Your search keyword '"particle detection"' showing total 5 results

1. An adaptive non-local means filter for denoising live-cell images and improving particle detection

Author

Yang, Lei, Parton, Richard, Ball, Graeme, Qiu, Zhen, Greenaway, Alan H., Davis, Ilan, and Lu, Weiping

Subjects

*FLUORESCENCE, *MOLECULAR dynamics, *SIGNAL-to-noise ratio, *IMAGE processing, *FEATURE extraction, *MICROTUBULES, *DROSOPHILA, *PROTEIN binding

Abstract

Abstract: Fluorescence imaging of dynamical processes in live cells often results in a low signal-to-noise ratio. We present a novel feature-preserving non-local means approach to denoise such images to improve feature recovery and particle detection. The commonly used non-local means filter is not optimal for noisy biological images containing small features of interest because image noise prevents accurate determination of the correct coefficients for averaging, leading to over-smoothing and other artifacts. Our adaptive method addresses this problem by constructing a particle feature probability image, which is based on Haar-like feature extraction. The particle probability image is then used to improve the estimation of the correct coefficients for averaging. We show that this filter achieves higher peak signal-to-noise ratio in denoised images and has a greater capability in identifying weak particles when applied to synthetic data. We have applied this approach to live-cell images resulting in enhanced detection of end-binding-protein 1 foci on dynamically extending microtubules in photo-sensitive Drosophila tissues. We show that our feature-preserving non-local means filter can reduce the threshold of imaging conditions required to obtain meaningful data. [ABSTRACT FROM AUTHOR]

Published

2010

2. SLEUTH—a fast computer program for automatically detecting particles in electron microscope images

Author

Short, Judith M.

Subjects

*COMPUTER software, *PARTICLES, *MICROGRAPHICS, *AUTOMATION

Abstract

A method has been developed to locate biological complexes in a digitized electron micrograph by matching small windows to a set of reference images using a series of simple criteria. From the reference images, the program calculates parameters such as the radius of gyration, the density sum and variance. It compares them with corresponding values from a moving square window of densities extracted from the micrograph and records the coordinates of successfully matched candidate squares. Since the same particle is detected in a series of overlapping windows, candidates found to be within close proximity are grouped and the best-fitting one is selected from each cluster. The user is required only to select a small stack of boxed reference images and provide a few parameters, such as the particle radius and the minimum acceptable distance between particle centres. Micrograph labels and other areas that do not contain appropriate specimens are automatically ignored in order to minimize false positives. The program has been tested successfully on a variety of different biological structures, from both negatively stained and ice-embedded specimens. [Copyright &y& Elsevier]

Published

2004

3. Detecting particles in cryo-EM micrographs using learned features

Author

Mallick, Satya P., Zhu, Yuanxin, and Kriegman, David

Subjects

*PARTICLES, *CRYOELECTRONICS, *ELECTRON microscopy, *MICROGRAPHICS

Abstract

A new learning-based approach is presented for particle detection in cryo-electron micrographs using the Adaboost learning algorithm. The approach builds directly on the successful detectors developed for the domain of face detection. It is a discriminative algorithm which learns important features of the particle’s appearance using a set of training examples of the particles and a set of images that do not contain particles. The algorithm is fast (10 s on a 1.3 GHz Pentium M processor), is generic, and is not limited to any particular shape or size of the particle to be detected. The method has been evaluated on a publicly available dataset of 82 cryo-EM images of keyhole lympet hemocyanin (KLH). From 998 automatically extracted particle images, the 3-D structure of KLH has been reconstructed at a resolution of 23.2 A˚ which is the same resolution as obtained using particles manually selected by a trained user. [Copyright &y& Elsevier]

Published

2004

4. Application of template matching technique to particle detection in electron micrographs

Author

Huang, Zhong and Penczek, Pawel A.

Subjects

*PARTICLES, *ELECTRON microscopy, *BAYESIAN analysis, *TRANSFER functions

Abstract

Template matching together with the comprehensive theory of image formation in electron microscope provides an optimal (in Bayesian sense) tool for solving one of the outstanding problems in single particle analysis, i.e., automatic selection of particle views from noisy micrograph fields. The method is based on the assumption that the reference three-dimensional structure is known and that the relevant parameters of the model of the image formation process can be estimated. In the first stage of the procedure, a set of possible particle views is generated using the available reference structure. The template images are constructed as linear combinations of available particle views using a clustering technique. Next, the micrograph noise characteristic is established using an automated contrast transfer function (CTF) estimation procedure. Finally, the CTF parameters calculated are used to construct a matched filter and correlation functions corresponding to the available template images are calculated. In order to alleviate the problem of the biased caused by varying image formation conditions, a decision making strategy based on the predicted distribution of correlation coefficients is proposed. It is demonstrated that due to the inclusion of CTF considerations, the template matching method performed very well in a broad range of microscopy conditions. [Copyright &y& Elsevier]

Published

2004

5. An adaptive non-local means filter for denoising live-cell images and improving particle detection

Author

Lei Yang, Graeme Ball, Zhen Qiu, Ilan Davis, Alan H. Greenaway, Weiping Lu, and Richard M. Parton

Subjects

Computer science, Noise reduction, Feature extraction, 02 engineering and technology, Microtubules, Synthetic data, Article, 03 medical and health sciences, Structural Biology, 0202 electrical engineering, electronic engineering, information engineering, Image noise, Animals, Computer vision, 030304 developmental biology, Particle detection, 0303 health sciences, Signal processing, Denoising, business.industry, Signal Processing, Computer-Assisted, Filter (signal processing), Non-local means, Non-local means filter, Microscopy, Fluorescence, Feature (computer vision), Computer Science::Computer Vision and Pattern Recognition, 020201 artificial intelligence & image processing, Drosophila, Artificial intelligence, business, Algorithms

Abstract

Fluorescence imaging of dynamical processes in live cells often results in a low signal-to-noise ratio. We present a novel feature-preserving non-local means approach to denoise such images to improve feature recovery and particle detection. The commonly used non-local means filter is not optimal for noisy biological images containing small features of interest because image noise prevents accurate determination of the correct coefficients for averaging, leading to over-smoothing and other artifacts. Our adaptive method addresses this problem by constructing a particle feature probability image, which is based on Haar-like feature extraction. The particle probability image is then used to improve the estimation of the correct coefficients for averaging. We show that this filter achieves higher peak signal-to-noise ratio in denoised images and has a greater capability in identifying weak particles when applied to synthetic data. We have applied this approach to live-cell images resulting in enhanced detection of end-binding-protein 1 foci on dynamically extending microtubules in photo-sensitive Drosophila tissues. We show that our feature-preserving non-local means filter can reduce the threshold of imaging conditions required to obtain meaningful data.

Published

2010