The present invention relates to techniques for automated analysis of digital chest radiographs, and more specifically to a method for automated detection of lung regions in digital chest radiographs.
Identification of lung regions in chest radiographs is an important pre-processing step for most types of computer analysis of digital chest radiographs, such as interstitial disease, pneumothorax, cardiomegaly and pulmonary nodules. Recent literature has addressed this topic, and various image processing methods have been applied. These methods can be basically classified into two categories. One is feature-based pixel classification and the other is ruled-based reasoning. In pixel classification systems, each pixel in the image is represented by a set of features, such as density, histogram, entropy, and gradients, and is classified into a region type based on the output of Neural Networks or Markov Random Field Modeling. Prior work in this subject area includes the work of McNitt-Gray et al. Feature Selection classification problem of digital chest radiograph segmentation, IEEE Trans. Med. Imaging, 1995, 14, pp 537-547, who developed a pattern classification scheme consisting of stepwise discriminate analysis as a basis for feature selection which has then used to train and test classifiers, Tsuji et al., Automated Segmentation of anatomical region in chest radiographs using an adaptive-sized hybrid neural network, Med. Phys., 25 (6), June 1998, pp 998-1007, who used an adaptive-sized hybrid neural network to classify each pixel into two anatomic classes (lung and others) according to relative pixel address, density and histogram equalized entropy and Hassegawa et al., A Shift-Invariant Neural Network for the Lung Field Segmentation in Chest Radiography, Journal of VLSI Signal Processing, No. 18, 1998, pp 241-250, who employed a shift-invariant neural network to extract the lung regions. Vittitoe et al., Identification of lung regions in chest radiographs using Markov random field modeling, Med. Phys. 25, (6), 1998, pp 976-985, developed a pixel classifier for the identification of lung regions using Markov Random Field modeling. Lung segmentation by rule-based reasoning consists of a series of steps, each containing specific processing and, usually, certain adjustable parameters. For example, Armato et al., Automated Registration of ventilation/perfusion images with digital chest radiographs., Acad. Radiology, 1997, 4, 183-192, used a combination of a global and local gray-level thresholding to extract lung regions and then smoothed the lung contours by a rolling ball technique. Duryea et al., A fully automated algorithm for the segmentation of lung fields in digital chest radiographic images, Med. Phys., 1995, 22, 99 183-191, proposed a heuristic edge tracing approach with validation against hand-drawn lung contours. Pietka, Lung Segmentation in Digital Radiographs, Journal of Digital Imaging, vol. 7, No. 2, 1994, pp 79-84, delineated lung borders using a single threshold determined from the gray-level histogram of a selected region, then refined the lung edges by gradient analysis. Xu et al., Image Feature Analysis For Computer-Aid Diagnosis: Detection of Right and Left hemi diaphragm edges and Delineation of lung field in chest radiographs, Med. Phys., 23 (9), Sept. 1996, pp 1613-1624, determined the lung regions by detecting top lung edges and ribcage edges, then fitting the edges into smooth curves. Carrascal et al., Automatic Calculation of total lung capacity from automatically traced boundaries in postero-anterior and lateral digital chest radiographs, Med. Phys., 25 (7), July 1998, pp 1118-1131, detected the lung boundary segments in a set of automatic defined Regions of Interests (ROIs), then corrected and completed the boundary by means of interpolation and arc fitting.
Generally speaking, the methods described in the prior art are low-level processing, which operate directly on the raw image data; even through a few of them utilize embedded domain knowledge as heuristics within segmentation algorithms. These approaches pose problems when processing images of abnormal anatomy, or images with excessive noise and poor quality, because the abnormal anatomic structures or noise often confuse the segmentation routines. Thus, there exists a need for high-level analysis, incorporating both the anatomical knowledge and low-level image processing, in order to improve the performance of segmentation algorithms. To solve the problem, Brown et al., Knowledge-based method for segmentation and analysis of lung boundaries in chest x-ray images, Computerized medical Imaging and Graphics, 1998, 22, pp 463-477, presented a knowledge-based system which matches image edges to an anatomical model of the lung boundary using parametric features and reasoning mechanisms. Ginneken et al., Computer-Aided Diagnosis in Chest Radiography PhD thesis, Utrecht University, March 2001, used a hybrid system that combines the strength of a rule-based approach and pixel classification to detect lung regions. Although the latter methods demonstrate improved performance, to automatically and accurately detect lung regions is still a difficult problem. There are several factors that contribute to this difficulty including (1) a high degree of variation in chest image composition from person to person, (2) the variability in the habitus and level of inspiration of the lungs during the examination, and (3) the superimposed structures in the lung regions of chest radiographs, such as lung vasculature, ribs, and clavicles. The latter structures cause the lung boundaries to appear ambiguous, which greatly reduces the performance of low-level image processing.
To reliably segment lung regions, both low-level processing and high-level analysis must be employed, and low-level processing techniques should be constrained and directed by knowledge of the relevant local anatomy, which is supplied through high-level analysis. The present invention provides a solution to the problems of the prior art and employs a robust means to automatically segment lung regions in digital chest radiographs by using a knowledge-based model, which not only encapsulates the properties of anatomic structures, but also specifies an efficient way to detect them and evaluate their relationships.
According to the present invention, there is provided an automated method for detecting lung regions in chest radiographs.
According to a feature of the present invention, there is to provide an automated method and system for detecting and locating the chest body and the spine column in chest radiographs.
A further object of this invention is to improve the image display quality based on the anatomical structures in chest radiographs.
According to the present invention, these objects are achieved by providing a new method and system for automated analysis of chest radiographs. The method includes pre-processing chest radiographs, extracting the chest body midline and lung centerlines, locating the chest body model, the spine column model and the lung models in chest radiographs, and deforming the lung shape model to coverage to the true boundaries of the lung regions.
Pre-processing chest radiographs comprises analyzing the histogram of a chest radiograph, deriving two thresholds from the histogram, segmenting the chest radiograph by the two thresholds, estimating the two lung regions and the mediastinum region from the segmented image, and normalizing the radiograph based on the properties extracted from the estimated lung regions and mediastinum region.
Extracting the chest body midline and lung centerlines makes use of the 0th-order X direction derivative image and the estimated lung regions and mediastinum region to detect three feature lines, one corresponding to the chest body midline and the other two to the lung centerlines.
Locating the knowledge model starts from the chest body model, then the spine model and finally the lung models with the help of three feature lines.
Deforming the lung shape model includes determining a target point for each landmark, adjusting the pose and size of the shape model and finally deforming the shape model locally to best fit the target points.
The invention has the following advantages.
1. Chest radiographs are normalized based on the anatomic regions, which not only improves the display quality of radiographs, but also makes the system robust;
2. The algorithm incorporates both high-level analysis and low-level image processing, which enables the system to deal with radiographs with abnormal anatomy, noise and poor quality;
3. The shape-based deformable lung model is tolerant of shape and positional variances as well as image disturbances.
4 The region-growing scheme is adaptive.
5. The employed edge information combines difference order derivative and different direction edge information, which makes the boundary detection more accurate and reliable.
The present invention relates in general to the processing of chest radiographic images.
The digital radiographic image is processed according to the present invention by image processing system 1602. System 1602 is preferably a digital computer or digital microprocessor by can include hardware and firmware to carry out the various image processing operations.
The processed digital radiographic image is provided to image output 1604, such as a high resolution electronic display or a printer which produces a hard copy (film) of the processed radiographic image. The original as well as the processed image can be transmitted to a remote location, can be stored in a radiographic image storage system (PACS), and the like.
The present invention discloses a method for automatically segmenting lung regions in chest radiographic images, which is based on the combination of six processing steps as shown in
A knowledge model is used for lung segmentation, which encapsulates the following characteristics:
Because of a high degree of variation (1) in the chest among patients, (2) in the exposure conditions in the choice of image acquisition devices, and (3) in the preference of the radiologist, chest radiographs look quite different, which greatly affects the processing results. Thus, image normalization is employed to promote the robustness. In the present invention, all input images are normalized based on Regions of Interests (ROIs), instead of the image gray-level histogram as most image histograms contain the gray levels from foreground, background, and ROIs. Foreground is the area that is occluded by x-ray collimation during the exposure. Backgrounds are areas that have received direct x-ray exposure, and ROIs is taken to be the remainder of the image that normally contains the anatomical regions of interest for diagnosis. If image normalization is simply based on its histogram, the result is inevitably biased by the image foreground and background.
Referring now to
Referring to
Where h(i) is the histogram of the chest radiograph.
The next step is to detect the mediastinum region which is located between the two lung fields. Its extraction can be simply completed by detecting the region between the two lung regions, as shown in
Where I(x,y) is the grey-level of the original chest radiographic image at the pixel (x,y).
Only using the estimate of lung regions is not sufficient to locate the knowledge model in chest radiographs, since its information is not precise and reliable, especially in some abnormal images. But it does provide a good hint for detecting lung regions. Some experimental results show that using appropriate scales and a combination of direction and derivation on the radiograph can extract some features corresponding closely to anatomical structures or boundaries. For example, the chest body midline and lung centerlines can be easily found in the 0th-order X-direction derivative image, as shown in
Inα(x,y,σ)=Gnα(x,y,σ){circumflex over (x)}Inew(x,y) (3)
The normalized Gaussian in two-dimension is given by:
Where {circumflex over (x)} denotes convolution and Gnα is the nth-order derivative of the Gaussian kernel in the direction α. In the present invention α=0° corresponds to X direction, and 60 =90° corresponds to Y direction. The white and black pixels in the derivative images correspond the maximum and minimum in the direction α, respectively, which are obtained by comparing each pixel with its neighboring regions using the non-maximal suppression algorithm. With the help of the estimate of lung regions, the two lung centerlines can be detected by finding two start points, one on each black line, then tracing them in both directions, and finally stopping at the pixel whose gray-level is greater than the second threshold (th2). The chest body midline is found by the same technique in the mediastinum region.
Once the chest body midline and lung centerlines are detected. The chest body model can be located by aligning its centerline with the chest body midline, and its model size is derived from the distance between the two lung centerlines, then the spine model is placed in the middle of the chest body model according to their anatomic spatial relationship. The locating of lung models is complicated, since their size, position and orientation have to be firstly derived from the lung centerlines, then the lung shape models are adjusted by these parameters and finally the models are aligned along the lung centerlines.
The lung shape model used in the present invention is a 2D statistical shape model from H. Luo et al., Method for automatic construction of 2D statistical shape model for the lung regions, which consists of a mean shape vector (
To determine a proper target point for each landmark is critical to the success of lung segmentation. In the present invention, both region and edge information are employed for the detection. The region information is obtained from a small local search region around the landmark, and used to indicate the landmark location, such as inside or outside of the lung regions, or close to the boundaries. The edge information is extracted from different orders and direction derivative images for each landmark, which gives an accurate representation of the boundary properties of the lung regions.
Reference is now made to
The lung region threshold used here is adaptive and updated during each iteration of deformation. It is first initialized as th2, detected in the pre-processing. Then after an iteration of deformation, the lung region threshold is updated based on a weighted mean of the newly detected lung region. Eq. 5 gives the way to compute the weighted region mean. For those pixels less than th2 in the detected lung region, it is sure that they belong to the lung region, thus their weights w(x,y) are set higher to emphasize their contribution to the region properties.
In present invention, the gray level distribution of lung regions is modeled as a Guassian distribution over the region weighted mean Ireg with variance σreg, as illustrated in
threg=2*Ireg (6)
The selection of edge information is based on the position of a landmark and its contour shape.
In the second stage, a set of suitable target points (XT) are given, and the best fit pose parameters can be computed by minimizing the sum of squares of distances between the landmarks from the lung mean shape and their corresponding target points.
E=(XT−M(Sd,θd)
Where
θd is an appropriate rotation, Sd is a scale and td=(tdx, tdy) represents translation.
According to the statistical shape model, any shape vector X can be approximated using the mean shape
X=
Where Pt is a matrix of the most significant eigenvectors, and bt is a set of shape parameters, one for each eigenvector. Since the mean shape
dx=M−1(sd,θd)(XT+td)−
Based on Eq. 9
dx=Ptbt (11)
With the properties of eigenvector matrices, the best approximation parameters is calculated by
bt=PtTdx=PtT[M−1(Sd,θd)(XT+td)−
During the deformation of the statistical shape model, the shape parameters (components in the vector bt) have to be checked by pre-defined limits to avoid implausible shape. This may cause the deformed shape not match the target points precisely sometimes. However, such imprecision can be eventually minimized or disappear after enough iteration, and finally the lung shape models will converge to the true boundaries of lung regions, as shown in
The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention.
This is a continuation of U.S. Ser. No. 10/315,884 filed on Dec. 10, 2002 titled “METHOD FOR AUTOMATED ANALYSIS OF DIGITAL CHEST RADIOGRAPHS” by Luo et al., incorporated herein by reference.
Number | Date | Country | |
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Parent | 10315884 | Dec 2002 | US |
Child | 11565709 | Dec 2006 | US |