51(1)

Automated Tasmanian devil segmentation and devil facial tumour disease classification

Fatih Veysel Nurçin https://orcid.org/0000-0003-3850-7061 A * , Niyazi Şentürk A , Elbrus Imanov B , Sam Thalmann C and Karen Fagg C
+ Author Affiliations
- Author Affiliations

A Department of Biomedical Engineering, Near East University, TRNC Mersin 10, Nicosia 99138, Turkey.

B Department of Computer Engineering, Near East University, TRNC Mersin 10, Nicosia 99138, Turkey.

C Save the Tasmanian Devil Program, Department of Natural Resources and Environment, Hobart, Tas. 7001, Australia.

* Correspondence to: fatihnurcin1@gmail.com

Handling Editor: Guangshun Jiang

Wildlife Research 51, WR22155 https://doi.org/10.1071/WR22155
Submitted: 21 September 2022  Accepted: 11 April 2023  Published: 5 June 2023

© 2024 The Author(s) (or their employer(s)). Published by CSIRO Publishing

Abstract

Context

Artificial intelligence algorithms are beneficial for automating the monitoring of threatened species. Devil facial tumour disease (DFTD) is an endemic disease threatening Australia’s Tasmanian devil. The disease is a cancer that can be transmitted from one devil to another during social interactions. Cameras and trapping techniques have been employed to monitor the spread of the disease in the wild. The use of cameras allows for more frequent monitoring of devils than does trapping, but differentiating wounds from tumours in images is challenging, and this requires time and expertise.

Aim

The purpose of this work is to develop a computer vision system to assist in the monitoring of DFTD spread.

Method

We propose a system that involves image segmentation, feature extraction, and classification steps. U-net architecture, global average pooling layer of pre-trained Resnet-18, and support vector machine (SVM) classifiers were employed for these purposes, respectively. In total, 1250 images of 961 healthy and 289 diseased (DFTD) devils were separated into training, validation, and testing sets.

Results

The proposed algorithm achieved 92.4% classification accuracy for the differentiation of healthy devils from those with DFTD.

Conclusion

The high classification accuracy means that our method can help field workers with monitoring devils.

Implications

The proposed approach will allow for more frequent analysis of devils while reducing the workload of field staff. Ultimately, this automation could be expanded to other species for simultaneous monitoring at shorter intervals to facilitate broadened ecological assessments.

Keywords: classification, conservation, DFTD, ecology, segmentation, support vector machine, threatened species, U-net architecture.

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