On the correlation between second order texture features and human observer detection performance in digital images.

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2020-08

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Abstract

Image texture, the relative spatial arrangement of intensity values in an image, encodes valuable information about the scene. As it stands, much of this potential information remains untapped. Understanding how to decipher textural details would afford another method of extracting knowledge of the physical world from images. In this work, we attempt to bridge the gap in research between quantitative texture analysis and the visual perception of textures. The impact of changes in image texture on human observer's ability to perform signal detection and localization tasks in complex digital images is not understood. We examine this critical question by studying task-based human observer performance in detecting and localizing signals in tomographic breast images. We have also investigated how these changes impact the formation of second-order image texture. We used digital breast tomosynthesis (DBT) an FDA approved tomographic X-ray breast imaging method as the modality of choice to show our preliminary results. Our human observer studies involve localization ROC (LROC) studies for low contrast mass detection in DBT. Simulated images are used as they offer the benefit of known ground truth. Our results prove that changes in system geometry or processing leads to changes in image texture magnitudes. We show that the variations in several well-known texture features estimated in digital images correlate with human observer detection-localization performance for signals embedded in them. This insight can allow efficient and practical techniques to identify the best imaging system design and algorithms or filtering tools by examining the changes in these texture features. This concept linking texture feature estimates and task based image quality assessment can be extended to several other imaging modalities and applications as well. It can also offer feedback in system and algorithm designs with a goal to improve perceptual benefits. Broader impact can be in wide array of areas including imaging system design, image processing, data science, machine learning, computer vision, perceptual and vision science. Our results also point to the caution that must be exercised in using these texture features as image-based radiomic features or as predictive markers for risk assessment as they are sensitive to system or image processing changes.

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10.1038/s41598-020-69816-z

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Nisbett, William H, Amar Kavuri and Mini Das (2020). On the correlation between second order texture features and human observer detection performance in digital images. Scientific reports, 10(1). p. 13510. 10.1038/s41598-020-69816-z Retrieved from https://hdl.handle.net/10161/28726.

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Scholars@Duke

Kavuri

Amareswararao Kavuri

Postdoctoral Associate

Research Interests: My research interests span several key areas within the realm of biomedical engineering and medical imaging. I specialize in Medical Imaging, Image Processing, Image Analysis, Image Perception, Visual Attention, and Virtual Imaging Trials. My work encompasses the development and application of innovative methodologies to enhance the accuracy, efficiency, and reliability of medical imaging systems.

Education:


Current Focus:
Currently, my research is centered on three primary objectives:

  1. Improving Virtual Imaging Trials Accuracy: I am actively involved in designing more accurate phantoms for virtual imaging trials. By developing realistic digital phantoms that closely mimic human anatomy and pathology, I aim to enhance the accuracy and reliability of virtual imaging trials, thereby contributing to advancements in medical imaging research.
  2. Enabling Easy Usage of Virtual Scanners: Another aspect of my current focus is to create user-friendly tools and interfaces for virtual scanner simulations. These tools facilitate the seamless and efficient use of virtual scanners, empowering researchers and clinicians to conduct virtual imaging trials with ease and precision.
  3. Evaluating and Improving Biomarker Accuracy: Additionally, I am engaged in evaluating and improving the accuracy of biomarkers in medical imaging. By leveraging advanced image processing and analysis techniques, I seek to enhance the reliability and predictive value of biomarkers, ultimately aiding in more accurate disease diagnosis and treatment assessment.


Overall, my work is driven by a passion for advancing the field of medical imaging and improving healthcare outcomes through innovative research and technology development.



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