Design of Metaheuristic Optimization‐Based Vascular Segmentation Techniques for Photoacoustic Images

Vaiyapuri, Thavavel; Dutta, Ashit Kumar; Sikkandar, Mohamed Yacin; Gupta, Deepak; Alouffi, Bader; Alharbi, Abdullah; Rauf, Hafiz Tayyab; Kadry, Seifedine

doi:10.1155/2022/4736113

Cited by 5 publications

(4 citation statements)

References 23 publications

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“…Several methodologies are currently employed for microvessel segmentation in endogenous contrast PAI such as the threshold-based segmentation [76,103], morphology-based segmentation [72,73,78,104,105], and deep learning-based segmentation [75,79,106,107]. While these methodologies are able to directly measure MVD based on microvessel segmentation, they have only been applied to microscopic or mesoscopic imaging configurations [72][73][74][75][76][77][78][79][80][103][104][105][106][107][108] that provide high resolution but lack sufficient penetration depth to enable 3D visualization in a clinical setting. This reiterates the need to develop vascular segmentation or classification methodologies which can be applied to macroscopic, relatively low resolution photoacoustic images.…”

Section: Discussionmentioning

confidence: 99%

“…Comprehensive knowledge of the microvascular alterations within a tumor in response to anti-angiogenic therapy is crucial for optimizing efficacy and predicting long-term effects. Several methodologies are currently employed for microvessel segmentation in endogenous contrast PAI such as the threshold-based segmentation [76,103], morphology-based segmentation [72,73,78,104,105], and deep learning-based segmentation [75,79,106,107]. While these methodologies are able to directly measure MVD based on microvessel segmentation, they have only been applied to microscopic or mesoscopic imaging configurations [72][73][74][75][76][77][78][79][80][103][104][105][106][107][108] that provide high resolution but lack sufficient penetration depth to enable 3D visualization in a clinical setting.…”

Section: Discussionmentioning

confidence: 99%

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Vascular regional analysis unveils differential responses to anti-angiogenic therapy in pancreatic xenografts through macroscopic photoacoustic imaging

Sweeney,

Xavierselvan,

Langley

et al. 2024

Preprint

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Pancreatic cancer (PC) is a highly lethal malignancy and the third leading cause of cancer deaths in the U.S. Despite major innovations in imaging technologies, there are limited surrogate radiographic indicators to aid in therapy planning and monitoring. Amongst the various imaging techniques Ultrasound-guided photoacoustic imaging (US-PAI) is a promising modality based on endogenous blood (hemoglobin) and blood oxygen saturation (StO2) contrast to monitor response to anti-angiogenic therapies. Adaptation of US-PAI to the clinical realm requires macroscopic configurations for adequate depth visualization, illuminating the need for surrogate radiographic markers, including the tumoral microvessel density (MVD). In this work, subcutaneous xenografts with PC cell lines AsPC-1 and MIA-PaCa-2 were used to investigate the effects of receptor tyrosine kinase inhibitor (sunitinib) treatment on MVD and StO2. Through histological correlation, we have shown that regions of high and low vascular density (HVD and LVD) can be identified through frequency domain filtering of macroscopic PA images which could not be garnered from purely global analysis. We utilized vascular regional analysis (VRA) of treatment-induced StO2and total hemoglobin (HbT) changes. VRA as a tool to monitor treatment response allowed us to identify potential timepoints of vascular remodeling, highlighting its ability to provide insights into the TME not only for sunitinib treatment but also other anti-angiogenic therapies.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Vascular regional analysis unveils differential responses to anti-angiogenic therapy in pancreatic xenografts through macroscopic photoacoustic imaging

Sweeney,

Xavierselvan,

Langley

et al. 2024

Preprint

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“…In the clinical setting, analysis of the medical image was usually conducted by trained experts such as radiologists and physicians in order to diagnose and understand the disease. However, these experts usually faced fatigue owing to pathologic variations and because this type of analysis requires laborious and tedious work [ 2 ]. In this sense, automated image analysis tools play an essential role in supporting clinicians to improve their examinations.…”

Section: Introductionmentioning

confidence: 99%

Deep Learning Approaches for Automatic Localization in Medical Images

Alaskar

Hussain

ِAlmaslukh

et al. 2022

Computational Intelligence and Neuroscience

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Recent revolutionary advances in deep learning (DL) have fueled several breakthrough achievements in various complicated computer vision tasks. The remarkable successes and achievements started in 2012 when deep learning neural networks (DNNs) outperformed the shallow machine learning models on a number of significant benchmarks. Significant advances were made in computer vision by conducting very complex image interpretation tasks with outstanding accuracy. These achievements have shown great promise in a wide variety of fields, especially in medical image analysis by creating opportunities to diagnose and treat diseases earlier. In recent years, the application of the DNN for object localization has gained the attention of researchers due to its success over conventional methods, especially in object localization. As this has become a very broad and rapidly growing field, this study presents a short review of DNN implementation for medical images and validates its efficacy on benchmarks. This study presents the first review that focuses on object localization using the DNN in medical images. The key aim of this study was to summarize the recent studies based on the DNN for medical image localization and to highlight the research gaps that can provide worthwhile ideas to shape future research related to object localization tasks. It starts with an overview on the importance of medical image analysis and existing technology in this space. The discussion then proceeds to the dominant DNN utilized in the current literature. Finally, we conclude by discussing the challenges associated with the application of the DNN for medical image localization which can drive further studies in identifying potential future developments in the relevant field of study.

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“…Besides, NasNet-based feature extractor with stochastic gradient descent is applied for feature extraction. Finally, realizing the significance of the parameter optimization in enhancing the model performance [ 12 , 13 ], the manta ray foraging optimization (MRFO) algorithm with cascaded neural network (CNN) is exploited for the classification process. To ensure the better outcomes of the CIMDC-DI technique, a wide-ranging simulation analysis was carried out and the results are assessed under distinct aspects.…”

Section: Introductionmentioning

confidence: 99%

Computational Intelligence-Based Melanoma Detection and Classification Using Dermoscopic Images

Vaiyapuri

Balaji

Shridevi

et al. 2022

Computational Intelligence and Neuroscience

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Melanoma is a kind of skin cancer caused by the irregular development of pigment-producing cells. Since melanoma detection efficiency is limited to different factors such as poor contrast among lesions and nearby skin regions, and visual resemblance among melanoma and non-melanoma lesions, intelligent computer-aided diagnosis (CAD) models are essential. Recently, computational intelligence (CI) and deep learning (DL) techniques are utilized for effective decision-making in the biomedical field. In addition, the fast-growing advancements in computer-aided surgeries and recent progress in molecular, cellular, and tissue engineering research have made CI an inevitable part of biomedical applications. In this view, the research work here develops a novel computational intelligence-based melanoma detection and classification technique using dermoscopic images (CIMDC-DIs). The proposed CIMDC-DI model encompasses different subprocesses. Primarily, bilateral filtering with fuzzy k-means (FKM) clustering-based image segmentation is applied as a preprocessing step. Besides, NasNet-based feature extractor with stochastic gradient descent is applied for feature extraction. Finally, the manta ray foraging optimization (MRFO) algorithm with a cascaded neural network (CNN) is exploited for the classification process. To ensure the potential efficiency of the CIMDC-DI technique, we conducted a wide-ranging simulation analysis, and the results reported its effectiveness over the existing recent algorithms with the maximum accuracy of 97.50%.

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Design of Metaheuristic Optimization‐Based Vascular Segmentation Techniques for Photoacoustic Images

Cited by 5 publications

References 23 publications

Vascular regional analysis unveils differential responses to anti-angiogenic therapy in pancreatic xenografts through macroscopic photoacoustic imaging

Vascular regional analysis unveils differential responses to anti-angiogenic therapy in pancreatic xenografts through macroscopic photoacoustic imaging

Deep Learning Approaches for Automatic Localization in Medical Images

Computational Intelligence-Based Melanoma Detection and Classification Using Dermoscopic Images

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