CA2201057C - A method of processing a sectional image of a sample bone including a cortical bone portion and a cancellous bone portion - Google Patents
A method of processing a sectional image of a sample bone including a cortical bone portion and a cancellous bone portion Download PDFInfo
- Publication number
- CA2201057C CA2201057C CA002201057A CA2201057A CA2201057C CA 2201057 C CA2201057 C CA 2201057C CA 002201057 A CA002201057 A CA 002201057A CA 2201057 A CA2201057 A CA 2201057A CA 2201057 C CA2201057 C CA 2201057C
- Authority
- CA
- Canada
- Prior art keywords
- image
- bone
- sectional
- pixels
- processing
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
Classifications
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06T—IMAGE DATA PROCESSING OR GENERATION, IN GENERAL
- G06T7/00—Image analysis
- G06T7/0002—Inspection of images, e.g. flaw detection
- G06T7/0012—Biomedical image inspection
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06T—IMAGE DATA PROCESSING OR GENERATION, IN GENERAL
- G06T7/00—Image analysis
- G06T7/10—Segmentation; Edge detection
- G06T7/11—Region-based segmentation
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06T—IMAGE DATA PROCESSING OR GENERATION, IN GENERAL
- G06T7/00—Image analysis
- G06T7/60—Analysis of geometric attributes
- G06T7/62—Analysis of geometric attributes of area, perimeter, diameter or volume
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06T—IMAGE DATA PROCESSING OR GENERATION, IN GENERAL
- G06T7/00—Image analysis
- G06T7/60—Analysis of geometric attributes
- G06T7/66—Analysis of geometric attributes of image moments or centre of gravity
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06T—IMAGE DATA PROCESSING OR GENERATION, IN GENERAL
- G06T2207/00—Indexing scheme for image analysis or image enhancement
- G06T2207/10—Image acquisition modality
- G06T2207/10072—Tomographic images
- G06T2207/10081—Computed x-ray tomography [CT]
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06T—IMAGE DATA PROCESSING OR GENERATION, IN GENERAL
- G06T2207/00—Indexing scheme for image analysis or image enhancement
- G06T2207/30—Subject of image; Context of image processing
- G06T2207/30004—Biomedical image processing
- G06T2207/30008—Bone
- G06T2207/30012—Spine; Backbone
Abstract
A binary image of a bone section is provided to be processed. A region of interest is provided on the binary image to produce a ROI image by extracting pixels corresponding to the bone portion from the binary image within the region of interest, onto which ROI image morphometry is carried out. A series of pixels which are on the center line extending along the cortical bone portion in the ROI image. A hemi-cortical bone image is produced by using the determined center line. The hemi-cortical bone image has a wall thickness substantially half of the real wall thickness of the cortical bone portion. A template image for the cortical bone portion is produced by executing expanding operations on the hemi-cortical bone image a predetermined number of times.
Description
22 0 ~ ~5 7 ~ TN-D254 A METHOD OF PROCESSING A SECTIONAL IMAGE OF
A SAMPLE BQNE INCLUDING A CQRTICAL BONE PORTION AND
A CANCELLOUS BONE PORTION
BACKGROUND OF THE INVENTION
1. Field of the Invention The invention relates to a bone morphometric method, in particular, to a method of processing a sectional image of a sample bone which includes a cortical bone portion and a cancellous bone portion.
A SAMPLE BQNE INCLUDING A CQRTICAL BONE PORTION AND
A CANCELLOUS BONE PORTION
BACKGROUND OF THE INVENTION
1. Field of the Invention The invention relates to a bone morphometric method, in particular, to a method of processing a sectional image of a sample bone which includes a cortical bone portion and a cancellous bone portion.
2. Description of the Related Art The morphologies of human bones are measured to evaluate the strength of bones, to diagnose and determine the degree of progress of bone diseases such as osteoporosis and osteomalacia, or to confirm a therapeutic effect.
As an example of a method for diagnosing the reduction of bone strength due to bone disease, the DEXA
(Dual Energy X-ray Absorptiometry) method and the MD
(Micro Densitometry) method are known in the art. The DEXA and MD methods measure the amount or the dencity of bone mineral to diagnose the reduction of bone strength based on an assumption that there is a correlation between the amount or the dencity of bone mineral and the bone strength. However, in fact, the amount or the dencity of bone mineral does not precisely present the bone strength since bone structure significantly affects the bone strength. Thus, in the recent years, an attempt has been developed to evaluate the bone strength based on a postulate that bone strength depends significantly on the bone structure as well as bone mineral.
As a bone structural analysis, sectional bone structural analysis is known in the art. In the sectional bone structural analysis, a sectional image of a bone is provided by a micrograph or a X-ray computed tomography of a sample bone, and is used for measuring ~ - 2 -various parameters, such as, the sectional area and the perimeter, for evaluating structural anisotropy in the bone portion (refer to ~Journal of Japanese Society of Bone Morphometry" Vol. 4, No. l Pages 83 - 89, 1994), and for the Node-strut method (refer to "Journal of Microscopy~ Vol. 142, Pt3, Pages 341 - 349, 1986).
Figure 1 is a schematic illustration of a vertebral body constituting a human spine. In general, a static compressive force substantially acts on end faces of the vertebral body within areas 2 (only one in the top end face is shown in Figure 1) as shown by arrows 1.
Therefore, during a bone morphometry, a subject region for analysis is defined on a sectional image of a sample bone, and'~-within the subject region for analysis, various analyses, such as measurements of total area in the sectional bone image, mean wall thickness of the cortical bone and the cancellous bone portions, are carried out.
In particular, the bone portion within the subject region is defined as a region of interest (ROI) so that various structural parameters are measured relative to the ROI.
With reference to Figures 2-4, a sectional binary image of a vertebral body of a rat (Figure 2), a micrograph of a vertebral body of a human (Figure 3), and a sectional binary image of a femur of a rat (Figure 4) are shown, respectively. In Figures 2 and 3, enclosed by subject regions 3 and 4 for analysis, are the portions on which a static compressive force primarily acts. In Figure 4, all of the sectional image is enclosed by a rectangle 5 as a subject region for analysis. As shown in Figures 2-4, the subject region for analysis are defined by configurations which have various shapes, sizes and orientations, for example, the rectangles 5 and 6, triangles 7 and 8, a sector 3, a circle and a configuration 4 combined thereby.
In the prior art, a subject region for analysis is manually provided on a sectional image of a sample bone so that a human error is introduced into the size, ~ 22 0 1 05 ~
shape, orientation, and position of the subject region.
The human errors reduce the credibility and repeatability of the sectional bone structural analysis carried out based on such a manually provided subject region.
On the other hand, the bone structure includes, in general, surface and internal structures. The internal structure further includes cancellous and cortical bone portions which have different functions.
For example, when a person falls so that a load is applied to a bone, the cancellous bone portion functions to bear the deformation while the cortical bone portion functions to absorb the impact. Therefore, the cancellous and cortical bone portions must be considered separately to evaluate the~internal bone structure.
There are, some apparatuses, for evaluating internal bone structure, which can separate the cancellous and cortical bone portions from each other to measure and evaluate the respective portions independently.
Such an apparatuses binarizes a raw sectional bone image, which is produced by a micrograph or X-ray computed tomograph of a sample bone to provide an original binary image for processing to separate the sectional bone image into cancellous and cortical bone portions. Then, a filling hole operation is carried out on the original binary image within the peripheral of the bone sectional image to provide a solid image. The solid image is contracted until its area becomes half.
According to this prior art method, a cancellous bone portion is provided by extracting the pixels which are common to the original binary image and the contracted solid image (referred to AND operation between the original binary image and the contracted solid image). A
cortical bone portion is provided by extracting the pixels which are not common to the original binary image and the contracted solid image (referred to NAND
operation of the original binary image and the contracted solid image).
.
~ 220~0~7 The above-mentioned prior art method defines the cancellous and cortical bone portions irrespective of the actual thickness of the cortical bone so that the structural evaluation based on the cancellous and cortical bone images thus provided cannot reflect the real bone strength.
SUMMARY OF THE INVENTION
The invention is directed to solve the problems in the prior art, and to provide an improved method of processing a sectional bone image for using in a morphometry of a bone which includes a cortical bone portion and a cancellous bone portion. The invention provides a method of processing a sectional bone image of a sample-~one which method can eliminate a human error, ~5 as produced in the prior art, by providing a subject region on a binary image digitized from the sectional bone image automatically. Further, the invention provides a fine separation of the cortical bone portion and the cancellous bone portion so that the morphometry of the sample bone, in particular, the cancellous bone portion can be carried out with high precision and repeatability.
According to the invention, first, a binary image of a bone section is provided to be processed. A subject region is provided on the binary image to producing a ROI
image by extracting pixels corresponding to the bone portion from the binary image within the subject region, onto which ROI image the morphometry is carried out. A
series of pixels which are on the center line extending along the cortical bone portion in the ROI image is determined. A hemi-cortical bone image is produced by using the determined center line. The hemi-cortical bone image has a wall thickness substantially half of the real wall thickness of the cortical bone portion.
A template image for the cortical bone portion is produced by executing expanding operations on the hemi-cortical bone image with a predetermined number of ~ ~20105Z
times of operation. The template image for the cortical bone portion, produced by expanding the hemi-cortical bone image by a number of times which is advantageously selected, defines precisely a region within which the cortical bone portion extends since the hemi-cortical bone image has a wall thickness substantially half of the real wall thickness of the cortical bone portion.
The number of times for carrying out the expansion is preferably defined by INT(MWT x ~ + 1).
where INT(x): a function removing fractional portion from x ~: a predetermined constant value Prefërably, ~ = 2.0 i-s selected. Alternatively, the number of times for carrying out the expansion may be defined by INT(MWT x ~ + 1.5).
According to another feature of the invention, extracting the pixels common to the ROI image and the template image provides an image substantially corresponding to the cortical bone portion, and eliminating the image corresponding to the cortical bone image from the ROI image provides an image corresponding to the cancellous bone portion. It will be understood that eliminating the pixels which are common to the ROI
image and the template image from the ROI image can also provide an image corresponding to the cancellous bone portion.
According to another feature of the invention, a tensor analysis of the image corresponding to the cancellous bone determines the structural anisotropy in the cancellous bone.
According to another feature of the invention, when the sectional binary image is of a vertebral body which includes a cortical bone portion and a cancellous bone portion, the region of interest is provided by providing a subject region on the binary image as follows. First, the axis of inertia of the binary image of a vertebral ~ 2201057 body, and pixels corresponding to the vertebral canal within the binary image of a vertebral body are determined. The smallest rectangle enclosing the pixels of the vertebral canal is provided and a pair of fillet coordinates which are at the corners on one of the diagonals of the smallest rectangle enclosing the vertebral canal are determined. A subject region on the binary image is provided based on a representative length, which is defined by determining the distances between the axis of inertia and the fillet coordinates as the representative length, to extract pixels corresponding to the bone portion within the subject region, whereby the region of interest is defined on the binary imiage by the extracted pixels.
Then, the hemi-cortical bone image is provided as follows. An operation region to enclose the ROI image is provided so that the operation region including the largest and second largest background portion at either side of the ROI image bounds the center line pixels. The largest and second largest backgrounds within the operation region are determined, preferably, by a labeling operation to label holes which include pixels with zero (0) intensity. Pixels are determined as first pixels which are common with the largest hole image and the ROI image to provide a first hemi-cortical image, and as second pixels which are common wlth the second largest hole image and the ROI image to provide a second hemi-cortical image. Combining the first and second hemi-cortical images provides the hemi-cortical image.
DESCRIPTION OF THE DRAWINGS
These and other objects and advantages and further description will now be discussed in connection with the drawings in which:
Figure 1 is a schematic illustration of a vertebral body constituting a human spine.
Figure 2 is a sectional binary image of a vertebral body of a rat.
~ 22 0 1 05 7 Figure 3 is a micrograph of a vertebral body of a human.
Figure 4 is a sectional binary image of a femur of a rat.
Figure 5 is a schematic illustration of an apparatus for micro-focus X-ray computed tomography.
Figure 6 is a schematic illustration of an example of an image processing system to which the inventive method can be applied.
Figure 7A is a flow chart for a method of providing a subject region for analysis on a sectional binary image of a femur of a rat, and of separating a cortical bone portion and a cancellous bone portion from each other according-~to the preferred embodiment of the invention.
Figure 7B is a flow chart for a method of providing a subject region for analysis on a sectional binary image of a femur of a rat, and of separating a cortical bone portion and a cancellous bone portion from each other according to the preferred embodiment of the invention.
Figure 8A is a schematic illustration for explaining the method according to the flow chart of Figures 7A and 7B, and in particular is a schematic illustration of a thinned image of the sectional binary image of a femur of a rat.
Figure 8B is a schematic illustration for explaining the method according to the flow chart of Figures 7A and 7B, and in particular is a schematic illustration of a solid image produced by filling the holes within the thinned image of Figure 8A.
Figure 8C is a schematic illustration for explaining the method according to the flow chart of Figures 7A and 7B, and in particular is a schematic illustration of a hemi-cortical bone image.
Figure 8D is a schematic illustration for explaining the method according to the flow chart of Figures 7A and 7B, and in particular is a schematic illustration of a template image for the cortical bone portion.
~ ~2 0 ~ 05 7 Figure 8E is a schematic illustration for explaining the method according to the flow chart of Figures 7A and 7B, and in particular is a schematic illustration of an image corresponding to the cortical bone portion.
Figure 8F is a schematic illustration for explaining the method according to the flow chart of Figures 7A and 7B, and in particular is a schematic illustration of an image corresponding to the cancellous bone portion.
Figure 9A is a flow chart for a method of providing a subject region for analysis in a sectional image of a vertebral body according to the embodiment of the invention.
Figure 9B is a flow chart for a method of providing a subject'-~region for analysis in a sectional image of a vertebral body according to the embodiment of the invention.
Figure 9C is a flow chart for a method of providing a subject region for analysis in a sectional image of a vertebral body according to the embodiment of the invention.
Figure 9D is a flow chart for a method of providing a subject region for analysis in a sectional image of a vertebral body according to the embodiment of the invention.
Figure 10 is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular is a schematic illustration of the coordinates and a sectional binary image of a vertebral body.
Figure 11 is a schematic illustration for explaining the method according to the flow chart of Figures 9A
- 9D, and in particular is a schematic illustration of the ROI image extracted from the sectional binary image of Figure 10.
Figure 12A is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular is a schematic 220 ~05 7 illustration of the thinned image.
Figure 12B is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular is a schematic illustration of providing an operation area on the thinned image of Figure 12A.
Figuré 12C is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular is a schematic illustration for explaining the find hole process executed within the operation area of Figure 12B.
Figure 12D is a schematic illustration for explaining the method according to the flow chart of Figures 9A- - 9D, and in particular is a schematic illustration of the hemi-cortical bone image.
Figure 12E is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular ls a schematic illustration of the template image for the cortical bone portion.
Figure 12F is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular is a schematic illustration of an image corresponding to the cortical bone portion.
Figure 12G is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular is a schematic illustration of an image corresponding to the cancellous bone portion.
Figure 13 is a schematic illustration for explaining a various measurements and analyses which can be carried on the thinned image obtained by thinning operation executed on the ROI image provide by the invention, and in particular, measurement of numbers of the nodes, the struts and the terminuses, and measurement of the length of the struts of the bone portion are illustrated.
~ 2 2 0 1 0 5 ~
Figure 14 is a schematic illustration of a measurement of the length of an intercept between a line and the bone portion which can be carried on the ROI
image provide by the invention.
Figure 15 is a schematic illustration for explaining a method of tensor analysis which is carried out to determine the structural anisotropy of the cancellous bone portion, and in particular, a schematic enlarged illustration of a thinned image produced by a thinning operation executed on the binary image corresponding to the cancellous bone portion provided by the invention, in which a pixel of interest is indicated by "Piorl' f and the adjacent pixels surrounding the pixel of interest Pior are referred to Pi, i = 0 to 7.
Figure 16 is a flow chart for determining the structural anisotropy of the cancellous bone portion by a tensor analysis according to the invention.
Figure 17 is an illustration of a simple example of a binary image for explaining the tensor analysis according to the invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
A method of processing a sectional image of a sample bone according to an embodiment of the invention will be described. A sectional image o~ a sample bone is provided to be input into an image processing system according to the invention. In order to analyze the bone structure with a high precision, an input raw image has a fine resolution, for example, lower than 20 ~m per pixel, preferably lower than 10 ~m per pixel. Tn the embodiment of the invention, such a sectional image is obtained by a micro-focus X-ray computed tomography although another method, such as a micrograph of a slice of a sample bone can be utilized.
With reference to Figure 5, micro-focus X-ray computed tomography will be described. An X-ray generator 14 includes a X-ray tube 14a o~ which the size ~ Z~01057 of the focus area is approximately 8 ~m and a rotating anode 14b. An X-ray sensor 16 and a slit 20 are provided apart from the X-ray generator 14 so that the slit 20 is positioned between the X-ray generator 14 and the X-ray sensor 16. An image reconstruction device 18 is electrically connected to the X-ray sensor 16 for receiving a signal corresponding to the intensity of the X-ray which reaches to the sensor 16. A sample bone 10 is disposed on a turntable 12 which is provided between the X-ray generator 14 and the slit 20.
X-rays are produced when electron hits the rotating anode 14b, so that the accelerated X-ray is directed to the sample bone 10. The propagated X-ray is attenuated through the sample bone 10-and reach the X-ray sensor 16 through the slit 20 so that X-rays which have the desired slice width are extracted from the propagated X-rays.
The X-ray sensor 16 sends a signal to the image reconstruction device 18 corresponding to the intensity of the X-rays. The image reconstruction device 18 stores an information corresponding to the signal. Then, the turntable 12 rotates through a predetermined angle to measure the sample bone 10 at the next rotational angle.
The above process is repeated until the measurement is carried out along the full arc of the sample bone 10.
Thereafter, the image reconstruction device 18 reconstructs a sectional image of the sample bone 10 based on the memorized information. Changing the level of the turntable 12 provides another sectional image of the sample bone 10 at a different height.
The sectional image thus obtained may consist of 512 pixels x 480 pixels with each pixel sized 15 ~m x 15 ~m, and with CT value being expressed by a gradation of 2l6.
Further the CT value of the respective pixels is converted into a gradation of 2 by the following equation (1) when the image is input into the image processing system of the invention.
~ 22 0 105 7 TL = INT(0.5 + ((CT value of the respective pixels) - (CT~in))/(CT~ax) - (CTmin)) x 255) ..- (1) where TL : converted CT value CTmaX : the maximum CT value (e.g. 2000) CTmin : the minimum CT value (e.g. 500) INT(x): a function removing fractional portion from x The image thus obtained is processed by the image processing system of the invention as described below.
With reference to Figure 6, an image processing system according to the embodiment of the invention will be described. In Figure 6, the image processing system 30 includes a computer 32 provided with a microprocessor (not shown) and memory devices (not shown) as known in the art. The image processing system 30 further includes a first or main display unit 34, such as a CRT display, for indicating text information, a second or additional display unit 36, such as a CRT display, for indicating the processed image, an output unit 38 such as a printer, and a key board 40. The system can include an additional memory device 42 such as an external hard drive unit or an magneto-optical disc drive. Instead of the first and second displays 34 and 36, a display can be provided fo~ indicating the text information and the processed image. The system may further include a pointing device 44, such as a mouse, a track ball, a touch panel or a light pen, for inputting a reference point necessary for the bone morphometry in the displayed image.
With reference to Figures 7 and 8, a method of providing a subject region for analysis on a sectional binary image of a sample bone, in particular, a femur of a rat, and of separating cortical bone portion and cancellous bone portion from each other according to the ~ ~20 ~0~ 7 preferred embodiment of the invention will be described.
In step S10, a sectional image of a femur of a rat which is obtained by X-ray computed tomography is input into the image processing system as a raw image. In step S12, the input raw image is binarized or digitized to provide a binary image of a bone section. In this embodiment, the discriminant analysis method is used to provide the binary image as describe below.
According to the discriminant analysis method, the pixels in an image are classified into two classes by a threshold value so that degrees of deviation of the intensity of the pixels in the respective class are ~inimized and the degree of deviation between the two classes is~ maximized. The~degree of deviation in classes is defined by the following equation.
~w = ~0 ~o + ~1 ~1 (2) where : number of pixels in class 0 ~O: degree of deviation of pixel in class 0 ~1: number of pixels in class 1 ~1: degree of deviation of pixel in class 1 On the other hand, the degree of deviation between the two classes is defined by the following equation.
~B2 = ~1 ~z (Mo - Ml)Z ~-- (3) where Mo mean intensity of pixels in class 0 Ml: mean intensity of pixels in class 1 The threshold value is determined to minimize the ratio of (~W2/~BZ). According to the discriminant analysis method, the pixels are thus classified into two classes, that is one is a class of "1" which means the bone portion, and the other is a class "0" which means the background or a hole.
The sectional image is binarized as described above to provide a binary image. In the case of the sectional image of the femur, a subject region for analysis is ~ 220~0~ 7 provided on the binary image to enclose the whole of the bone portion to be defined as region of interest (ROI).
Then, the following process is carried out on the ROI
image.
In general, a sectional image of a bone obtained by computed tomography may include openings in the cortical bone portion due to the blood vessels extending into the internal tissue of the bone. A binary image based on such a sectional image also includes openings in the cortical bone portion. Therefore, such a binary image must be processed to close the possible openings in the cortical bone portion.
In step S14, n times of expanding operations are carried o'ut on the ROI image, and in step S16, (n+l) times of contracting operations are carried out on the expanded image. In this embodiment, n = 12 is advantageously selected in consideration of the general size of the openings in the bone portion. In step S18, a filling hole operation is carried out on the contracted image to provide a first solid image. In step S20, boundary pixels of the first solid image which bounds the background pixels are determined and extracted from the first solid image. In step S22, the pixels which belongs to the boundary pixels or the ROI image are extracted, which is referred to as an OR operation between the boundary pixels and the ROI image. This results in a subject binary image, in which openings in the cortical bone portion are closed by the boundary pixels.
In step S24, a thinning operation is carried out on the subject binary image to obtain a thinned image as shown in Figure 8A. The thinned image includes a series of pixels which are substantially along the center line of the cortical bone portion. In step S26, a filling hole operation is carried out on the thinned image to obtain a second solid image. In step S28, one contracting operation is carried out on the second solid image, and in step S30, one expanding operation is , ~ 22 a 1 ~ 5 7 carried out on the contracted second solid image to eliminate noise pixels from the second solid image, which is referred to as a subject solid image.
In step 32, a NAND operation is carried out to extract pixels which are not common to the subject solid image and the subject binary image so that an image (in Figure 8C) which has a wall thickness substantially half of the real cortical bone portion is provided by the extracted common pixels. The image composed of the extracted pixels is referred to a hemi-cortical bone image in this specification.
Based on the hemi-cortical bone image, in step S34, the mean wall thickness (MWT) is calculated by the followingi~~equation.
MWT = 2 . 0 X A~I/PHI
where A~I: area of the hemi-cortical image PHI: perimeter of the hemi-cortical image In step S36, expanding operations are carried out by 20 a predetermined number of times on the hemi-cortical image to provide a template image for the cortical bone portion as shown in Figure 8D. Experiments show that the number of times for carrying out the expansion is preferably defined by INT(MWT x ~ + 1).
2 5 where INT(x): a function removing fractional portion from x ~ : a predetermined constant value Preferably, ~ = 2.0 is selected. Alternatively, the number of times for carrying out the expansion may be defined by INT(MWT x ~ + 1.5). The cortical bone includes recesses and protrusions along its peripheral surface. When the wall thickness varies significantly along its periphery, or even a small hole presents in the cortical hone, if ~ = l.O, then the innermost portion of the cortical bone is often recognized as a part of the 2~n105 7 .
cancellous bone. Thus, ~ is empirically selected to a value slightly larger than 1.0, for example ~ = 2Ø
When the cortical bone is relatively plain, a number 1.0 < ~ < 2.0 can be selected advantageously.
S In step S38, an AND operation is carried out between the ROI image and the template image for the cortical bone portion to separate or to extract an image of the cortical bone portion (Figure 8E) from the ROI image. In step S40, a NAND operation is carried out between the ROI
image and the separated cortical bone image to separate or to extract an image of the cancellous bone.
A NAND operation can be carried out between the template image for the cortical bone and the ROI image to provide t'he cancellous bone image. Removing the cancellous bone image from the ROI image provides the cortical bone image.
A semi-binary image can be provided by putting the intensity values of the original bone sectional image obtained by the micro-focus X-ray computed tomography on the respective pixels of the cortical bone image and/or the cancellous bone image, and putting zero (0) value on the remaining hackground pixels.
When the section of a sample bone has a relatively simple configuration as in the previous description regarding a femur, the hole of the sectional image can be defined as ROI image. On the other hand, if the section of a sample bone has a relatively complex configuration, for example in case of a vertebral body, a portion of the sectional image must be defined as ROI image onto which an analysis is carried out. According to the invention, ROI is defined through providing a subject region for analysis on the sectional image.
With reference to Figures 9 - 10, a method of providing a subject region for analysis in a sectional image of a sample bone, in particular, a vertebral body, according to the embodiment of the invention will be described.
~ 2~ 0 10~ 7 In step S50 (Figure 9A), a bone sectional image is input in the image processing system as a raw image. In this embodiment, a sectional image of a vertebral body of a rat which is obtained by micro-focus X-ray computed tomography is used. In step S52, the input raw image is binarized or digitized to provide a binary image of a bone section as described above.
In step S54, the area of the binary image (AMB) is calculated by the following equation.
AMB = ~ [p(i,j)] ~-- (5) where i: X-axis coordinate (in this embodiment 0 < i 511) j: Y-axis coordinate (in this embodiment 0 < j < 479) [p(i,j)] = 1 (if pixel (i,j) belongs to class 1) [p(i,j)] = 0 (if pixel (i,j) belongs to class 0) Further in step S54, the geometrical moment of area is calculated by the following equations.
Mx~ [p(i~j)] ~-- (6) MYL = ~ [p(i,j)] ~-- (7) where MX1: the geometrical moment of area about X-axis Myl: the geometrical moment of area about y-axis In step S56, the center of gravity G of the binary image is calculated by the following equation.
(Xg, Yg) = (MXl/AMB, My1/AMB) ... (8) where (Xg, Yg): coordinate of the center of gravity In step S58, the geometrical moment of inertia of the binary image is calculated by the following equations.
M 2 = ~i~j (j _ yg~2.(~ [p(i,j)] . . . (9) My2 = ~i~j (i - Xg) ~~) [p(i, j) ] . . . (10) where MX2: the geometrical moment of inertia about X-axis ~ - 18 - 22 0 1 0~ 7 My2 the geometrical moment of inertia about y-axis Further in step S58, the product of inertia is calculated by the following equation.
M~ j (i - Xg)~(j - Y )~~1) [p(i j)] ... (11) where Mll: product of inertia In step S60, calculated by the following equation is the angle ~, related to the X-axis, of the axis of inertia about the center of gravity of the bone portion.
0 = (tan (2 x Mll/(Mxz - My2)))/2 .......... (12) In step S62, the input raw image is rotated around the center of gravity by (90 - ~) degrees in the clockwise direction so that the axis of inertia is parallel to Y-axis. In step S64, the rotated raw image is binarized or digitized by the process described above.
In step S66, pixels corresponding to the vertebral canal in the rotated binary image is determined as described bçlow. With reference to Figure 10, the rotated binary image of a vertebral body of a rat processed as described above is shown. As can be seen from Figure 10, the vertebral canal 50 is the largest hole in the sectional bone image. Thus, the areas of the respective holes are calculated by the following equation.
Ah = ~ h [ p ( i, j ) ] ~ ~ ~ ( 13) ~h [p(i, j) ] = 1 (if pixel (i,j) belongs to class 0 which indicates a hole) ~h [p(i~ j ) ] = O (if pixel (i, j ) belongs to class 1 which does not indicate a hole) Then the minimum rectangle, which encloses the vertebral canal and has two pairs of sides parallel to X-and Y-axes, respectively, is provided on the binary image. In step S68, determined is a pair of fillet coordinates Fl (xl, Yl) and Fz (x2, Y2) which are at the corners on one of the diagonals of the smallest rectangle enclosing the vertebral canal.
~ 2 2 0 1 0 ~ 7 Alternatively, the fillet coordinates Fl and F2 can be defined as follows.
Fl (Xmint Ymin) r F2 (X~axl Ymax) or Fl ( Xmin I Ymax ) r F2 ( Xmax r Ymin ) where xmax ; the maximum x coordinate of the pixel which belongs to the vertebral canal Ymax : the maximum y coordinate of the pixel which belongs to the vertebral canal xmin : the minimum x coordinate of the pixel which belongs to the vertebral canal Ymin : the minimum y coordinate of the pixel which belongs to the vertebral canal In step S70, distances dl and dz are calculated between the axis of inertia and the fillet coordinates F
(xl, Yl) and F2 (xz, Y2), respectively. In step 72, a representative length d3 is calculated by the following equation.
d3 = INT(~ x Min(dl, dz) + 0.5) ... (14) where if dl > d2, then Min(dl, d2) = d2 ... (15) if dl < d2, then Min(dl, d2) = dl ... (16) INT(x): a function removing fractional portion from x ~: a constant value The constant value ~ can be optionally determined to eliminate unwanted bone portions, such as anapophysises, which do not substantially contribute to the bone strength. In this embodiment, ~ = 0.9 is selected in consideration of the general configuration of a vertebral body of a rat. Another value of ~ can be advantageously employed depending on the general configuration in a sectional image of a kind of a bone.
In step S74, a subject region fQr analysis is defined automatically by using the representative length 22~ 10~ ~
Lr so that the previously mentioned prior art human error is eliminated. In this embodiment, a subject region for analysis is defined by a rectangle 52 which has a pair of diagonal coordinates (Xg - d3, Yg) and (Xg ~ d3, 479). A
ROI is defined within the subject region to provide a ROI
image by the pixels corresponding to the bone portion within the subject region as shown in Figure 11.
In step S76, n times of expanding operations are carried out on the ROI image, then in step S78, (n+l) times of contracting operations are carried out on the expanded image. In this embodiment, n = 8 is advantageously selected in consideration with the general size of the openings in the bone portion. In step S80, a filling hole operation is~carried out on the contracted image to provide a solid image.
In step S82, boundary pixels of the solid image which contact the background pixels are determined, and are extracted from the solid image. In step S84, an OR
operation between the boundary pixels and the ROI image are executed to provide a subject binary image, in which openings in the cortical bone portion are closed by the boundary pixels.
In step S86, a thinning operation is carried out on the subject binary image to obtain a thinned image. The thinned image includes a series of pixels which are substantially along the center line of the cortical bone portion. In step S88, an AND operation is carried out between the thinned image and the ROI image to provide a thinned subject image shown in Figure 12A. In step S90, a pair of fillet coordinates F3 (X3, y3) and F4 (x,,, y4), which are at the corners on one of the diagonals of the smallest rectangle enclosing the thinned subject image, are determined. Alternatively, the fillet coordinates F3(x3, y3) and F4(x4, y4) can be defined as follows.
F3 ( Xmin ' Ymin ' ) I F 4 ( Xmax / Ym~x ) O r F3 ( Xmin ' r Ymax ~ ) r F4 ( Xm~x ~ r Ymin ~ 22n10~7 where XmaX': the maximum x coordinate of the pixel which belongs to the thinned subject image Y~a~': the maximum y coordinate of the pixel which belongs to the thinned subject image X~in ': the minimum x coordinate of the pixel which belongs to the thinned subject image Y~in': the minimum y coordinate of the pixel which belongs to the thinned subject image In step S92, a rectangle operation area 56 which has a pair of fillet coordinates Foal (X3~ FoaZ (X4~ 478) is provided as shown in Figure 12B. The rectangle operation area 56 i,ncludes the largest and second largest holes or backgrounds 58 and 60 which have the background intensity, 0 (zero), in this embodiment at the upper and lower sides which bounds the pixels of the thinned subject image corresponding to the center line extending along the cortical bone portion.
In step S94, a find hole operation,-which determines holes which have the background intensity is carried out within the operation area 56, and the respective holes are labeled. In step S96, the largest and the second largest backgrounds 58 and 60, which are labeled in step S94, are determined in the operation area 56 as shown in Figure 12C.
In step S98, the pixels which are common to the largest background image and the subject binary image (AND operation) to provide a first hemi-cortical image 62 shown in Figure 12D, which has a wall thickness substantially half of the corresponding portion of the real cortical bone. Similarly, an AND operation is carried out between the second largest background image and the subject binary image to provide a second hemi-cortical image 64. In step S100, the mean wall thickness (MWTl and MWT2) of the first and second hemi-cortical images 62 and 64 is calculated, respectively as described - 22 ~2 0 1 ~5 7 above. Figure 12D shows a hemi-cortical bone image combined by the first and second hemi-cortical bone images 62 and 64.
In step S102, expanding operations are carried out on the hemi-cortical image to provide a template image for the cortical bone portion as shown in Figure 12E. In particular, the first hemi-cortical bone image 62 is expanded nl times, and the second hemi-cortical bone image 64 is expanded n2 times. The numbers nl and n2 are preferably defined as follows.
nl = INT(MWTl x ~1 + 1) n2 = INT(MWT2 x ~z + 1) INT(x): a function removing fractional portion from x ~1 :=a predetermined constant value a2 : a predetermined constant value Preferably, ~1 = 2.0 and ~z = 2.0 can be selected.
Alternatively, nl = INT(MWTl x ~1 + 1.5) and n2 = INT(MWT2 x ~2 + 1 . 5) may be used.
In step S104, an AND operation is carried out between the template image and the ROI image to extract pixels corresponding to the cortical bone portion shown in Figure 12F. In step S106, a NAND operation is carried out between the template image and the ROI image to extract pixels corresponding to the cancellous bone portion shown in Figure 12G.
It can be seen that, according to the invention, the cancellous bone portion and the cortical bone portion are extracted from the binary image of a sample bone section through providing the hemi-cortical bone image and the template image for the cortical bone portion. This provides significant improvement in precision of the separation of the cortical bone portion and the cancellous bone portion compared with the prior art.
various measurements and analyses are carried out on the ROI image thus provided. For example, measurement of ~ 22 0 1 0 5 ~
numbers of the terminuses, the struts and the nodes, and measurement of the length of the struts of the bone portion (shown by fine lines in Figure 13) can be carried out after the ROI image is further processed by a thinning operation.
Figure 14 schematically illustrates a measurement of the length of an intercept between a line and the bone portion. In Figure 14, a line 56, which extends at an angle relative to the X-axis through point P which is selected at random, intersects the cancellous bone portion at three intercepts 56a, 56b and 56c. The respective lengths of the intercepts 56a, 56b and 56c are determined. This process is repeated by a statistically sufficient number of times with the position of the point P and the angle of the line 56 being changed at random.
For example, the position of the point P is changed by one hundred times and the angle of the line 56 is changed by thirty-six times at the respective positions of the point P. This measurement can be applied to the cortical bone portion and to the marrow space portion.
Then, the sample of the length of the intercepts measured as described above may be processed to provide mean, maximum and minimum length, standard deviation of length and/or a parameter provided by combination thereof. The sample may be analyzed by using a pattern analysis such as Fourier analysis.
Further, the measurement and analysis can include a tensor analysis of the cancellous bone portion as described hereinafter. According to the embodiment of the invention, the tensor analysis is weighted by the mean wall thickness (MWT) of the cancellous bone portion.
First, MWT of the cancellous bone portion is calculated by means of the total area (Tb.BV) and the total perimeter (Tb.S) of the cancellous bone portion through the following equation.
MWT = 2.0 x (Tb.BV)/(Tb.S) ... (17) Then, the structural anisotropy of the cancellous 220~05 7 .
bone portion is determined by a tensor analysis as described bellow. The binary image corresponding to the cancellous bone portion provided by the invention is processed to provide a thinned image. The following operation is carried out on the each pixel of the thinned image. With reference to Figure 15, a schematic enlarged illustration of an image is shown, in which a pixel of interest is indicated by I~Piorll / and the adjacent pixels surrounding the pixel of interest Pior are referred to Pi, i = 0 to 7, respectively, in which the adjacent pixels Pi, i = 0, 1, 3, 4, 5, and 7, are positioned in the X
direction relative to the pixel of interest Piorr and the adjacent pixels Pi, i = 1, 2, 3, 5, 6 and 7, are ~ .
positioned in the Y direction relative to the pixel of intereSt Pior~
Figure 16 illustrates a flow chart for determining the structural anisotropy of the cancellous bone portion according to the invention. In step SllO in Figure 16, an initialization is carried out so that zero (0) is input into adjacency parameters nO to n7 which associate to the adjacent pixels P0 to P7r respectively. Thus, adjacency parameters ni, i = 0, 1, 3, 4, 5, and 7, are associated in the X orientation relative to the pixel of ~ interest Piorr and the adjacency parameters ni, i = l, 2, 3, 5, 6 and 7, are associated in the Y
orientation relative to the pixel of interest Pior~
In step S112, zero (o) is input into parameter i.
In step S114, it is determined whether the adjacent pixel Pi indicates the bone portion or not. If so, one (1) is added to the parameter ni (step S116), and the routine goes to step S118. In step S114, if the adjacent pixel Pi does not indicate the bone portion, the routine also goes to step S118. In step S120, it is determined whether i = 7 or not. If not, the steps S114 to S118 are carried out again. If i = 7 in step S120, that is, when -~ 220 ~05 7 the above operation has been carried out on all of the adjacent pixels P0 to P7 surrounding the pixel of interest Pior~ the process is repeated again from step S112 until the process is carried out on all of the pixels of interest. The tensor (Nx, Ny) is defined as follows.
Nx = tnO + nl + n3 + n4 + n5 + n7)/2 ... (18) Ny = (nl + n2 + n3 + ns + n6 + n7)/2 ... (19) With Reference to Figure 17, a simple example of a binary image is shown, in which the adjacency parameters are calculated by the above operation as follows.
i=0 1 2 3 4 5 6 7 Pll .0 0 0 - O O O 0 P3l 0 0 0 o O 1 0 P22 ~ 1 0 1 0 1 0 P42 ~ ~ ~ 1 0 1 0 Pl3 0 1 0 0 0 0 0 P24 ~ 1 0 1 0 0 0 0 P5b ~ ~ 1 0 0 0 0 0 ni ~ 4 1 5 0 4 1 5 Thus, the tensor in the case of Figure 17 is 2S calculated as follows.
Nx = 9 and Ny = 10 Further, in consideration of MWT, a relative tensor is provided by (NNX, NNy).
where NNX = (MWT x Nx)/(Nx + Ny)/ ................ (20) Ny ( MWT x Ny)/(NX2 + N2)l/2 .............. (21) The relative tensor indicates the relative strength of the cancellous bone portion as well as the degree of the structural anisotropy of the cancellous bone portion.
That is, by consideration of MWT, the length of the ~ 22 0 ~ ~5 ~
relative tensor (NNX, NNy) indicates the relative strength of the cancellous bone portion, and the ratio of NNX and NNy indicates the structural anisotropy of the cancellous bone portion.
It will also be understood by those skilled in the art that the forgoing description is a preferred embodiment of the disclosed device and that various changes and modifications may be made without departing from the spirit and scope of the invention.
As an example of a method for diagnosing the reduction of bone strength due to bone disease, the DEXA
(Dual Energy X-ray Absorptiometry) method and the MD
(Micro Densitometry) method are known in the art. The DEXA and MD methods measure the amount or the dencity of bone mineral to diagnose the reduction of bone strength based on an assumption that there is a correlation between the amount or the dencity of bone mineral and the bone strength. However, in fact, the amount or the dencity of bone mineral does not precisely present the bone strength since bone structure significantly affects the bone strength. Thus, in the recent years, an attempt has been developed to evaluate the bone strength based on a postulate that bone strength depends significantly on the bone structure as well as bone mineral.
As a bone structural analysis, sectional bone structural analysis is known in the art. In the sectional bone structural analysis, a sectional image of a bone is provided by a micrograph or a X-ray computed tomography of a sample bone, and is used for measuring ~ - 2 -various parameters, such as, the sectional area and the perimeter, for evaluating structural anisotropy in the bone portion (refer to ~Journal of Japanese Society of Bone Morphometry" Vol. 4, No. l Pages 83 - 89, 1994), and for the Node-strut method (refer to "Journal of Microscopy~ Vol. 142, Pt3, Pages 341 - 349, 1986).
Figure 1 is a schematic illustration of a vertebral body constituting a human spine. In general, a static compressive force substantially acts on end faces of the vertebral body within areas 2 (only one in the top end face is shown in Figure 1) as shown by arrows 1.
Therefore, during a bone morphometry, a subject region for analysis is defined on a sectional image of a sample bone, and'~-within the subject region for analysis, various analyses, such as measurements of total area in the sectional bone image, mean wall thickness of the cortical bone and the cancellous bone portions, are carried out.
In particular, the bone portion within the subject region is defined as a region of interest (ROI) so that various structural parameters are measured relative to the ROI.
With reference to Figures 2-4, a sectional binary image of a vertebral body of a rat (Figure 2), a micrograph of a vertebral body of a human (Figure 3), and a sectional binary image of a femur of a rat (Figure 4) are shown, respectively. In Figures 2 and 3, enclosed by subject regions 3 and 4 for analysis, are the portions on which a static compressive force primarily acts. In Figure 4, all of the sectional image is enclosed by a rectangle 5 as a subject region for analysis. As shown in Figures 2-4, the subject region for analysis are defined by configurations which have various shapes, sizes and orientations, for example, the rectangles 5 and 6, triangles 7 and 8, a sector 3, a circle and a configuration 4 combined thereby.
In the prior art, a subject region for analysis is manually provided on a sectional image of a sample bone so that a human error is introduced into the size, ~ 22 0 1 05 ~
shape, orientation, and position of the subject region.
The human errors reduce the credibility and repeatability of the sectional bone structural analysis carried out based on such a manually provided subject region.
On the other hand, the bone structure includes, in general, surface and internal structures. The internal structure further includes cancellous and cortical bone portions which have different functions.
For example, when a person falls so that a load is applied to a bone, the cancellous bone portion functions to bear the deformation while the cortical bone portion functions to absorb the impact. Therefore, the cancellous and cortical bone portions must be considered separately to evaluate the~internal bone structure.
There are, some apparatuses, for evaluating internal bone structure, which can separate the cancellous and cortical bone portions from each other to measure and evaluate the respective portions independently.
Such an apparatuses binarizes a raw sectional bone image, which is produced by a micrograph or X-ray computed tomograph of a sample bone to provide an original binary image for processing to separate the sectional bone image into cancellous and cortical bone portions. Then, a filling hole operation is carried out on the original binary image within the peripheral of the bone sectional image to provide a solid image. The solid image is contracted until its area becomes half.
According to this prior art method, a cancellous bone portion is provided by extracting the pixels which are common to the original binary image and the contracted solid image (referred to AND operation between the original binary image and the contracted solid image). A
cortical bone portion is provided by extracting the pixels which are not common to the original binary image and the contracted solid image (referred to NAND
operation of the original binary image and the contracted solid image).
.
~ 220~0~7 The above-mentioned prior art method defines the cancellous and cortical bone portions irrespective of the actual thickness of the cortical bone so that the structural evaluation based on the cancellous and cortical bone images thus provided cannot reflect the real bone strength.
SUMMARY OF THE INVENTION
The invention is directed to solve the problems in the prior art, and to provide an improved method of processing a sectional bone image for using in a morphometry of a bone which includes a cortical bone portion and a cancellous bone portion. The invention provides a method of processing a sectional bone image of a sample-~one which method can eliminate a human error, ~5 as produced in the prior art, by providing a subject region on a binary image digitized from the sectional bone image automatically. Further, the invention provides a fine separation of the cortical bone portion and the cancellous bone portion so that the morphometry of the sample bone, in particular, the cancellous bone portion can be carried out with high precision and repeatability.
According to the invention, first, a binary image of a bone section is provided to be processed. A subject region is provided on the binary image to producing a ROI
image by extracting pixels corresponding to the bone portion from the binary image within the subject region, onto which ROI image the morphometry is carried out. A
series of pixels which are on the center line extending along the cortical bone portion in the ROI image is determined. A hemi-cortical bone image is produced by using the determined center line. The hemi-cortical bone image has a wall thickness substantially half of the real wall thickness of the cortical bone portion.
A template image for the cortical bone portion is produced by executing expanding operations on the hemi-cortical bone image with a predetermined number of ~ ~20105Z
times of operation. The template image for the cortical bone portion, produced by expanding the hemi-cortical bone image by a number of times which is advantageously selected, defines precisely a region within which the cortical bone portion extends since the hemi-cortical bone image has a wall thickness substantially half of the real wall thickness of the cortical bone portion.
The number of times for carrying out the expansion is preferably defined by INT(MWT x ~ + 1).
where INT(x): a function removing fractional portion from x ~: a predetermined constant value Prefërably, ~ = 2.0 i-s selected. Alternatively, the number of times for carrying out the expansion may be defined by INT(MWT x ~ + 1.5).
According to another feature of the invention, extracting the pixels common to the ROI image and the template image provides an image substantially corresponding to the cortical bone portion, and eliminating the image corresponding to the cortical bone image from the ROI image provides an image corresponding to the cancellous bone portion. It will be understood that eliminating the pixels which are common to the ROI
image and the template image from the ROI image can also provide an image corresponding to the cancellous bone portion.
According to another feature of the invention, a tensor analysis of the image corresponding to the cancellous bone determines the structural anisotropy in the cancellous bone.
According to another feature of the invention, when the sectional binary image is of a vertebral body which includes a cortical bone portion and a cancellous bone portion, the region of interest is provided by providing a subject region on the binary image as follows. First, the axis of inertia of the binary image of a vertebral ~ 2201057 body, and pixels corresponding to the vertebral canal within the binary image of a vertebral body are determined. The smallest rectangle enclosing the pixels of the vertebral canal is provided and a pair of fillet coordinates which are at the corners on one of the diagonals of the smallest rectangle enclosing the vertebral canal are determined. A subject region on the binary image is provided based on a representative length, which is defined by determining the distances between the axis of inertia and the fillet coordinates as the representative length, to extract pixels corresponding to the bone portion within the subject region, whereby the region of interest is defined on the binary imiage by the extracted pixels.
Then, the hemi-cortical bone image is provided as follows. An operation region to enclose the ROI image is provided so that the operation region including the largest and second largest background portion at either side of the ROI image bounds the center line pixels. The largest and second largest backgrounds within the operation region are determined, preferably, by a labeling operation to label holes which include pixels with zero (0) intensity. Pixels are determined as first pixels which are common with the largest hole image and the ROI image to provide a first hemi-cortical image, and as second pixels which are common wlth the second largest hole image and the ROI image to provide a second hemi-cortical image. Combining the first and second hemi-cortical images provides the hemi-cortical image.
DESCRIPTION OF THE DRAWINGS
These and other objects and advantages and further description will now be discussed in connection with the drawings in which:
Figure 1 is a schematic illustration of a vertebral body constituting a human spine.
Figure 2 is a sectional binary image of a vertebral body of a rat.
~ 22 0 1 05 7 Figure 3 is a micrograph of a vertebral body of a human.
Figure 4 is a sectional binary image of a femur of a rat.
Figure 5 is a schematic illustration of an apparatus for micro-focus X-ray computed tomography.
Figure 6 is a schematic illustration of an example of an image processing system to which the inventive method can be applied.
Figure 7A is a flow chart for a method of providing a subject region for analysis on a sectional binary image of a femur of a rat, and of separating a cortical bone portion and a cancellous bone portion from each other according-~to the preferred embodiment of the invention.
Figure 7B is a flow chart for a method of providing a subject region for analysis on a sectional binary image of a femur of a rat, and of separating a cortical bone portion and a cancellous bone portion from each other according to the preferred embodiment of the invention.
Figure 8A is a schematic illustration for explaining the method according to the flow chart of Figures 7A and 7B, and in particular is a schematic illustration of a thinned image of the sectional binary image of a femur of a rat.
Figure 8B is a schematic illustration for explaining the method according to the flow chart of Figures 7A and 7B, and in particular is a schematic illustration of a solid image produced by filling the holes within the thinned image of Figure 8A.
Figure 8C is a schematic illustration for explaining the method according to the flow chart of Figures 7A and 7B, and in particular is a schematic illustration of a hemi-cortical bone image.
Figure 8D is a schematic illustration for explaining the method according to the flow chart of Figures 7A and 7B, and in particular is a schematic illustration of a template image for the cortical bone portion.
~ ~2 0 ~ 05 7 Figure 8E is a schematic illustration for explaining the method according to the flow chart of Figures 7A and 7B, and in particular is a schematic illustration of an image corresponding to the cortical bone portion.
Figure 8F is a schematic illustration for explaining the method according to the flow chart of Figures 7A and 7B, and in particular is a schematic illustration of an image corresponding to the cancellous bone portion.
Figure 9A is a flow chart for a method of providing a subject region for analysis in a sectional image of a vertebral body according to the embodiment of the invention.
Figure 9B is a flow chart for a method of providing a subject'-~region for analysis in a sectional image of a vertebral body according to the embodiment of the invention.
Figure 9C is a flow chart for a method of providing a subject region for analysis in a sectional image of a vertebral body according to the embodiment of the invention.
Figure 9D is a flow chart for a method of providing a subject region for analysis in a sectional image of a vertebral body according to the embodiment of the invention.
Figure 10 is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular is a schematic illustration of the coordinates and a sectional binary image of a vertebral body.
Figure 11 is a schematic illustration for explaining the method according to the flow chart of Figures 9A
- 9D, and in particular is a schematic illustration of the ROI image extracted from the sectional binary image of Figure 10.
Figure 12A is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular is a schematic 220 ~05 7 illustration of the thinned image.
Figure 12B is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular is a schematic illustration of providing an operation area on the thinned image of Figure 12A.
Figuré 12C is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular is a schematic illustration for explaining the find hole process executed within the operation area of Figure 12B.
Figure 12D is a schematic illustration for explaining the method according to the flow chart of Figures 9A- - 9D, and in particular is a schematic illustration of the hemi-cortical bone image.
Figure 12E is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular ls a schematic illustration of the template image for the cortical bone portion.
Figure 12F is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular is a schematic illustration of an image corresponding to the cortical bone portion.
Figure 12G is a schematic illustration for explaining the method according to the flow chart of Figures 9A - 9D, and in particular is a schematic illustration of an image corresponding to the cancellous bone portion.
Figure 13 is a schematic illustration for explaining a various measurements and analyses which can be carried on the thinned image obtained by thinning operation executed on the ROI image provide by the invention, and in particular, measurement of numbers of the nodes, the struts and the terminuses, and measurement of the length of the struts of the bone portion are illustrated.
~ 2 2 0 1 0 5 ~
Figure 14 is a schematic illustration of a measurement of the length of an intercept between a line and the bone portion which can be carried on the ROI
image provide by the invention.
Figure 15 is a schematic illustration for explaining a method of tensor analysis which is carried out to determine the structural anisotropy of the cancellous bone portion, and in particular, a schematic enlarged illustration of a thinned image produced by a thinning operation executed on the binary image corresponding to the cancellous bone portion provided by the invention, in which a pixel of interest is indicated by "Piorl' f and the adjacent pixels surrounding the pixel of interest Pior are referred to Pi, i = 0 to 7.
Figure 16 is a flow chart for determining the structural anisotropy of the cancellous bone portion by a tensor analysis according to the invention.
Figure 17 is an illustration of a simple example of a binary image for explaining the tensor analysis according to the invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
A method of processing a sectional image of a sample bone according to an embodiment of the invention will be described. A sectional image o~ a sample bone is provided to be input into an image processing system according to the invention. In order to analyze the bone structure with a high precision, an input raw image has a fine resolution, for example, lower than 20 ~m per pixel, preferably lower than 10 ~m per pixel. Tn the embodiment of the invention, such a sectional image is obtained by a micro-focus X-ray computed tomography although another method, such as a micrograph of a slice of a sample bone can be utilized.
With reference to Figure 5, micro-focus X-ray computed tomography will be described. An X-ray generator 14 includes a X-ray tube 14a o~ which the size ~ Z~01057 of the focus area is approximately 8 ~m and a rotating anode 14b. An X-ray sensor 16 and a slit 20 are provided apart from the X-ray generator 14 so that the slit 20 is positioned between the X-ray generator 14 and the X-ray sensor 16. An image reconstruction device 18 is electrically connected to the X-ray sensor 16 for receiving a signal corresponding to the intensity of the X-ray which reaches to the sensor 16. A sample bone 10 is disposed on a turntable 12 which is provided between the X-ray generator 14 and the slit 20.
X-rays are produced when electron hits the rotating anode 14b, so that the accelerated X-ray is directed to the sample bone 10. The propagated X-ray is attenuated through the sample bone 10-and reach the X-ray sensor 16 through the slit 20 so that X-rays which have the desired slice width are extracted from the propagated X-rays.
The X-ray sensor 16 sends a signal to the image reconstruction device 18 corresponding to the intensity of the X-rays. The image reconstruction device 18 stores an information corresponding to the signal. Then, the turntable 12 rotates through a predetermined angle to measure the sample bone 10 at the next rotational angle.
The above process is repeated until the measurement is carried out along the full arc of the sample bone 10.
Thereafter, the image reconstruction device 18 reconstructs a sectional image of the sample bone 10 based on the memorized information. Changing the level of the turntable 12 provides another sectional image of the sample bone 10 at a different height.
The sectional image thus obtained may consist of 512 pixels x 480 pixels with each pixel sized 15 ~m x 15 ~m, and with CT value being expressed by a gradation of 2l6.
Further the CT value of the respective pixels is converted into a gradation of 2 by the following equation (1) when the image is input into the image processing system of the invention.
~ 22 0 105 7 TL = INT(0.5 + ((CT value of the respective pixels) - (CT~in))/(CT~ax) - (CTmin)) x 255) ..- (1) where TL : converted CT value CTmaX : the maximum CT value (e.g. 2000) CTmin : the minimum CT value (e.g. 500) INT(x): a function removing fractional portion from x The image thus obtained is processed by the image processing system of the invention as described below.
With reference to Figure 6, an image processing system according to the embodiment of the invention will be described. In Figure 6, the image processing system 30 includes a computer 32 provided with a microprocessor (not shown) and memory devices (not shown) as known in the art. The image processing system 30 further includes a first or main display unit 34, such as a CRT display, for indicating text information, a second or additional display unit 36, such as a CRT display, for indicating the processed image, an output unit 38 such as a printer, and a key board 40. The system can include an additional memory device 42 such as an external hard drive unit or an magneto-optical disc drive. Instead of the first and second displays 34 and 36, a display can be provided fo~ indicating the text information and the processed image. The system may further include a pointing device 44, such as a mouse, a track ball, a touch panel or a light pen, for inputting a reference point necessary for the bone morphometry in the displayed image.
With reference to Figures 7 and 8, a method of providing a subject region for analysis on a sectional binary image of a sample bone, in particular, a femur of a rat, and of separating cortical bone portion and cancellous bone portion from each other according to the ~ ~20 ~0~ 7 preferred embodiment of the invention will be described.
In step S10, a sectional image of a femur of a rat which is obtained by X-ray computed tomography is input into the image processing system as a raw image. In step S12, the input raw image is binarized or digitized to provide a binary image of a bone section. In this embodiment, the discriminant analysis method is used to provide the binary image as describe below.
According to the discriminant analysis method, the pixels in an image are classified into two classes by a threshold value so that degrees of deviation of the intensity of the pixels in the respective class are ~inimized and the degree of deviation between the two classes is~ maximized. The~degree of deviation in classes is defined by the following equation.
~w = ~0 ~o + ~1 ~1 (2) where : number of pixels in class 0 ~O: degree of deviation of pixel in class 0 ~1: number of pixels in class 1 ~1: degree of deviation of pixel in class 1 On the other hand, the degree of deviation between the two classes is defined by the following equation.
~B2 = ~1 ~z (Mo - Ml)Z ~-- (3) where Mo mean intensity of pixels in class 0 Ml: mean intensity of pixels in class 1 The threshold value is determined to minimize the ratio of (~W2/~BZ). According to the discriminant analysis method, the pixels are thus classified into two classes, that is one is a class of "1" which means the bone portion, and the other is a class "0" which means the background or a hole.
The sectional image is binarized as described above to provide a binary image. In the case of the sectional image of the femur, a subject region for analysis is ~ 220~0~ 7 provided on the binary image to enclose the whole of the bone portion to be defined as region of interest (ROI).
Then, the following process is carried out on the ROI
image.
In general, a sectional image of a bone obtained by computed tomography may include openings in the cortical bone portion due to the blood vessels extending into the internal tissue of the bone. A binary image based on such a sectional image also includes openings in the cortical bone portion. Therefore, such a binary image must be processed to close the possible openings in the cortical bone portion.
In step S14, n times of expanding operations are carried o'ut on the ROI image, and in step S16, (n+l) times of contracting operations are carried out on the expanded image. In this embodiment, n = 12 is advantageously selected in consideration of the general size of the openings in the bone portion. In step S18, a filling hole operation is carried out on the contracted image to provide a first solid image. In step S20, boundary pixels of the first solid image which bounds the background pixels are determined and extracted from the first solid image. In step S22, the pixels which belongs to the boundary pixels or the ROI image are extracted, which is referred to as an OR operation between the boundary pixels and the ROI image. This results in a subject binary image, in which openings in the cortical bone portion are closed by the boundary pixels.
In step S24, a thinning operation is carried out on the subject binary image to obtain a thinned image as shown in Figure 8A. The thinned image includes a series of pixels which are substantially along the center line of the cortical bone portion. In step S26, a filling hole operation is carried out on the thinned image to obtain a second solid image. In step S28, one contracting operation is carried out on the second solid image, and in step S30, one expanding operation is , ~ 22 a 1 ~ 5 7 carried out on the contracted second solid image to eliminate noise pixels from the second solid image, which is referred to as a subject solid image.
In step 32, a NAND operation is carried out to extract pixels which are not common to the subject solid image and the subject binary image so that an image (in Figure 8C) which has a wall thickness substantially half of the real cortical bone portion is provided by the extracted common pixels. The image composed of the extracted pixels is referred to a hemi-cortical bone image in this specification.
Based on the hemi-cortical bone image, in step S34, the mean wall thickness (MWT) is calculated by the followingi~~equation.
MWT = 2 . 0 X A~I/PHI
where A~I: area of the hemi-cortical image PHI: perimeter of the hemi-cortical image In step S36, expanding operations are carried out by 20 a predetermined number of times on the hemi-cortical image to provide a template image for the cortical bone portion as shown in Figure 8D. Experiments show that the number of times for carrying out the expansion is preferably defined by INT(MWT x ~ + 1).
2 5 where INT(x): a function removing fractional portion from x ~ : a predetermined constant value Preferably, ~ = 2.0 is selected. Alternatively, the number of times for carrying out the expansion may be defined by INT(MWT x ~ + 1.5). The cortical bone includes recesses and protrusions along its peripheral surface. When the wall thickness varies significantly along its periphery, or even a small hole presents in the cortical hone, if ~ = l.O, then the innermost portion of the cortical bone is often recognized as a part of the 2~n105 7 .
cancellous bone. Thus, ~ is empirically selected to a value slightly larger than 1.0, for example ~ = 2Ø
When the cortical bone is relatively plain, a number 1.0 < ~ < 2.0 can be selected advantageously.
S In step S38, an AND operation is carried out between the ROI image and the template image for the cortical bone portion to separate or to extract an image of the cortical bone portion (Figure 8E) from the ROI image. In step S40, a NAND operation is carried out between the ROI
image and the separated cortical bone image to separate or to extract an image of the cancellous bone.
A NAND operation can be carried out between the template image for the cortical bone and the ROI image to provide t'he cancellous bone image. Removing the cancellous bone image from the ROI image provides the cortical bone image.
A semi-binary image can be provided by putting the intensity values of the original bone sectional image obtained by the micro-focus X-ray computed tomography on the respective pixels of the cortical bone image and/or the cancellous bone image, and putting zero (0) value on the remaining hackground pixels.
When the section of a sample bone has a relatively simple configuration as in the previous description regarding a femur, the hole of the sectional image can be defined as ROI image. On the other hand, if the section of a sample bone has a relatively complex configuration, for example in case of a vertebral body, a portion of the sectional image must be defined as ROI image onto which an analysis is carried out. According to the invention, ROI is defined through providing a subject region for analysis on the sectional image.
With reference to Figures 9 - 10, a method of providing a subject region for analysis in a sectional image of a sample bone, in particular, a vertebral body, according to the embodiment of the invention will be described.
~ 2~ 0 10~ 7 In step S50 (Figure 9A), a bone sectional image is input in the image processing system as a raw image. In this embodiment, a sectional image of a vertebral body of a rat which is obtained by micro-focus X-ray computed tomography is used. In step S52, the input raw image is binarized or digitized to provide a binary image of a bone section as described above.
In step S54, the area of the binary image (AMB) is calculated by the following equation.
AMB = ~ [p(i,j)] ~-- (5) where i: X-axis coordinate (in this embodiment 0 < i 511) j: Y-axis coordinate (in this embodiment 0 < j < 479) [p(i,j)] = 1 (if pixel (i,j) belongs to class 1) [p(i,j)] = 0 (if pixel (i,j) belongs to class 0) Further in step S54, the geometrical moment of area is calculated by the following equations.
Mx~ [p(i~j)] ~-- (6) MYL = ~ [p(i,j)] ~-- (7) where MX1: the geometrical moment of area about X-axis Myl: the geometrical moment of area about y-axis In step S56, the center of gravity G of the binary image is calculated by the following equation.
(Xg, Yg) = (MXl/AMB, My1/AMB) ... (8) where (Xg, Yg): coordinate of the center of gravity In step S58, the geometrical moment of inertia of the binary image is calculated by the following equations.
M 2 = ~i~j (j _ yg~2.(~ [p(i,j)] . . . (9) My2 = ~i~j (i - Xg) ~~) [p(i, j) ] . . . (10) where MX2: the geometrical moment of inertia about X-axis ~ - 18 - 22 0 1 0~ 7 My2 the geometrical moment of inertia about y-axis Further in step S58, the product of inertia is calculated by the following equation.
M~ j (i - Xg)~(j - Y )~~1) [p(i j)] ... (11) where Mll: product of inertia In step S60, calculated by the following equation is the angle ~, related to the X-axis, of the axis of inertia about the center of gravity of the bone portion.
0 = (tan (2 x Mll/(Mxz - My2)))/2 .......... (12) In step S62, the input raw image is rotated around the center of gravity by (90 - ~) degrees in the clockwise direction so that the axis of inertia is parallel to Y-axis. In step S64, the rotated raw image is binarized or digitized by the process described above.
In step S66, pixels corresponding to the vertebral canal in the rotated binary image is determined as described bçlow. With reference to Figure 10, the rotated binary image of a vertebral body of a rat processed as described above is shown. As can be seen from Figure 10, the vertebral canal 50 is the largest hole in the sectional bone image. Thus, the areas of the respective holes are calculated by the following equation.
Ah = ~ h [ p ( i, j ) ] ~ ~ ~ ( 13) ~h [p(i, j) ] = 1 (if pixel (i,j) belongs to class 0 which indicates a hole) ~h [p(i~ j ) ] = O (if pixel (i, j ) belongs to class 1 which does not indicate a hole) Then the minimum rectangle, which encloses the vertebral canal and has two pairs of sides parallel to X-and Y-axes, respectively, is provided on the binary image. In step S68, determined is a pair of fillet coordinates Fl (xl, Yl) and Fz (x2, Y2) which are at the corners on one of the diagonals of the smallest rectangle enclosing the vertebral canal.
~ 2 2 0 1 0 ~ 7 Alternatively, the fillet coordinates Fl and F2 can be defined as follows.
Fl (Xmint Ymin) r F2 (X~axl Ymax) or Fl ( Xmin I Ymax ) r F2 ( Xmax r Ymin ) where xmax ; the maximum x coordinate of the pixel which belongs to the vertebral canal Ymax : the maximum y coordinate of the pixel which belongs to the vertebral canal xmin : the minimum x coordinate of the pixel which belongs to the vertebral canal Ymin : the minimum y coordinate of the pixel which belongs to the vertebral canal In step S70, distances dl and dz are calculated between the axis of inertia and the fillet coordinates F
(xl, Yl) and F2 (xz, Y2), respectively. In step 72, a representative length d3 is calculated by the following equation.
d3 = INT(~ x Min(dl, dz) + 0.5) ... (14) where if dl > d2, then Min(dl, d2) = d2 ... (15) if dl < d2, then Min(dl, d2) = dl ... (16) INT(x): a function removing fractional portion from x ~: a constant value The constant value ~ can be optionally determined to eliminate unwanted bone portions, such as anapophysises, which do not substantially contribute to the bone strength. In this embodiment, ~ = 0.9 is selected in consideration of the general configuration of a vertebral body of a rat. Another value of ~ can be advantageously employed depending on the general configuration in a sectional image of a kind of a bone.
In step S74, a subject region fQr analysis is defined automatically by using the representative length 22~ 10~ ~
Lr so that the previously mentioned prior art human error is eliminated. In this embodiment, a subject region for analysis is defined by a rectangle 52 which has a pair of diagonal coordinates (Xg - d3, Yg) and (Xg ~ d3, 479). A
ROI is defined within the subject region to provide a ROI
image by the pixels corresponding to the bone portion within the subject region as shown in Figure 11.
In step S76, n times of expanding operations are carried out on the ROI image, then in step S78, (n+l) times of contracting operations are carried out on the expanded image. In this embodiment, n = 8 is advantageously selected in consideration with the general size of the openings in the bone portion. In step S80, a filling hole operation is~carried out on the contracted image to provide a solid image.
In step S82, boundary pixels of the solid image which contact the background pixels are determined, and are extracted from the solid image. In step S84, an OR
operation between the boundary pixels and the ROI image are executed to provide a subject binary image, in which openings in the cortical bone portion are closed by the boundary pixels.
In step S86, a thinning operation is carried out on the subject binary image to obtain a thinned image. The thinned image includes a series of pixels which are substantially along the center line of the cortical bone portion. In step S88, an AND operation is carried out between the thinned image and the ROI image to provide a thinned subject image shown in Figure 12A. In step S90, a pair of fillet coordinates F3 (X3, y3) and F4 (x,,, y4), which are at the corners on one of the diagonals of the smallest rectangle enclosing the thinned subject image, are determined. Alternatively, the fillet coordinates F3(x3, y3) and F4(x4, y4) can be defined as follows.
F3 ( Xmin ' Ymin ' ) I F 4 ( Xmax / Ym~x ) O r F3 ( Xmin ' r Ymax ~ ) r F4 ( Xm~x ~ r Ymin ~ 22n10~7 where XmaX': the maximum x coordinate of the pixel which belongs to the thinned subject image Y~a~': the maximum y coordinate of the pixel which belongs to the thinned subject image X~in ': the minimum x coordinate of the pixel which belongs to the thinned subject image Y~in': the minimum y coordinate of the pixel which belongs to the thinned subject image In step S92, a rectangle operation area 56 which has a pair of fillet coordinates Foal (X3~ FoaZ (X4~ 478) is provided as shown in Figure 12B. The rectangle operation area 56 i,ncludes the largest and second largest holes or backgrounds 58 and 60 which have the background intensity, 0 (zero), in this embodiment at the upper and lower sides which bounds the pixels of the thinned subject image corresponding to the center line extending along the cortical bone portion.
In step S94, a find hole operation,-which determines holes which have the background intensity is carried out within the operation area 56, and the respective holes are labeled. In step S96, the largest and the second largest backgrounds 58 and 60, which are labeled in step S94, are determined in the operation area 56 as shown in Figure 12C.
In step S98, the pixels which are common to the largest background image and the subject binary image (AND operation) to provide a first hemi-cortical image 62 shown in Figure 12D, which has a wall thickness substantially half of the corresponding portion of the real cortical bone. Similarly, an AND operation is carried out between the second largest background image and the subject binary image to provide a second hemi-cortical image 64. In step S100, the mean wall thickness (MWTl and MWT2) of the first and second hemi-cortical images 62 and 64 is calculated, respectively as described - 22 ~2 0 1 ~5 7 above. Figure 12D shows a hemi-cortical bone image combined by the first and second hemi-cortical bone images 62 and 64.
In step S102, expanding operations are carried out on the hemi-cortical image to provide a template image for the cortical bone portion as shown in Figure 12E. In particular, the first hemi-cortical bone image 62 is expanded nl times, and the second hemi-cortical bone image 64 is expanded n2 times. The numbers nl and n2 are preferably defined as follows.
nl = INT(MWTl x ~1 + 1) n2 = INT(MWT2 x ~z + 1) INT(x): a function removing fractional portion from x ~1 :=a predetermined constant value a2 : a predetermined constant value Preferably, ~1 = 2.0 and ~z = 2.0 can be selected.
Alternatively, nl = INT(MWTl x ~1 + 1.5) and n2 = INT(MWT2 x ~2 + 1 . 5) may be used.
In step S104, an AND operation is carried out between the template image and the ROI image to extract pixels corresponding to the cortical bone portion shown in Figure 12F. In step S106, a NAND operation is carried out between the template image and the ROI image to extract pixels corresponding to the cancellous bone portion shown in Figure 12G.
It can be seen that, according to the invention, the cancellous bone portion and the cortical bone portion are extracted from the binary image of a sample bone section through providing the hemi-cortical bone image and the template image for the cortical bone portion. This provides significant improvement in precision of the separation of the cortical bone portion and the cancellous bone portion compared with the prior art.
various measurements and analyses are carried out on the ROI image thus provided. For example, measurement of ~ 22 0 1 0 5 ~
numbers of the terminuses, the struts and the nodes, and measurement of the length of the struts of the bone portion (shown by fine lines in Figure 13) can be carried out after the ROI image is further processed by a thinning operation.
Figure 14 schematically illustrates a measurement of the length of an intercept between a line and the bone portion. In Figure 14, a line 56, which extends at an angle relative to the X-axis through point P which is selected at random, intersects the cancellous bone portion at three intercepts 56a, 56b and 56c. The respective lengths of the intercepts 56a, 56b and 56c are determined. This process is repeated by a statistically sufficient number of times with the position of the point P and the angle of the line 56 being changed at random.
For example, the position of the point P is changed by one hundred times and the angle of the line 56 is changed by thirty-six times at the respective positions of the point P. This measurement can be applied to the cortical bone portion and to the marrow space portion.
Then, the sample of the length of the intercepts measured as described above may be processed to provide mean, maximum and minimum length, standard deviation of length and/or a parameter provided by combination thereof. The sample may be analyzed by using a pattern analysis such as Fourier analysis.
Further, the measurement and analysis can include a tensor analysis of the cancellous bone portion as described hereinafter. According to the embodiment of the invention, the tensor analysis is weighted by the mean wall thickness (MWT) of the cancellous bone portion.
First, MWT of the cancellous bone portion is calculated by means of the total area (Tb.BV) and the total perimeter (Tb.S) of the cancellous bone portion through the following equation.
MWT = 2.0 x (Tb.BV)/(Tb.S) ... (17) Then, the structural anisotropy of the cancellous 220~05 7 .
bone portion is determined by a tensor analysis as described bellow. The binary image corresponding to the cancellous bone portion provided by the invention is processed to provide a thinned image. The following operation is carried out on the each pixel of the thinned image. With reference to Figure 15, a schematic enlarged illustration of an image is shown, in which a pixel of interest is indicated by I~Piorll / and the adjacent pixels surrounding the pixel of interest Pior are referred to Pi, i = 0 to 7, respectively, in which the adjacent pixels Pi, i = 0, 1, 3, 4, 5, and 7, are positioned in the X
direction relative to the pixel of interest Piorr and the adjacent pixels Pi, i = 1, 2, 3, 5, 6 and 7, are ~ .
positioned in the Y direction relative to the pixel of intereSt Pior~
Figure 16 illustrates a flow chart for determining the structural anisotropy of the cancellous bone portion according to the invention. In step SllO in Figure 16, an initialization is carried out so that zero (0) is input into adjacency parameters nO to n7 which associate to the adjacent pixels P0 to P7r respectively. Thus, adjacency parameters ni, i = 0, 1, 3, 4, 5, and 7, are associated in the X orientation relative to the pixel of ~ interest Piorr and the adjacency parameters ni, i = l, 2, 3, 5, 6 and 7, are associated in the Y
orientation relative to the pixel of interest Pior~
In step S112, zero (o) is input into parameter i.
In step S114, it is determined whether the adjacent pixel Pi indicates the bone portion or not. If so, one (1) is added to the parameter ni (step S116), and the routine goes to step S118. In step S114, if the adjacent pixel Pi does not indicate the bone portion, the routine also goes to step S118. In step S120, it is determined whether i = 7 or not. If not, the steps S114 to S118 are carried out again. If i = 7 in step S120, that is, when -~ 220 ~05 7 the above operation has been carried out on all of the adjacent pixels P0 to P7 surrounding the pixel of interest Pior~ the process is repeated again from step S112 until the process is carried out on all of the pixels of interest. The tensor (Nx, Ny) is defined as follows.
Nx = tnO + nl + n3 + n4 + n5 + n7)/2 ... (18) Ny = (nl + n2 + n3 + ns + n6 + n7)/2 ... (19) With Reference to Figure 17, a simple example of a binary image is shown, in which the adjacency parameters are calculated by the above operation as follows.
i=0 1 2 3 4 5 6 7 Pll .0 0 0 - O O O 0 P3l 0 0 0 o O 1 0 P22 ~ 1 0 1 0 1 0 P42 ~ ~ ~ 1 0 1 0 Pl3 0 1 0 0 0 0 0 P24 ~ 1 0 1 0 0 0 0 P5b ~ ~ 1 0 0 0 0 0 ni ~ 4 1 5 0 4 1 5 Thus, the tensor in the case of Figure 17 is 2S calculated as follows.
Nx = 9 and Ny = 10 Further, in consideration of MWT, a relative tensor is provided by (NNX, NNy).
where NNX = (MWT x Nx)/(Nx + Ny)/ ................ (20) Ny ( MWT x Ny)/(NX2 + N2)l/2 .............. (21) The relative tensor indicates the relative strength of the cancellous bone portion as well as the degree of the structural anisotropy of the cancellous bone portion.
That is, by consideration of MWT, the length of the ~ 22 0 ~ ~5 ~
relative tensor (NNX, NNy) indicates the relative strength of the cancellous bone portion, and the ratio of NNX and NNy indicates the structural anisotropy of the cancellous bone portion.
It will also be understood by those skilled in the art that the forgoing description is a preferred embodiment of the disclosed device and that various changes and modifications may be made without departing from the spirit and scope of the invention.
Claims (22)
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:
1. A method of processing a sectional bone image for a morphometry of a bone which includes a cortical bone portion and a cancellous bone portion, comprising the steps of:
providing a binary image of a bone section;
providing a subject region on the binary image to producing a ROI image by extracting pixels corresponding to the bone portion from the binary image within the subject region, onto which ROI image the morphometry is carried out;
determining a series of pixels along the center line extending along the cortical bone portion in the ROI image; and providing a hemi-cortical bone image which has a wall thickness substantially half of the real wall thickness of the cortical bone portion by using the center line determined in the preceding step.
providing a binary image of a bone section;
providing a subject region on the binary image to producing a ROI image by extracting pixels corresponding to the bone portion from the binary image within the subject region, onto which ROI image the morphometry is carried out;
determining a series of pixels along the center line extending along the cortical bone portion in the ROI image; and providing a hemi-cortical bone image which has a wall thickness substantially half of the real wall thickness of the cortical bone portion by using the center line determined in the preceding step.
2. The method of processing a sectional bone image according to claim 1, further comprising a step of providing a template image for the cortical bone portion by executing expanding operations on the hemi-cortical bone image a predetermined number of times.
3. The method of processing a sectional bone image according to claim 1, in which the series of pixels along the center line extending along the cortical bone portion is determined by executing a thinning process on the ROI
image.
image.
4. The method of processing a sectional bone image according to claim 1, in which the hemi-cortical bone image is provided by the steps of:
executing a filling hole operation on the center line image to provide a solid image; and removing the pixels of the solid image from the ROI image.
executing a filling hole operation on the center line image to provide a solid image; and removing the pixels of the solid image from the ROI image.
5. The method of processing a sectional bone image according to claim 2, further comprising a step of extracting the common pixels between the ROI image and the template image to provide an image substantially corresponding to the cortical bone portion.
6. The method of processing a sectional bone image according to claim 5, further comprising a step of eliminating the image corresponding to the cortical bone image from the ROI image to provide an image corresponding to the cancellous bone portion.
7. The method of processing a sectional bone image according to claim 6, further comprising the step of executing a tensor analysis on the image corresponding to the cancellous bone to determine the structural anisotropy in the cancellous bone.
8. The method of processing a sectional bone image according to claim 2, further comprising a step of eliminating the pixels, which are common to the ROI image and the template image, from the ROI image to provide an image corresponding to the cancellous bone portion.
9. The method of processing a sectional bone image according to claim 8, further comprising a step of eliminating the image corresponding to the cancellous bone portion from the ROI image to provide an image corresponding to the cortical bone portion.
10. The method of processing a sectional bone image according to claim 8, further comprising the step of executing a tensor analysis on the image corresponding to the cancellous bone to determine the structural anisotropy in the cancellous bone.
11. A method of processing a sectional bone image according to claim 1, in which the binary image is of a vertebral body which includes a cortical bone portion and a cancellous bone portion, and the region of interest is provided by the steps of:
determining the axis of inertia of the binary image of a vertebral body;
determining pixels corresponding to the vertebral canal within the binary image of a vertebral body;
determining a respective length relating to the extension of the vertebral canal; and providing a subject region on the binary image based on the representative length to extract pixels corresponding to the bone portion within the subject region whereby the region of interest is defined on the binary image by the extracted pixels.
determining the axis of inertia of the binary image of a vertebral body;
determining pixels corresponding to the vertebral canal within the binary image of a vertebral body;
determining a respective length relating to the extension of the vertebral canal; and providing a subject region on the binary image based on the representative length to extract pixels corresponding to the bone portion within the subject region whereby the region of interest is defined on the binary image by the extracted pixels.
12. A method of processing a sectional bone image according to claim 11, in which the step of determining the representative length includes steps of providing the smallest rectangle enclosing the pixels of the vertebral canal;
determining a pair of fillet coordinates which are at the corners on one of the diagonals of the smallest rectangle enclosing the vertebral canal; and determining the distances between the axis of inertia and the fillet coordinates as the representative length.
determining a pair of fillet coordinates which are at the corners on one of the diagonals of the smallest rectangle enclosing the vertebral canal; and determining the distances between the axis of inertia and the fillet coordinates as the representative length.
13. A method of processing a sectional bone image according to claim 11 in which the step of determining the representative length includes steps of determining the maximum and minimum x and y coordinates of the pixels which belong to the vertebral canal; and determining the distances between the axis of inertia and the points defined by the maximum and minimum x and y coordinates as the representative length.
14. The method of processing a sectional bone image according to claim 11, further comprising a step of providing a template image for the cortical bone portion by executing expanding operations on the hemi-cortical bone image a predetermined number of times.
15. The method of processing a sectional bone image according to claim 11, in which a series of pixels along the center line extending along the cortical bone portion is determined by executing a thinning process on the ROI
image.
image.
16. The method of processing a sectional bone image according to claim 11, in which the hemi-cortical bone image is provided by the steps of:
providing an operation region to enclose the ROI image so that the operation region including the largest and second largest background portion at the either side of the ROI image bounds the center line pixels;
determining the largest and second largest backgrounds within the operation region;
determining first pixels which are common with the largest hole image and the ROI image to provide a first hemi-cortical bone image;
determining second pixels which are common with the second largest hole image and the ROI image to provide a second hemi-cortical bone image; and combining the first and second hemi-cortical images to provide the hemi-cortical bone image.
providing an operation region to enclose the ROI image so that the operation region including the largest and second largest background portion at the either side of the ROI image bounds the center line pixels;
determining the largest and second largest backgrounds within the operation region;
determining first pixels which are common with the largest hole image and the ROI image to provide a first hemi-cortical bone image;
determining second pixels which are common with the second largest hole image and the ROI image to provide a second hemi-cortical bone image; and combining the first and second hemi-cortical images to provide the hemi-cortical bone image.
17. The method of processing a sectional bone image according to claim 11, further comprising a step of extracting the common pixels between the ROI image and the template image to provide an image substantially corresponding to the cortical bone portion.
18. The method of processing a sectional bone image according to claim 17, further comprising a step of eliminating the image corresponding to the cortical bone image from the ROI image to provide an image corresponding to the cancellous bone portion.
19. The method of processing a sectional bone image according to claim 18, further comprising the step of executing a tensor analysis on the image corresponding to the cancellous bone to determine the structural anisotropy in the cancellous bone.
20. The method of processing a sectional bone image according to claim 11, future comprising a step of eliminating the pixels, which are common to the ROI image and the template image, from the ROI image to provide an image corresponding to the cancellous bone portion.
21. The method of processing a sectional bone image according to claim 20, further comprising a step of eliminating the image corresponding to the cancellous bone portion from the ROI image to provide an image corresponding to the cortical bone portion.
22. The method of processing a sectional bone image according to claim 20, further comprising the step of executing a tensor analysis on the image corresponding to the cancellous bone to determine the structural anisotropy in the cancellous bone.
Applications Claiming Priority (6)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP07643096A JP3258233B2 (en) | 1996-03-29 | 1996-03-29 | Bone measurement method |
| JP8-76430 | 1996-03-29 | ||
| JP8-83940 | 1996-04-05 | ||
| JP08394096A JP3238626B2 (en) | 1996-04-05 | 1996-04-05 | Bone measurement method |
| JP8-112418 | 1996-05-07 | ||
| JP11241896A JP3229200B2 (en) | 1996-05-07 | 1996-05-07 | Bone measurement method |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| CA2201057A1 CA2201057A1 (en) | 1997-09-29 |
| CA2201057C true CA2201057C (en) | 2002-01-01 |
Family
ID=27302154
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA002201057A Expired - Fee Related CA2201057C (en) | 1996-03-29 | 1997-03-26 | A method of processing a sectional image of a sample bone including a cortical bone portion and a cancellous bone portion |
Country Status (6)
| Country | Link |
|---|---|
| US (1) | US5835619A (en) |
| EP (1) | EP0803843B1 (en) |
| AT (1) | ATE250252T1 (en) |
| AU (1) | AU713136B2 (en) |
| CA (1) | CA2201057C (en) |
| DE (1) | DE69724865D1 (en) |
Families Citing this family (118)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US6021213A (en) * | 1996-06-13 | 2000-02-01 | Eli Lilly And Company | Automatic contextual segmentation for imaging bones for osteoporosis therapies |
| US8545569B2 (en) | 2001-05-25 | 2013-10-01 | Conformis, Inc. | Patient selectable knee arthroplasty devices |
| US8735773B2 (en) | 2007-02-14 | 2014-05-27 | Conformis, Inc. | Implant device and method for manufacture |
| US9603711B2 (en) | 2001-05-25 | 2017-03-28 | Conformis, Inc. | Patient-adapted and improved articular implants, designs and related guide tools |
| US7618451B2 (en) | 2001-05-25 | 2009-11-17 | Conformis, Inc. | Patient selectable joint arthroplasty devices and surgical tools facilitating increased accuracy, speed and simplicity in performing total and partial joint arthroplasty |
| US8771365B2 (en) | 2009-02-25 | 2014-07-08 | Conformis, Inc. | Patient-adapted and improved orthopedic implants, designs, and related tools |
| US8480754B2 (en) | 2001-05-25 | 2013-07-09 | Conformis, Inc. | Patient-adapted and improved articular implants, designs and related guide tools |
| US8556983B2 (en) | 2001-05-25 | 2013-10-15 | Conformis, Inc. | Patient-adapted and improved orthopedic implants, designs and related tools |
| US8617242B2 (en) | 2001-05-25 | 2013-12-31 | Conformis, Inc. | Implant device and method for manufacture |
| US8882847B2 (en) | 2001-05-25 | 2014-11-11 | Conformis, Inc. | Patient selectable knee joint arthroplasty devices |
| US7468075B2 (en) | 2001-05-25 | 2008-12-23 | Conformis, Inc. | Methods and compositions for articular repair |
| US7534263B2 (en) | 2001-05-25 | 2009-05-19 | Conformis, Inc. | Surgical tools facilitating increased accuracy, speed and simplicity in performing joint arthroplasty |
| US8083745B2 (en) | 2001-05-25 | 2011-12-27 | Conformis, Inc. | Surgical tools for arthroplasty |
| JP3656695B2 (en) * | 1997-09-30 | 2005-06-08 | 富士写真フイルム株式会社 | Bone measuring method and apparatus |
| US6310967B1 (en) * | 1998-04-29 | 2001-10-30 | University Of South Florida | Normal and abnormal tissue identification system and method for medical images such as digital mammograms |
| US7184814B2 (en) | 1998-09-14 | 2007-02-27 | The Board Of Trustees Of The Leland Stanford Junior University | Assessing the condition of a joint and assessing cartilage loss |
| ATE439806T1 (en) | 1998-09-14 | 2009-09-15 | Univ Leland Stanford Junior | DETERMINING THE CONDITION OF A JOINT AND PREVENTING DAMAGE |
| US7239908B1 (en) | 1998-09-14 | 2007-07-03 | The Board Of Trustees Of The Leland Stanford Junior University | Assessing the condition of a joint and devising treatment |
| US6839457B1 (en) | 1999-06-03 | 2005-01-04 | Teijin Limited | Bone measuring method |
| US6941323B1 (en) | 1999-08-09 | 2005-09-06 | Almen Laboratories, Inc. | System and method for image comparison and retrieval by enhancing, defining, and parameterizing objects in images |
| ATE426357T1 (en) | 2000-09-14 | 2009-04-15 | Univ Leland Stanford Junior | ASSESSING THE CONDITION OF A JOINT AND PLANNING TREATMENT |
| KR100419573B1 (en) * | 2000-12-14 | 2004-02-19 | 한국전자통신연구원 | Method for evaluating trabecular bone using X-ray image |
| US7664297B2 (en) * | 2001-04-26 | 2010-02-16 | Teijin Limited | Three-dimensional joint structure measuring method |
| JP2005504563A (en) | 2001-05-25 | 2005-02-17 | イメージング セラピューティクス,インコーポレーテッド | Methods and compositions for resurfacing joints |
| US8951260B2 (en) | 2001-05-25 | 2015-02-10 | Conformis, Inc. | Surgical cutting guide |
| US8439926B2 (en) | 2001-05-25 | 2013-05-14 | Conformis, Inc. | Patient selectable joint arthroplasty devices and surgical tools |
| AU2002360293A1 (en) * | 2001-11-23 | 2003-06-10 | The University Of Chicago | Differentiation of bone disease on radiographic images |
| ITMI20021184A1 (en) * | 2002-05-31 | 2003-12-01 | Milano Politecnico | DEVICE FOR MEASURING THE TENSOR OF A RIGID BODY |
| EP1555962B1 (en) | 2002-10-07 | 2011-02-09 | Conformis, Inc. | Minimally invasive joint implant with 3-dimensional geometry matching the articular surfaces |
| JP2006505366A (en) | 2002-11-07 | 2006-02-16 | コンフォーミス・インコーポレイテッド | Method of determining meniscus size and shape and devised treatment |
| DE102004026524A1 (en) * | 2004-05-25 | 2005-12-22 | Aesculap Ag & Co. Kg | Bone based coordinate system determination procedure for implant operations uses tomography to find centre of gravity and load paths |
| WO2006039358A2 (en) * | 2004-09-30 | 2006-04-13 | The Regents Of The University Of California | Method for assessment of the structure-function characteristics of structures in a human or animal body |
| EP1847221B1 (en) * | 2005-02-09 | 2013-07-17 | Hitachi Medical Corporation | Diagnostic imaging support system and diagnostic imaging support program |
| WO2007092841A2 (en) | 2006-02-06 | 2007-08-16 | Conformis, Inc. | Patient selectable joint arthroplasty devices and surgical tools |
| US8623026B2 (en) | 2006-02-06 | 2014-01-07 | Conformis, Inc. | Patient selectable joint arthroplasty devices and surgical tools incorporating anatomical relief |
| US8608748B2 (en) | 2006-02-27 | 2013-12-17 | Biomet Manufacturing, Llc | Patient specific guides |
| US9918740B2 (en) | 2006-02-27 | 2018-03-20 | Biomet Manufacturing, Llc | Backup surgical instrument system and method |
| US10278711B2 (en) | 2006-02-27 | 2019-05-07 | Biomet Manufacturing, Llc | Patient-specific femoral guide |
| US9907659B2 (en) | 2007-04-17 | 2018-03-06 | Biomet Manufacturing, Llc | Method and apparatus for manufacturing an implant |
| US20150335438A1 (en) | 2006-02-27 | 2015-11-26 | Biomet Manufacturing, Llc. | Patient-specific augments |
| US8591516B2 (en) | 2006-02-27 | 2013-11-26 | Biomet Manufacturing, Llc | Patient-specific orthopedic instruments |
| US9339278B2 (en) | 2006-02-27 | 2016-05-17 | Biomet Manufacturing, Llc | Patient-specific acetabular guides and associated instruments |
| US9289253B2 (en) | 2006-02-27 | 2016-03-22 | Biomet Manufacturing, Llc | Patient-specific shoulder guide |
| US8568487B2 (en) | 2006-02-27 | 2013-10-29 | Biomet Manufacturing, Llc | Patient-specific hip joint devices |
| US8535387B2 (en) | 2006-02-27 | 2013-09-17 | Biomet Manufacturing, Llc | Patient-specific tools and implants |
| US8377066B2 (en) * | 2006-02-27 | 2013-02-19 | Biomet Manufacturing Corp. | Patient-specific elbow guides and associated methods |
| US9345548B2 (en) | 2006-02-27 | 2016-05-24 | Biomet Manufacturing, Llc | Patient-specific pre-operative planning |
| US9113971B2 (en) | 2006-02-27 | 2015-08-25 | Biomet Manufacturing, Llc | Femoral acetabular impingement guide |
| US9173661B2 (en) | 2006-02-27 | 2015-11-03 | Biomet Manufacturing, Llc | Patient specific alignment guide with cutting surface and laser indicator |
| US8133234B2 (en) | 2006-02-27 | 2012-03-13 | Biomet Manufacturing Corp. | Patient specific acetabular guide and method |
| US8608749B2 (en) | 2006-02-27 | 2013-12-17 | Biomet Manufacturing, Llc | Patient-specific acetabular guides and associated instruments |
| US8603180B2 (en) | 2006-02-27 | 2013-12-10 | Biomet Manufacturing, Llc | Patient-specific acetabular alignment guides |
| US8407067B2 (en) | 2007-04-17 | 2013-03-26 | Biomet Manufacturing Corp. | Method and apparatus for manufacturing an implant |
| US7967868B2 (en) | 2007-04-17 | 2011-06-28 | Biomet Manufacturing Corp. | Patient-modified implant and associated method |
| US20070211930A1 (en) * | 2006-03-09 | 2007-09-13 | Terry Dolwick | Attribute based image enhancement and display for medical imaging applications |
| US20090051082A1 (en) * | 2006-04-13 | 2009-02-26 | Sagawa Printing Co., Ltd. | Method for producing artificial bone |
| US9795399B2 (en) | 2006-06-09 | 2017-10-24 | Biomet Manufacturing, Llc | Patient-specific knee alignment guide and associated method |
| GB2442441B (en) | 2006-10-03 | 2011-11-09 | Biomet Uk Ltd | Surgical instrument |
| US20090055137A1 (en) * | 2007-08-22 | 2009-02-26 | Imed Gargouri | Method for obtaining geometric properties of an anatomic part |
| US8682052B2 (en) | 2008-03-05 | 2014-03-25 | Conformis, Inc. | Implants for altering wear patterns of articular surfaces |
| JP4492886B2 (en) * | 2008-04-03 | 2010-06-30 | 富士フイルム株式会社 | Three-dimensional intraperitoneal region detection apparatus, method, and program |
| EP2303193A4 (en) | 2008-05-12 | 2012-03-21 | Conformis Inc | Devices and methods for treatment of facet and other joints |
| US9017334B2 (en) | 2009-02-24 | 2015-04-28 | Microport Orthopedics Holdings Inc. | Patient specific surgical guide locator and mount |
| US8808297B2 (en) | 2009-02-24 | 2014-08-19 | Microport Orthopedics Holdings Inc. | Orthopedic surgical guide |
| US8808303B2 (en) | 2009-02-24 | 2014-08-19 | Microport Orthopedics Holdings Inc. | Orthopedic surgical guide |
| WO2010099231A2 (en) | 2009-02-24 | 2010-09-02 | Conformis, Inc. | Automated systems for manufacturing patient-specific orthopedic implants and instrumentation |
| SG175229A1 (en) | 2009-04-16 | 2011-11-28 | Conformis Inc | Patient-specific joint arthroplasty devices for ligament repair |
| DE102009028503B4 (en) | 2009-08-13 | 2013-11-14 | Biomet Manufacturing Corp. | Resection template for the resection of bones, method for producing such a resection template and operation set for performing knee joint surgery |
| EP2509539B1 (en) | 2009-12-11 | 2020-07-01 | ConforMIS, Inc. | Patient-specific and patient-engineered orthopedic implants |
| US9058665B2 (en) | 2009-12-30 | 2015-06-16 | General Electric Company | Systems and methods for identifying bone marrow in medical images |
| US8632547B2 (en) | 2010-02-26 | 2014-01-21 | Biomet Sports Medicine, Llc | Patient-specific osteotomy devices and methods |
| US9271744B2 (en) | 2010-09-29 | 2016-03-01 | Biomet Manufacturing, Llc | Patient-specific guide for partial acetabular socket replacement |
| US9968376B2 (en) | 2010-11-29 | 2018-05-15 | Biomet Manufacturing, Llc | Patient-specific orthopedic instruments |
| EP2754419B1 (en) | 2011-02-15 | 2024-02-07 | ConforMIS, Inc. | Patient-adapted and improved orthopedic implants |
| US9241745B2 (en) | 2011-03-07 | 2016-01-26 | Biomet Manufacturing, Llc | Patient-specific femoral version guide |
| US8715289B2 (en) | 2011-04-15 | 2014-05-06 | Biomet Manufacturing, Llc | Patient-specific numerically controlled instrument |
| US9675400B2 (en) | 2011-04-19 | 2017-06-13 | Biomet Manufacturing, Llc | Patient-specific fracture fixation instrumentation and method |
| US8668700B2 (en) | 2011-04-29 | 2014-03-11 | Biomet Manufacturing, Llc | Patient-specific convertible guides |
| US8956364B2 (en) | 2011-04-29 | 2015-02-17 | Biomet Manufacturing, Llc | Patient-specific partial knee guides and other instruments |
| US8532807B2 (en) | 2011-06-06 | 2013-09-10 | Biomet Manufacturing, Llc | Pre-operative planning and manufacturing method for orthopedic procedure |
| US9084618B2 (en) | 2011-06-13 | 2015-07-21 | Biomet Manufacturing, Llc | Drill guides for confirming alignment of patient-specific alignment guides |
| US8891848B2 (en) * | 2011-06-14 | 2014-11-18 | Radnostics, LLC | Automated vertebral body image segmentation for medical screening |
| US8764760B2 (en) | 2011-07-01 | 2014-07-01 | Biomet Manufacturing, Llc | Patient-specific bone-cutting guidance instruments and methods |
| US20130001121A1 (en) | 2011-07-01 | 2013-01-03 | Biomet Manufacturing Corp. | Backup kit for a patient-specific arthroplasty kit assembly |
| US8597365B2 (en) | 2011-08-04 | 2013-12-03 | Biomet Manufacturing, Llc | Patient-specific pelvic implants for acetabular reconstruction |
| WO2013020142A2 (en) | 2011-08-04 | 2013-02-07 | University Of Southern California | Image-based crack detection |
| US9066734B2 (en) | 2011-08-31 | 2015-06-30 | Biomet Manufacturing, Llc | Patient-specific sacroiliac guides and associated methods |
| US9295497B2 (en) | 2011-08-31 | 2016-03-29 | Biomet Manufacturing, Llc | Patient-specific sacroiliac and pedicle guides |
| US9386993B2 (en) | 2011-09-29 | 2016-07-12 | Biomet Manufacturing, Llc | Patient-specific femoroacetabular impingement instruments and methods |
| US9554910B2 (en) | 2011-10-27 | 2017-01-31 | Biomet Manufacturing, Llc | Patient-specific glenoid guide and implants |
| US9451973B2 (en) | 2011-10-27 | 2016-09-27 | Biomet Manufacturing, Llc | Patient specific glenoid guide |
| KR20130046337A (en) | 2011-10-27 | 2013-05-07 | 삼성전자주식회사 | Multi-view device and contol method thereof, display apparatus and contol method thereof, and display system |
| EP2770918B1 (en) | 2011-10-27 | 2017-07-19 | Biomet Manufacturing, LLC | Patient-specific glenoid guides |
| US9301812B2 (en) | 2011-10-27 | 2016-04-05 | Biomet Manufacturing, Llc | Methods for patient-specific shoulder arthroplasty |
| WO2013090830A1 (en) | 2011-12-16 | 2013-06-20 | University Of Southern California | Autonomous pavement condition assessment |
| US9237950B2 (en) | 2012-02-02 | 2016-01-19 | Biomet Manufacturing, Llc | Implant with patient-specific porous structure |
| US9486226B2 (en) | 2012-04-18 | 2016-11-08 | Conformis, Inc. | Tibial guides, tools, and techniques for resecting the tibial plateau |
| US9675471B2 (en) | 2012-06-11 | 2017-06-13 | Conformis, Inc. | Devices, techniques and methods for assessing joint spacing, balancing soft tissues and obtaining desired kinematics for joint implant components |
| US9060788B2 (en) | 2012-12-11 | 2015-06-23 | Biomet Manufacturing, Llc | Patient-specific acetabular guide for anterior approach |
| US9204977B2 (en) | 2012-12-11 | 2015-12-08 | Biomet Manufacturing, Llc | Patient-specific acetabular guide for anterior approach |
| US9839438B2 (en) | 2013-03-11 | 2017-12-12 | Biomet Manufacturing, Llc | Patient-specific glenoid guide with a reusable guide holder |
| US9579107B2 (en) | 2013-03-12 | 2017-02-28 | Biomet Manufacturing, Llc | Multi-point fit for patient specific guide |
| US9498233B2 (en) | 2013-03-13 | 2016-11-22 | Biomet Manufacturing, Llc. | Universal acetabular guide and associated hardware |
| US9826981B2 (en) | 2013-03-13 | 2017-11-28 | Biomet Manufacturing, Llc | Tangential fit of patient-specific guides |
| US9517145B2 (en) | 2013-03-15 | 2016-12-13 | Biomet Manufacturing, Llc | Guide alignment system and method |
| US20150112349A1 (en) | 2013-10-21 | 2015-04-23 | Biomet Manufacturing, Llc | Ligament Guide Registration |
| US10282488B2 (en) | 2014-04-25 | 2019-05-07 | Biomet Manufacturing, Llc | HTO guide with optional guided ACL/PCL tunnels |
| US9408616B2 (en) | 2014-05-12 | 2016-08-09 | Biomet Manufacturing, Llc | Humeral cut guide |
| US9561040B2 (en) | 2014-06-03 | 2017-02-07 | Biomet Manufacturing, Llc | Patient-specific glenoid depth control |
| US9839436B2 (en) | 2014-06-03 | 2017-12-12 | Biomet Manufacturing, Llc | Patient-specific glenoid depth control |
| US9826994B2 (en) | 2014-09-29 | 2017-11-28 | Biomet Manufacturing, Llc | Adjustable glenoid pin insertion guide |
| US9833245B2 (en) | 2014-09-29 | 2017-12-05 | Biomet Sports Medicine, Llc | Tibial tubercule osteotomy |
| WO2016129682A1 (en) * | 2015-02-13 | 2016-08-18 | 株式会社島津製作所 | Bone analyzing device |
| US9820868B2 (en) | 2015-03-30 | 2017-11-21 | Biomet Manufacturing, Llc | Method and apparatus for a pin apparatus |
| US10568647B2 (en) | 2015-06-25 | 2020-02-25 | Biomet Manufacturing, Llc | Patient-specific humeral guide designs |
| US10226262B2 (en) | 2015-06-25 | 2019-03-12 | Biomet Manufacturing, Llc | Patient-specific humeral guide designs |
| US10722310B2 (en) | 2017-03-13 | 2020-07-28 | Zimmer Biomet CMF and Thoracic, LLC | Virtual surgery planning system and method |
| JP2020044045A (en) * | 2018-09-18 | 2020-03-26 | オリンパス株式会社 | Ultrasonic observation apparatus, operation method of ultrasonic observation apparatus, and operation program of ultrasonic observation apparatus |
Family Cites Families (8)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| DE3687519T2 (en) * | 1985-11-11 | 1993-05-13 | Teijin Ltd | METHOD FOR ASSESSING BONES. |
| US5228068A (en) * | 1992-09-14 | 1993-07-13 | Lunar Corporation | Device and method for automated determination and analysis of bone density and vertebral morphology |
| US5577089A (en) * | 1991-02-13 | 1996-11-19 | Lunar Corporation | Device and method for analysis of bone morphology |
| DE69320418T2 (en) * | 1992-06-04 | 1999-01-07 | Teijin Ltd | Method and device for bone measurement |
| US5602935A (en) * | 1993-04-23 | 1997-02-11 | Teijin Limited | Bone morphometric method using radiation patterns along measuring lines related to a bone axis and apparatus for carrying out the same |
| US5327262A (en) * | 1993-05-24 | 1994-07-05 | Xerox Corporation | Automatic image segmentation with smoothing |
| GB2278436A (en) * | 1993-05-28 | 1994-11-30 | Kevin Hill | Image processing system and method for automatic feature extraction |
| US5452367A (en) * | 1993-11-29 | 1995-09-19 | Arch Development Corporation | Automated method and system for the segmentation of medical images |
-
1997
- 1997-03-26 CA CA002201057A patent/CA2201057C/en not_active Expired - Fee Related
- 1997-03-27 DE DE69724865T patent/DE69724865D1/en not_active Expired - Lifetime
- 1997-03-27 US US08/825,091 patent/US5835619A/en not_active Expired - Lifetime
- 1997-03-27 EP EP97105299A patent/EP0803843B1/en not_active Expired - Lifetime
- 1997-03-27 AT AT97105299T patent/ATE250252T1/en not_active IP Right Cessation
- 1997-04-01 AU AU16674/97A patent/AU713136B2/en not_active Ceased
Also Published As
| Publication number | Publication date |
|---|---|
| AU1667497A (en) | 1997-10-02 |
| EP0803843A3 (en) | 1997-11-12 |
| US5835619A (en) | 1998-11-10 |
| ATE250252T1 (en) | 2003-10-15 |
| EP0803843B1 (en) | 2003-09-17 |
| AU713136B2 (en) | 1999-11-25 |
| EP0803843A2 (en) | 1997-10-29 |
| CA2201057A1 (en) | 1997-09-29 |
| DE69724865D1 (en) | 2003-10-23 |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| CA2201057C (en) | A method of processing a sectional image of a sample bone including a cortical bone portion and a cancellous bone portion | |
| AU2002251559B2 (en) | Three-dimensional joint structure measuring method | |
| US8634629B2 (en) | Estimating risk of future bone fracture utilizing three-dimensional bone density model | |
| US6442287B1 (en) | Method and system for the computerized analysis of bone mass and structure | |
| CN1930584B (en) | System and method for filtering a medical image | |
| US6449502B1 (en) | Bone measurement method and apparatus | |
| US6609021B1 (en) | Pulmonary nodule detection using cartwheel projection analysis | |
| JP5486197B2 (en) | Vertebral center detecting device, method and program | |
| US6249590B1 (en) | Method for automatically locating image pattern in digital images | |
| JP3499761B2 (en) | Bone image processing method and bone strength evaluation method | |
| WO2007044527A1 (en) | Automatic bone detection in mri images | |
| US6839457B1 (en) | Bone measuring method | |
| US6560474B2 (en) | Method for evaluating structural strength of cancellous bone using X-ray image | |
| JP3229200B2 (en) | Bone measurement method | |
| JP3238626B2 (en) | Bone measurement method | |
| JP3258233B2 (en) | Bone measurement method | |
| Hacihaliloglu et al. | Automatic data-driven parameterization for phase-based bone localization in US using log-gabor filters | |
| JP2003265450A (en) | Medical image display method and medical image processor | |
| Boehm et al. | Using Radon transform of standard radiographs of the hip to differentiate between post-menopausal women with and without fracture of the proximal femur | |
| Khaled et al. | Osteoporosis Detection Using Combined Texture Features of Proximal Femur Radiographs | |
| Sokiranski | A new Method for Assessing the Anchorage of Custom-Made Hip Endoprostheses with CT R. Sokiranski (*), E. Klotz (**), S. Klotz (***), D. Felsenberg (*), S. Exner (***)(*) Free University of Berlin, Klinikum Steglitz, Berlin, Germany.(**) Siemens Medizintechnik, Erlangen, Germany. | |
| JPH09266905A (en) | Bone measurement method |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| EEER | Examination request | ||
| MKLA | Lapsed |
Effective date: 20150326 |
|
| MKLA | Lapsed |
Effective date: 20150326 |