Test–Retest Reproducibility Analysis of Lung CT Image Features

Balagurunathan, Yoganand; Kumar, Virendra; Gu, Yi; Kim, Jongphil; Wang, Hua; Liu, Ying; Goldgof, Dmitry B.; Hall, Lawrence O.; Korn, R; Zhao, Binsheng; Schwartz, Lawrence H.; Basu, Shibani; Eschrich, Steven; Gatenby, Robert A.; Gillies, Robert J.

doi:10.1007/s10278-014-9716-x

Cited by 210 publications

(193 citation statements)

References 33 publications

Supporting

Mentioning

188

Contrasting

Unclassified

Order By: Relevance

“…95 In NSCLC, quantitative imaging features have been used to distinguish between adenocarcinoma and squamous cell subtypes and suggest tumor characteristics such as stage, metabolism, hypoxia, angiogenesis, and prognosis. 96,97 Using a publicly available dataset consisting of 32 NSCLC patients, Kumar and colleagues 98 have identified 39 of 327 CT features that are reproducible, nonredundant, and informative. Recently, quantitative CT texture and spatial analysis techniques used to analyze mediastinal lymph nodes in 43 patients with primary lung malignancies showed a sensitivity of 81% and specificity of 80% for detecting nodal metastatic disease.…”

Section: Future Directions Quantitative Imagingmentioning

confidence: 99%

Staging of Lung Cancer

Groot

Carter

Cuellar

et al. 2015

Clinics in Chest Medicine

View full text Add to dashboard Cite

Section: Future Directions Quantitative Imagingmentioning

confidence: 99%

Staging of Lung Cancer

Groot

Carter

Cuellar

et al. 2015

Clinics in Chest Medicine

View full text Add to dashboard Cite

“…At the time neither the image quality nor the computational capacity was sufficient to operate with textural features. Thanks to recent advances in imaging and computational fields, several groups have investigated the potential of textural features in light of in vivo disease characterization [8,28,56,[148][149][150]. Routine clinical evaluation of PET images relies on the statistical analysis of Standardized Uptake Values (SUV) [151].…”

Section: Radiomicsmentioning

confidence: 99%

Personalizing Medicine Through Hybrid Imaging and Medical Big Data Analysis

et al. 2018

View full text Add to dashboard Cite

Medical imaging has evolved from a pure visualization tool to representing a primary source of analytic approaches toward in vivo disease characterization. Hybrid imaging is an integral part of this approach, as it provides complementary visual and quantitative information in the form of morphological and functional insights into the living body. As such, non-invasive imaging modalities no longer provide images only, but data, as stated recently by pioneers in the field. Today, such information, together with other, non-imaging medical data creates highly heterogeneous data sets that underpin the concept of medical big data. While the exponential growth of medical big data challenges their processing, they inherently contain information that benefits a patient-centric personalized healthcare. Novel machine learning approaches combined with high-performance distributed cloud computing technologies help explore medical big data. Such exploration and subsequent generation of knowledge require a profound understanding of the technical challenges. These challenges increase in complexity when employing hybrid, aka dual-or even multi-modality image data as input to big data repositories. This paper provides a general insight into medical big data analysis in light of the use of hybrid imaging information. First, hybrid imaging is introduced (see further contributions to this special Research Topic), also in the context of medical big data, then the technological background of machine learning as well as state-of-the-art distributed cloud computing technologies are presented, followed by the discussion of data preservation and data sharing trends. Joint data exploration endeavors in the context of in vivo radiomics and hybrid imaging will be presented. Standardization challenges of imaging protocol, delineation, feature engineering, and machine learning evaluation will be detailed. Last, the paper will provide an outlook into the future role of hybrid imaging in view of personalized medicine, whereby a focus will be given to the derivation of prediction models as part of clinical decision support systems, to which machine learning approaches and hybrid imaging can be anchored.

show abstract

“…2,26-30 A full description of the CCC can be found in the studies by Lin 26 and Balagurunathan et al 27 A strength of agreement classification defined by McBride was used to classify CCC results (Table 2). 31 The mean CCC for each feature subtype was calculated, and the median and range for each feature across noise levels were plotted.…”

Section: Statistical Analysis On Patient Datamentioning

confidence: 99%

Sensitivity of Image Features to Noise in Conventional and Respiratory-Gated PET/CT Images of Lung Cancer: Uncorrelated Noise Effects

Oliver

Budzevich

Hunt

et al. 2016

Technol Cancer Res Treat

View full text Add to dashboard Cite

The effect of noise on image features has yet to be studied in depth. Our objective was to explore how significantly image features are affected by the addition of uncorrelated noise to an image. The signal-to-noise ratio and noise power spectrum were calculated for a positron emission tomography/computed tomography scanner using a Ge-68 phantom. The conventional and respiratory-gated positron emission tomography/computed tomography images of 31 patients with lung cancer were retrospectively examined. Multiple sets of noise images were created for each original image by adding Gaussian noise of varying standard deviation equal to 2.5%, 4.0%, and 6.0% of the maximum intensity for positron emission tomography images and 10, 20, 50, 80, and 120 Hounsfield units for computed tomography images. Image features were extracted from all images, and percentage differences between the original image and the noise image feature values were calculated. These features were then categorized according to the noise sensitivity. The contour-dependent shape descriptors averaged below 4% difference in positron emission tomography and below 13% difference in computed tomography between noise and original images. Gray level size zone matrix features were the most sensitive to uncorrelated noise exhibiting average differences >200% for conventional and respiratorygated images in computed tomography and 90% in positron emission tomography. Image feature differences increased as the noise level increased for shape, intensity, and gray-level co-occurrence matrix features in positron emission tomography and for graylevel co-occurrence matrix and gray-level size zone matrix features in conventional computed tomography. Investigators should be aware of the noise effects on image features.

show abstract

Test–Retest Reproducibility Analysis of Lung CT Image Features

Cited by 210 publications

References 33 publications

Staging of Lung Cancer

Staging of Lung Cancer

Personalizing Medicine Through Hybrid Imaging and Medical Big Data Analysis

Sensitivity of Image Features to Noise in Conventional and Respiratory-Gated PET/CT Images of Lung Cancer: Uncorrelated Noise Effects

Contact Info

Product

Resources

About