Quantification of Radiomics features of Peritumoral Vasogenic Edema extracted from fluid‐attenuated inversion recovery images in glioblastoma and isolated brain metastasis, using T1‐dynamic contrast‐enhanced Perfusion analysis

Parvaze, P. Suhail; Bhattacharjee, Rupsa; Verma, Yogesh Kumar; Singh, Rajesh; Yadav, Virendra Kumar; Singh, Anup; Khanna, Gaurav; Ahlawat, Sunita; Trivedi, Richa; Patir, Rana; Vaishya, Sandeep; Shah, Tushar A.; Gupta, Rakesh K.

doi:10.1002/nbm.4884

Cited by 9 publications

(2 citation statements)

References 42 publications

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“…Compression models are essential for efficiently retrieving data and for transmission to satisfy the requirements of multimedia applications [62,63]. Early discovery of retinopathy due to diabetes by Thippa et al employed a Deep Learning model based on the PCA-Firefly process [64,65]. Recent studies have utilized radiomics analysis and ML techniques to generate probability maps and radiomics-based feature maps to extract diagnostic information from MRI-based brain tumor images [66].…”

Section: Role Of Vesselnessmentioning

confidence: 99%

Robust Machine Learning Technique to Classify COVID-19 Using Fusion of Texture and Vesselness of X-Ray Images

Basha,

Albuquerque,

Chelloug

et al. 2024

CMES

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Manual investigation of chest radiography (CXR) images by physicians is crucial for effective decision-making in COVID-19 diagnosis. However, the high demand during the pandemic necessitates auxiliary help through image analysis and machine learning techniques. This study presents a multi-threshold-based segmentation technique to probe high pixel intensity regions in CXR images of various pathologies, including normal cases. Texture information is extracted using gray co-occurrence matrix (GLCM)-based features, while vessel-like features are obtained using Frangi, Sato, and Meijering filters. Machine learning models employing Decision Tree (DT) and Random Forest (RF) approaches are designed to categorize CXR images into common lung infections, lung opacity (LO), COVID-19, and viral pneumonia (VP). The results demonstrate that the fusion of texture and vesselbased features provides an effective ML model for aiding diagnosis. The ML model validation using performance measures, including an accuracy of approximately 91.8% with an RF-based classifier, supports the usefulness of the feature set and classifier model in categorizing the four different pathologies. Furthermore, the study investigates the importance of the devised features in identifying the underlying pathology and incorporates histogrambased analysis. This analysis reveals varying natural pixel distributions in CXR images belonging to the normal, COVID-19, LO, and VP groups, motivating the incorporation of additional features such as mean, standard deviation, skewness, and percentile based on the filtered images. Notably, the study achieves a considerable improvement in categorizing COVID-19 from LO, with a true positive rate of 97%, further substantiating the effectiveness of the methodology implemented.

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Section: Role Of Vesselnessmentioning

confidence: 99%

Robust Machine Learning Technique to Classify COVID-19 Using Fusion of Texture and Vesselness of X-Ray Images

Basha,

Albuquerque,

Chelloug

et al. 2024

CMES

View full text Add to dashboard Cite

show abstract

“…Moreover, Wang et al fused individual features from both CNN and GCN to assist radiologists in rapidly detecting COVID-19 from chest CT images [ 54 ]. Parvaze et al extracting crafted features to analyze and identification the pathologies features of peritumoral vasogenic edema [ 35 , 36 ].…”

Section: Introductionmentioning

confidence: 99%

Structure-constrained deep feature fusion for chronic otitis media and cholesteatoma identification

Cao

Song

et al. 2023

Multimed Tools Appl

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Chronic suppurative otitis media (CSOM) and middle ear cholesteatoma (MEC) were two most common chronic middle ear disease(MED) clinically. Accurate differential diagnosis between these two diseases is of high clinical importance given the difference in etiologies, lesion manifestations and treatments. The high-resolution computed tomography (CT) scanning of the temporal bone presents a better view of auditory structures, which is currently regarded as the first-line diagnostic imaging modality in the case of MED. In this paper, we first used a region-of-interest (ROI) network to find the area of the middle ear in the entire temporal bone CT image and segment it to a size of 100*100 pixels. Then, we used a structure-constrained deep feature fusion algorithm to convert different characteristic features of the middle ear in three groups as suppurative otitis media (CSOM), middle ear cholesteatoma (MEC) and normal patches. To fuse structure information, we introduced a graph isomorphism network that implements a feature vector from neighbourhoods and the coordinate distance between vertices. Finally, we construct a classifier named the “otitis media, cholesteatoma and normal identification classifier” (OMCNIC). The experimental results achieved by the graph isomorphism network revealed a 96.36% accuracy in all CSOM and MEC classifications. The experimental results indicate that our structure-constrained deep feature fusion algorithm can quickly and effectively classify CSOM and MEC. It will help otologist in the selection of the most appropriate treatment, and the complications can also be reduced.

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Machine learning for predicting post-operative outcomes in meningiomas: a systematic review and meta-analysis

Abualnaja,

Morris,

Rashid

et al. 2024

Acta Neurochir

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Purpose Meningiomas are the most common primary brain tumour and account for over one-third of cases. Traditionally, estimations of morbidity and mortality following surgical resection have depended on subjective assessments of various factors, including tumour volume, location, WHO grade, extent of resection (Simpson grade) and pre-existing co-morbidities, an approach fraught with subjective variability. This systematic review and meta-analysis seeks to evaluate the efficacy with which machine learning (ML) algorithms predict post-operative outcomes in meningioma patients. Methods A literature search was conducted in December 2023 by two independent reviewers through PubMed, DARE, Cochrane Library and SCOPUS electronic databases. Random-effects meta-analysis was conducted. Results Systematic searches yielded 32 studies, comprising 142,459 patients and 139,043 meningiomas. Random-effects meta-analysis sought to generate restricted maximum-likelihood estimates for the accuracy of alternate ML algorithms in predicting several postoperative outcomes. ML models incorporating both clinical and radiomic data significantly outperformed models utilizing either data type alone as well as traditional methods. Pooled estimates for the AUCs achieved by different ML algorithms ranged from 0.74–0.81 in the prediction of overall survival and progression-/recurrence-free survival, with ensemble classifiers demonstrating particular promise for future clinical application. Additionally, current ML models may exhibit a bias in predictive accuracy towards female patients, presumably due to the higher prevalence of meningiomas in females. Conclusion This review underscores the potential of ML to improve the accuracy of prognoses for meningioma patients and provides insight into which model classes offer the greatest potential for predicting survival outcomes. However, future research will have to directly compare standardized ML methodologies to traditional approaches in large-scale, prospective studies, before their clinical utility can be confidently validated.

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Quantification of Radiomics features of Peritumoral Vasogenic Edema extracted from fluid‐attenuated inversion recovery images in glioblastoma and isolated brain metastasis, using T1‐dynamic contrast‐enhanced Perfusion analysis

Cited by 9 publications

References 42 publications

Robust Machine Learning Technique to Classify COVID-19 Using Fusion of Texture and Vesselness of X-Ray Images

Robust Machine Learning Technique to Classify COVID-19 Using Fusion of Texture and Vesselness of X-Ray Images

Structure-constrained deep feature fusion for chronic otitis media and cholesteatoma identification

Machine learning for predicting post-operative outcomes in meningiomas: a systematic review and meta-analysis

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