STEM Image Analysis Using LAT Image Processing

The role of medical image computing in oncology is growing stronger, not least due to the unprecedented advancement of computational AI techniques, providing a technological bridge between radiology and oncology, which could significantly accelerate the advancement of precision medicine throughout the cancer care continuum. Medical image processing has been an active field of research for more than three decades, focusing initially on traditional image analysis tasks such as registration segmentation, fusion, and contrast optimization. However, with the advancement of model-based medical image processing, the field of imaging biomarker discovery has focused on transforming functional imaging data into meaningful biomarkers that are able to provide insight into a tumor’s pathophysiology. More recently, the advancement of high-performance computing, in conjunction with the availability of large medical imaging datasets, has enabled the deployment of sophisticated machine learning techniques in the context of radiomics and deep learning modeling. This paper reviews and discusses the evolving role of image analysis and processing through the lens of the abovementioned developments, which hold promise for accelerating precision oncology, in the sense of improved diagnosis, prognosis, and treatment planning of cancer.

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Image processing techniques used for dental x-ray image analysis

2008 31st International Spring Seminar on Electronics Technology ◽

10.1109/isse.2008.5276424 ◽

2008 ◽

Cited By ~ 8

Author(s):

Stefan Oprea ◽

Costin Marinescu ◽

Ioan Lita ◽

Mariana Jurianu ◽

Daniel Alexandru Visan ◽

...

Keyword(s):

Image Processing ◽

Image Analysis ◽

X Ray ◽

Image Processing Techniques ◽

Processing Techniques

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A Survey on Solar Image Segmentation Techniques

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.945-949.1899 ◽

2014 ◽

Vol 945-949 ◽

pp. 1899-1902

Author(s):

Yuan Yuan Fan ◽

Wei Jiang Li ◽

Feng Wang

Keyword(s):

Image Processing ◽

Pattern Recognition ◽

Image Analysis ◽

Image Segmentation ◽

Image Retrieval ◽

Fundamental Issue ◽

Solar Image ◽

Segmentation Methods

Image segmentation is one of the basic problems of image processing, also is the first essential and fundamental issue in the solar image analysis and pattern recognition. This paper summarizes systematically on the image segmentation techniques in the solar image retrieval and the recent applications of image segmentation. Then the merits and demerits of each method are discussed in this paper, in this way we can combine some methods for image segmentation to reach the better effects in astronomy. Finally, according to the characteristics of the solar image itself, the more appropriate image segmentation methods are summed up, and some remarks on the prospects and development of image segmentation are presented.

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Validation of a new image analysis procedure for quantifying filamentous bacteria in activated sludge

Water Science & Technology ◽

10.2166/wst.2014.296 ◽

2014 ◽

Vol 70 (6) ◽

pp. 955-963 ◽

Cited By ~ 4

Author(s):

Ewa Liwarska-Bizukojc ◽

Marcin Bizukojc ◽

Olga Andrzejczak

Keyword(s):

Image Processing ◽

Image Analysis ◽

Activated Sludge ◽

Analysis Procedure ◽

Automated Image Analysis ◽

Filamentous Bacteria ◽

Image Processing And Analysis ◽

Manual Counting ◽

Analysis Application ◽

Activated Sludge Systems

Quantification of filamentous bacteria in activated sludge systems can be made by manual counting under a microscope or by the application of various automated image analysis procedures. The latter has been significantly developed in the last two decades. In this work a new method based upon automated image analysis techniques was elaborated and presented. It consisted of three stages: (a) Neisser staining, (b) grabbing of microscopic images, and (c) digital image processing and analysis. This automated image analysis procedure possessed the features of novelty. It simultaneously delivered data about aggregates and filaments in an individual calculation routine, which is seldom met in the procedures described in the literature so far. What is more important, the macroprogram performing image processing and calculation of morphological parameters was written in the same software which was used for grabbing of images. Previously published procedures required using two different types of software, one for image grabbing and another one for image processing and analysis. Application of this new procedure for the quantification of filamentous bacteria in the full-scale as well as laboratory activated sludge systems proved that it was simple, fast and delivered reliable results.

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Integrating Image Computation in Undergraduate Level Data-Structure Education

International Journal of Pattern Recognition and Artificial Intelligence ◽

10.1142/s0218001498000609 ◽

1998 ◽

Vol 12 (08) ◽

pp. 1071-1080 ◽

Cited By ~ 9

Author(s):

Sudeep Sarkar ◽

Dmitry Goldgof

Keyword(s):

Image Processing ◽

Image Analysis ◽

Data Structure ◽

Data Structures ◽

Science Curriculum ◽

Early Stage ◽

Real Life ◽

South Florida ◽

The University ◽

Structure Education

There is a growing need for expertise both in image analysis and in software engineering. To date, these two areas have been taught separately in an undergraduate computer and information science curriculum. However, we have found that introduction to image analysis can be easily integrated in data-structure courses without detracting from the original goal of teaching data structures. Some of the image processing tasks offer a natural way to introduce basic data structures such as arrays, queues, stacks, trees and hash tables. Not only does this integrated strategy expose the students to image related manipulations at an early stage of the curriculum but it also imparts cohesiveness to the data-structure assignments and brings them closer to real life. In this paper we present a set of programming assignments that integrates undergraduate data-structure education with image processing tasks. These assignments can be incorporated in existing data-structure courses with low time and software overheads. We have used these assignment sets thrice: once in a 10-week duration data-structure course at the University of California, Santa Barbara and the other two times in 15-week duration courses at the University of South Florida, Tampa.

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An Overview of the Topological Gradient Approach in Image Processing: Advantages and Inconveniences

Journal of Applied Mathematics ◽

10.1155/2010/761783 ◽

2010 ◽

Vol 2010 ◽

pp. 1-19 ◽

Cited By ~ 1

Author(s):

Lamia Jaafar Belaid

Keyword(s):

Image Processing ◽

Image Analysis ◽

Numerical Experiments ◽

Grey Level ◽

Major Drawback ◽

Topological Gradient ◽

Boundary Measurements ◽

Topological Asymptotic Expansion ◽

Gradient Approach ◽

Segmentation Problem

Image analysis by topological gradient approach is a technique based upon the historic application of the topological asymptotic expansion to crack localization problem from boundary measurements. This paper aims at reviewing this methodology through various applications in image processing; in particular image restoration with edge detection, classification and segmentation problems for both grey level and color images is presented in this work. The numerical experiments show the efficiency of the topological gradient approach for modelling and solving different image analysis problems. However, the topological gradient approach presents a major drawback: the identified edges are not connected and then the results obtained particularly for the segmentation problem can be degraded. To overcome this inconvenience, we propose an alternative solution by combining the topological gradient approach with the watershed technique. The numerical results obtained using the coupled method are very interesting.

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PlantCV v2: Image analysis software for high-throughput plant phenotyping

PeerJ ◽

10.7717/peerj.4088 ◽

2017 ◽

Vol 5 ◽

pp. e4088 ◽

Cited By ~ 63

Author(s):

Malia A. Gehan ◽

Noah Fahlgren ◽

Arash Abbasi ◽

Jeffrey C. Berry ◽

Steven T. Callen ◽

...

Keyword(s):

Image Processing ◽

Computer Vision ◽

Image Analysis ◽

Image Data ◽

Plant Phenotyping ◽

Analysis Software ◽

Computational Tools ◽

Landmark Identification ◽

Plant Image ◽

Leaf Segmentation

Systems for collecting image data in conjunction with computer vision techniques are a powerful tool for increasing the temporal resolution at which plant phenotypes can be measured non-destructively. Computational tools that are flexible and extendable are needed to address the diversity of plant phenotyping problems. We previously described the Plant Computer Vision (PlantCV) software package, which is an image processing toolkit for plant phenotyping analysis. The goal of the PlantCV project is to develop a set of modular, reusable, and repurposable tools for plant image analysis that are open-source and community-developed. Here we present the details and rationale for major developments in the second major release of PlantCV. In addition to overall improvements in the organization of the PlantCV project, new functionality includes a set of new image processing and normalization tools, support for analyzing images that include multiple plants, leaf segmentation, landmark identification tools for morphometrics, and modules for machine learning.

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IDENTIFICATION OF MEGALOBLASTIC ANEMIA CELLS THROUGH THE USE OF IMAGE PROCESSING TECHNIQUES

International Journal of Clinical and Biomedical Research ◽

10.31878/ijcbr.2018.43.01 ◽

2018 ◽

Vol 4 (3) ◽

pp. 1-5 ◽

Cited By ~ 1

Author(s):

Asaad Babker ◽

Vyacheslav Lyashenko

Keyword(s):

Image Processing ◽

Image Analysis ◽

Blood Smear ◽

Color Image ◽

Megaloblastic Anemia ◽

Cell Structure ◽

Color Space ◽

Image Processing Techniques ◽

Processing Techniques ◽

Blood Smear Image

Objective: Our aim is to show the possibility of using different image processing techniques for blood smear analysis. Also our aim is to determine the sequence of image processing techniques to identify megaloblastic anemia cells. Methods: We consider blood smear image. We use a variety of image processing techniques to identify megaloblastic anemia cells. Among these methods, we distinguish the modification of the color space and the use of wavelets. Results: We developed a sequence of image processing techniques for blood smear image analysis and megaloblastic anemia cells identification. As a characteristic feature for megaloblastic anemia cells identification, we consider neutrophil image structure. We also use the morphological methods of image analysis in order to reveal the nuclear lobes in neutrophil structure. Conclusion: We can identify the megaloblastic anemia cells. To do this, we use the following sequence of blood smear image processing: color image modification, change of the image contrast, use of wavelets and morphological analysis of the cell structure.

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A Critical Overview of Image Segmentation Techniques Based on Transition Region

Encyclopedia of Information Science and Technology, Fourth Edition ◽

10.4018/978-1-5225-2255-3.ch112 ◽

2018 ◽

pp. 1308-1318

Author(s):

Yu-Jin Zhang

Keyword(s):

Image Processing ◽

Image Analysis ◽

Image Segmentation ◽

Transition Region ◽

Google Scholar ◽

Research Directions ◽

Distinctive Type ◽

Critical Overview

Image segmentation is the key step from image processing to image analysis, and is an important technique of image engineering. Image segmentation based on transition region is a special or distinctive type of techniques that are different from traditional boundary-based or region-based techniques. Since the first technique using transition region proposed, there are many subsequent related researches and applications, and a series of papers in the literature citing are published worldwide. Using Google Scholar, a number of papers citing the original papers are searched, a study on the statistics of these papers is conducted. These papers are sorted first according to the publishing year, and then grouped according to their purposes and contents (with techniques used). Some questionable issues in these papers are pointed out and critically discussed, and several further research directions are indicated and analyzed.

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Image Processing for Solar Cell Analysis, Diagnostics and Quality Assurance Inspection

Handbook of Research on Solar Energy Systems and Technologies ◽

10.4018/978-1-4666-1996-8.ch014 ◽

2013 ◽

pp. 338-375

Author(s):

Michael G. Mauk

Keyword(s):

Image Processing ◽

Image Analysis ◽

Quality Assurance ◽

Solar Cell ◽

Process Development ◽

Low Cost ◽

Scale Up ◽

Image Capturing ◽

Infrared Cameras ◽

Primary Focus

Image capturing, processing, and analysis have numerous uses in solar cell research, device and process development and characterization, process control, and quality assurance and inspection. Solar cell image processing is expanding due to the increasing performance (resolution, sensitivity, spectral range) and low-cost of commercial CCD and infrared cameras. Methods and applications are discussed, with primary focus on monocrystalline and polycrystalline silicon solar cells using visible and infrared (thermography) wavelengths. The most prominent applications relate to mapping of minority carrier lifetime, shunts, and defects in solar cell wafers, in various stages of the manufacturing process. Other applications include measurements of surface texture and reflectivity, surface cleanliness, integrity of metallization lines, uniformity of coatings, and crystallographic texture and grain size. Image processing offers the capability to assess large-areas (> 100 cm2) with a non-contact, fast (~ 1 second), and modest cost. The challenge is to quantify and interpret the image data in order to better inform device design, process engineering, and quality control. Many promising solar cell technologies fail in the transition from laboratory to factory due to issues related to scale-up in area and manufacturing throughput. Image analysis provides an effective method to assess areal uniformity, device-to-device reproducibility, and defect densities. More integration of image analysis from research devices to field testing of modules will continue as the photovoltaics industry matures.

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