Volume 14 , Issue 2 , PP: 101-114, 2024 | Cite this article as | XML | Html | PDF | Full Length Article
Koppagiri Jyothsna Devi 1 , Gouranga Mandal 2 *
Doi: https://doi.org/10.54216/JCIM.140207
For biomedical image analysis, instance segmentation is crucial. It is still difficult because of the intricate backdrop elements, the significant variation in object appearances, the large number of overlapping items, and the hazy object borders. Deep learning-based techniques, which may be separated into proposal-free and proposal-based approaches, have been frequently employed recently to overcome these challenges. The existing approaches experience information loss due to their concentration on either local-level instance features or global-level semantics. To solve this problem, this work proposes an improved dense Net ( ) that mixes instance and semantic data. The suggested promotes the acquisition of semantic contextual information by the instance branch by linking instance prediction and semantic features via a residual attention feature integration strategy. The confidence score of each item is then matched with the accuracy of the prediction using a dense quality sub-branch that is created. A consistency regularisation technique is also proposed for the robust learning of segmentation for instance branches and the semantic segments tasks. By proving its utility, the proposed outperforms prevailing approaches on various biomedical datasets.
panoptic segmentation , multi-modal , prediction: semantic features , instance
[1] Xing and L. Yang, “Robust nucleus/cell detection and segmentation in digital pathology and microscopy images: A comprehensive review,” IEEE Rev. Biomed. Eng., vol. 9, pp. 234–263, 2016.
[2] Song, L. Xiao, and Z. Lian, “Contour-seed pairs learning-based framework for simultaneously detecting and segmenting various overlapping cells/nuclei in microscopy images,” IEEE Trans. Image Process., vol. 27, no. 12, pp. 5759–5774, Dec. 2018.
[3] Payer, D. Štern, M. Feiner, H. Bischof, and M. Urschler, “Segmenting and tracking cell instances with cosine embeddings and recurrent hourglass networks,” Med. Image Anal., vol. 57, pp. 106–119, Oct. 2019
[4] De Brabandere, D. Neven, and L. Van Gool, “Semantic instance segmentation with a discriminative loss function,” 2017, arXiv:1708.02551. [Online]. Available: http://arxiv.org/abs/1708.02551
[5] Ambeth Kumar, V.D. (2017). Automation of Image Categorization with Most Relevant Negatives. Pattern Recognition and Image Analysis, 27(3), 371–379.
[6] Kumar, I., Kumar, A., Kumar, V.D.A. et al. (2022) Dense Tissue Pattern Characterization Using Deep Neural Network. Cogn Comput 14, 1728–1751.
[7] Liu et al., “Nuclei segmentation via a deep panoptic model with semantic feature integration,” in Proc. 28th Int. Joint Conf. Artif. Intell., AAAI Press, Aug. 2019, pp. 861–868.
[8] Chen, A. Hermans, G. Papandreou, F. Schroff, P. Wang, and H. Adam, “MaskLab: Instance segmentation by refining object detection with semantic and direction features,” in Proc. IEEE/CVF Conf. Comput. Vis. Pattern Recognit., Jun. 2018, pp. 4013–4022
[9] Ambeth Kumar, V.D. Vaishali,S. Shweta, B. (2015). Basic Study of the Human Foot. Biomedical and Pharmacology, 8(1), 435-444.
[10] Y. Li et al., “Attention-guided unified network for panoptic segmentation,” in Proc. IEEE/CVF Conf. Comput. Vis. Pattern Recognit. (CVPR), Jun. 2019, pp. 7026–7035.
[11] Chen et al., “Hybrid task cascade for instance segmentation,” in Proc. IEEE/CVF Conf. Comput. Vis. Pattern Recognit. (CVPR), Jun. 2019, pp. 4974–4983.
[12] He, X. Zhang, S. Ren, and J. Sun, “Deep residual learning for image recognition,” in Proc. IEEE Conf. Comput. Vis. Pattern Recognit. (CVPR), Jun. 2016, pp. 770–778.
[13] Lin, P. Dollar, R. Girshick, K. He, B. Hariharan, and S. Belongie, “Feature pyramid networks for object detection,” in Proc. IEEE Conf. Comput. Vis. Pattern Recognit. (CVPR), Jul. 2017, pp. 2117–2125.
[14] Ambeth Kumar, V.D. Ramakrishnan,M. (2013). Temple and Maternity Ward Security using FPRS. Journal of Electrical Engineering & Technology, 8(3), 633-637.
[15] Salvador et al., “Recurrent neural networks for semantic instance segmentation,” 2017, arXiv:1712.00617. [Online]. Available: http://arxiv.org/abs/1712.00617
[16] Cuocolo, R.; Stanzione, A.; Ponsiglione, A.; Romeo, V.; Verde, F.; Creta, M.; La Rocca, R.; Longo, N.; Pace, L.; Imbriaco, M. Clinically significant prostate cancer detection on MRI: A radio mic shape features study. Eur. J. Radiol. 2019, 116, 144–149.
[17] Comelli, A.; Bignardi, S.; Stefano, A.; Russo, G.; Sabini, MG; Ippolito, M.; Yezzi, A. Development of a new fully three-dimensional methodology for tumour delineation in functional images. Comput. Biol. Med. 2020, 120, 103701.
[18] Christe, A.; Peters, A.A.; Drakopoulos, D.; Heverhagen, J.T.; Geiser, T.; Stathopoulou, T.; Christodoulidis, S.; Anthimopoulos, M.; Mougiakakou, S.G.; Ebner, L. Computer-Aided Diagnosis of Pulmonary Fibrosis Using Deep Learning and CT Images. Invest. Radiol. 2019, 54, 627–632.
[19] Kumar, V.D.A., Sharmila, S., Kumar, A. et al. (2023). A novel solution for finding postpartum haemorrhage using fuzzy neural techniques. Neural Comput & Applic. 35(33), 23683–23696
[20] Torrisi, S.E.; Palmucci, S.; Stefano, A.; Russo, G.; Torcitto, A.G.; Falsaperla, D.; Gioè, M.; Pavone, M.; Vancheri, A.; Sambataro, G.; et al. Assessment of survival in patients with idiopathic pulmonary fibrosis using quantitative HRCT indexes. Multidiscip. Respir. Med. 2018, 13, 1–8.
[21] Gerard, S.E.; Herrmann, J.; Kaczka, D.W.; Musch, G.; Fernandez-Bustamante, A.; Reinhardt, J.M. Multi-resolution convolutional neural networks for fully automated segmentation of acutely injured lungs in multiple species. Med. Image Anal. 2020, 60, 101592.
[22] Sun, K.; Xiao, B.; Liu, D.; Wang, J. Deep, high-resolution representation learning for human pose estimation. In Proceedings of the IEEE Computer Society Conference on Computer Vision and Pattern Recognition, Long Beach, CA, USA, 16–20 June 2019; pp. 5686–5696.
[23] Cuocolo, R.; Cipullo, MB; Stanzione, A.; Ugga, L.; Romeo, V.; Radice, L.; Brunetti, A.; Imbriaco, M. Machine learning applications in prostate cancer magnetic resonance imaging. Eur. Radiol. Exp. 2019, 3, 35.
[24] Sathya Preiya, V., and V. D. Ambeth Kumar. (2023). Deep Learning-Based Classification and Feature Extraction for Predicting Pathogenesis of Foot Ulcers in Patients with Diabetes. Diagnostics 13(12), 1983.
[25] Park, B.; Park, H.; Lee, S.M.; Seo, J.B.; Kim, N. Lung Segmentation on HRCT and Volumetric CT for Diffuse Interstitial Lung Disease Using Deep Convolutional Neural Networks. J. Digit. Imaging 2019, 32, 1019–1026
[26] Hemamalini, Selvamani, and Visvam Devadoss Ambeth Kumar. (2022). Outlier Based Skimpy Regularization Fuzzy Clustering Algorithm for Diabetic Retinopathy Image Segmentation. Symmetry, 14(12), 2512
[27] Piyush K. Pareek, Pixel Level Image Fusion in Moving objection Detection and Tracking with Machine Learning “,Fusion: Practice and Applications, Volume 2 , Issue 1 , PP: 42-60, 2020
[28] Shivam Grover, Kshitij Sidana, Vanita Jain, “Egocentric Performance Capture: A Review”, Fusion: Practice and Applications, Volume 2, Issue 2 , PP: 64-73, 2020.
[29] Abdel Nasser H. Zaied, Mahmoud Ismail and Salwa El- Sayed, A Survey on Meta-heuristic Algorithms for Global Optimization Problems, Journal of Intelligent Systems and Internet of Things,Volume 1 , Issue 1 , PP: 48-60, 2020
[30] Mahmoud H.Alnamoly, Ahmed M. Alzohairy, Ibrahim M. El-Henawy, “A survey on gel images analysis software tools, Journal of Intelligent Systems and Internet of Things,Volume 1 , Issue 1 , PP: 40-47, 2021.