Abstract:
A breast compression device for use with a conventional mammography system is disclosed. The device comprises a paddle support frame which is slidably connected to a conventional mammography system&#39;s compression paddle carriage. A mounting arm may be provided for attaching the paddle support frame to the mammography system. The device further comprises a compression surface having a chest wall end and a nipple end. The paddle support frame is located between the x-ray tube and the detector of the mammography system. The compression surface of the device is comprised of three angled segments which conform to the normal contours of the breast.

Description:
CLAIM OF PRIORITY 
     This application claims the benefit of U.S. Provisional Patent Application No. 60/406,564 filed Aug. 28, 2002. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to a mammography compression device, and more particularly to a compression paddle which provides a more uniform compression to a woman&#39;s breast while preventing too much compression at the chest wall and yet providing enough compression towards the nipple end of the breast. 
     2. Description of Related Art 
     Mammography systems utilize a compression paddle which is used to compress the breast of a patient intermediate a support plate and the compression paddle. Good compression of the breast is necessary for good quality mammographic images. Good compression spreads apart the breast structures which reduces superimposed structures and spreads apart the breast tissue permitting better visualization of abnormalities. 
     Good compression of the breast improves mammographic image quality in several ways. Breast thickness is decreased, reducing radiation exposure time. This can eliminate blurring of the image due to motion. Lower x-ray energy is required and this produces higher contrast images while limiting patient exposure to radiation. 
     In the most common prior art breast compression device, the compression paddle is rigidly fixed to a frame and positioned so as to have a single compression surface which parallels a breast support platform surface. These prior art compression devices used with conventional mammography systems produce non-uniform breast compression with the greatest compression closest to the chest wall and the least compression towards the nipple where the breast is not as thick. These compression paddles also unfortunately permit movement of the breast tissue in the mid breast and in the nipple end of the breast during imaging which causes blurring of the image, because of insufficient compression. Since exposure times are typically measured on the order of seconds, even though the patient may not move observably, small movement as well as the heart beating can blur images over time. Those images taken with longer exposure times, such as about two or more seconds, are particularly often adversely affected. Additionally, these prior art compression paddles can cause patient discomfort near the chest wall where the compression surface applies the greatest compression. 
     A number of other compression paddles have been developed in order to attempt to overcome some of the problems associated with the most common prior art design. 
     One prior art breast compression device has a single planar compression surface that is not used parallel to the an image detector. The apparatus comprises a compression paddle pivotally connected to a frame at a pivot point located between the chest wall end and the nipple end. The paddle may be positioned at one of a plurality of angles relative to the support surface. When the non-parallel planar surface is angled toward the nipple from the chest wall, the breast tissue can be squeezed or pushed out of the x-ray field back towards and effectively into the chest wall. The result is that tissue, which may contain a tumor is not imaged. Nevertheless, this design more effectively compresses the nipple end of the breast than the parallel planar surface. An example of this type may be seen in U.S. Pat. No. 5,706,327. 
     Another compression system is disclosed in U.S. Pat. No. 3,971,950 to Evans, Jul. 27, 1976. This patent discloses a mammographic compression and positioning device which is independent of the x-ray system. The compression surface of the paddle has a curved lower surface with both a concave and a convex surface. The position of the paddle is adjustable in a plurality of directions. These curves are not believed to optimally compress the breast as the nipple end of the breast is undercompressed due to the concave portion located above the nipple end. The chest wall end would also be undercompressed. An additional drawback would be the breast tissue at chest wall end would tend to be pushed back out of the field of view of the imager. 
     Another compression paddle system has a paddle which comes down at an angle. This was produced by Planmed of Helsinki, Finland. During the first phase of compression, the chest wall side of the upper paddle is angled toward the image detector at the start of compression. As the paddle descends and starts to compress the breast, the paddle begins to level out. At completion of the compression, the paddle is level or parallel to the image detector. Since the paddle is level at the end of the process, it is not believed to be optimally oriented to compress the breast. 
     Another known compression device for a mammography system is disclosed in U.S. Pat. No. 5,506,877. This patent discloses a compression paddle, which is pivotally connected within the support frame by a pivot connection. The pivot connection is located on a chest wall side of the support frame. The compression paddle is substantially horizontal to the detector and is rotatable around the pivot connection. During the initial compression the compression paddle begins substantially parallel to said detector. As force is applied the paddle angles toward the detector during final compression. The breast appears to dictate the angle of compression, not the radiologist in this design. Furthermore, due to the conical shape of the breast, during final compression the paddle will end up angled downwardly from the chest wall to the nipple thereby pushing the breast toward the chest wall, possibly pushing some of the breast out of an image. 
     Another known compression paddle system was produced by Trex Medical Corporation for Bennett Contour mammography systems (Trex Medical Corporation, Product Brochure, January 1997). This compression apparatus comprises a compression paddle pivotally connected to a frame at a pivot point located at the chest wall end. Rotation about the pivot point is allowed so that an operator may select the paddle angle. The paddle itself was comprised of two planar surfaces which meet at an angle of about nine degrees. The planar surface closest to the chest wall extends a length of about one inch away from the breast with the other planar surface extending from there past the nipple. 
     While the Bennett paddle achieves improved compression of the breast without significantly displacing any breast tissue backward out of the field of view at the chest wall end, this device still has a number of disadvantages. Specifically, the approximate 9° angle between the two planar surfaces is believed to be so great that it effectively forms a valley where the two angular surfaces meet. The breast located below this valley receives suboptimal compression in a zone where the largest percentage of cancers are detected. Almost one half of all breast cancers are located within the posterior one third of the breast which is where this “dead zone” occurs with the Bennett paddle. The breast is very thick in this area which in itself often makes good imaging difficult. If there is suboptimal compression here, small cancers might not be detected. A need therefore exists to optimally compress the breast within this zone to remove this potential “dead zone” from images taken. 
     Another known compression device for a mammography system is disclosed in U.S. Pat. No. 5,851,180 to Crosby et al., Dec. 22, 1998. This patent discloses an apparatus having first and second compression surfaces that experience a lateral translation as they move towards one another. In addition, the first and second compression surfaces may be tilted slightly relative to a plane orthogonal to the patient&#39;s chest wall to enhance the traction effect on the breast. 
     While significant strides have been made to provide a good compression system, a need still exists to provide an optimum paddle design. There are over twenty-five different types of breast cancer and many more abnormalities which could be confused as cancer. It only takes finding one additional cancer which would otherwise elude detection and go unnoticed to make a huge difference in the life of that one individual. 
     SUMMARY OF THE INVENTION 
     Consequently, it is a primary object of the present invention to provide a mammographic paddle which may more effectively compress the mid breast and breast tissue toward the nipple end, while preventing slippage of breast tissue from the field of view of the detector towards the chest wall end. 
     It is another object of the invention to provide a device which provides more uniform compression for the entire breast. 
     Another object of the invention is to provide a compression paddle which provides a relatively uniform compression on breasts for a large percentage of the population. 
     Another object of the invention is to provide improved image quality and less patient discomfort. 
     Another object of the invention is to provide higher contrast images with better x-ray penetration and spreading apart of breast tissue thereby resulting in fewer superimposed structures and more lesion detections. 
     Another object of the invention is to increase patient comfort. 
     Yet another object of the present invention is to reduce the amount of radiation exposure to a patient. 
     Yet another object of the present invention is to reduce the number of additional problem solving views needed. 
     Accordingly, the present invention provides a paddle that has a compression surface, preferably none of which is parallel with the image detector, the compression surface comprising three angled planar segments which are believed to conform to the normal contours of the breast for a large percentage of the population. 
     Two of the angled segments are located near the chest wall end. A main object of these angled segments near the chest wall end, is to make initial compression contact with a breast pushing the imaged tissue downward out and forward toward the nipple end of a breast so that it will be included in the scope of the detection device at the chest wall end. The two slightly angled segments located near the chest wall end more effectively push the imaged tissue downward and outward toward the nipple end of the breast than one larger angled segment. The chest wall lip portion of this inventive device is essentially perpendicular to the image detector and the compression paddle of this inventive device is horizontally adjustable within a support frame. 
     Accordingly, a mammographic paddle is disclosed having three planar sections. A first planar section proximate to the chest wall preferably has a downward tilt of about 2° relative to a horizontal or about 92° from the chest wall lip of the paddle. The first planar segment extends about ¾ of an inch. The second planar segment is preferably angled about 2° relative to the first segment and extends for about half an inch. The remaining third segment preferably extends to the lip of the nipple end of the paddle. Accordingly, the third segment has a slope of about 6° relative to the chest wall lip of the paddle. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The particular features and advantages of the invention as well as other objects will become apparent from the following description taken in connection with the accompanying drawings in which: 
         FIG. 1  is a side plan view of the preferred embodiment of the mammographic paddle of the present invention; 
         FIG. 2  is a top plan view of the paddle of  FIG. 1 ; 
         FIG. 3  is a cut away side view of a breast with the paddle compressing the breast for imaging; 
         FIG. 4  is a prior art paddle illustrated compressing a breast; 
         FIG. 5  is a first alternatively preferred embodiment of a paddle; and 
         FIG. 6  is a second alternatively preferred embodiment of a paddle. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Accordingly, a compression system  10  of the preferred embodiment is illustrated in  FIG. 1 . The compression system includes a paddle  12  connected to a frame  14 . This frame  14  is adjustable vertically relative to a support plate  16 . An image detector (not shown) is typically located immediately below the support plate  16  or comprises a portion of the support plate  16 . The compression system  10  shown in  FIG. 1  shows a minimal number of components. Additional components known in the art and are shown in some of the references cited and are helpful in automating the compression system  10 . 
       FIG. 2  shows a top view of the paddle  12 . The paddle  12  is connected to frame  14 . Referring back to  FIG. 1 , the frame  14  is also vertically adjustable relative to guide  24  to selectively adjust the vertical position of the paddle  12  relative to the support plate  16 . This way a breast  36  as shown in  FIG. 3  may be compressed intermediate the paddle  12  and the support plate  16 . 
     The paddle  12  is illustrated with three compression surfaces  26 , 28 , 30 . Each of the compression surfaces  26 , 28 , 30  is planar. Preferably, the compression surfaces  26 , 28 , 30  are part of a molded piece of plastic which comprises the entire paddle  12 . 
     The first compression surface  26  is preferably angled between about 90° to about 94° or 95°, and more preferably at about 92° relative to the lip  32 . The lip  32  is preferably planar and placed against the chest wall of a patient above a breast. The first compression surface  26  preferably extends about an inch and preferably about ¾ of an inch away from the lip  32  and the chest end of the paddle  12 . Accordingly, the lip  32  extends substantially perpendicularly to the support plate  16  which is usually positioned in a horizontal position such as parallel to the ground. The first compression surface  26  is preferably angled at about a 2° down angle relative to a parallel to the support plate  16  and/or a horizontal plane. 
     The second compression surface  28  is preferably an downwardly angled at about 2° relative to a plane extending through the first compression surface  26 . Accordingly, there is an about 178° angle intermediate the first and second compression surfaces  26 , 28 . Similarly, the third compression surface  30  is angled at about a 2° downward angle relative to a plane extending to the second compression surface  28 . Accordingly, there is about a 178° angle intermediate the second and third compression surfaces  28 , 30 . The second compression  28  surface is preferably on the order of about less than an inch and preferably about half an inch in length. These are small downward angles, i.e., less than 5° downward angles and preferably about 2°, relative to the respective planes. Four degrees and three degrees may be appropriate in other embodiments, but about two degrees has been found optimal in the preferred embodiment. The small downward angles are not present in the prior art and are believed to assist in optimally compressing the breast immediately beneath them, eliminating dead zones immediately beneath them while adequately compressing the mid breast and the nipple end. 
     As can be seen, the second compression surface  28  is angled at about a 4° down angle relative to a perpendicular through lip  32 . The third compression surface is at about 6° downward angle relative to the perpendicular taken through the lip  32 . Slots  21 , 23  in the paddle  12  allow for linear horizontal movement of the paddle  12  relative to frame  14 . This provides for optimal alignment of the paddle  12  relative to the image detector and breast support plate  16  with a properly located compressed breast, intermediate the two. In the preferred embodiment, about ⅜ inch linear adjustment is provided through the use of slots  21 , 23  relative to pins  18 , 20 . 
     It is preferable that the paddle  12  be fixed so that relative to the frame  14  so that the chest wall is substantially parallel to the lip  32 , i.e., the lip  32  is substantially perpendicular to the horizontal and/or the support plate  16 . Screws illustrated as pins  18 , 20  hold the paddle  12  relative to frame  14 . Accordingly, the first compression surface  26  will have about a 2° down angle, the second compression surface  28  will have about a 4° down angle and the third compression surface  30  will have about a 6° down angle. 
       FIG. 4  shows the use of a prior art Bennett paddle. The paddle  100  has two compression surfaces, the first compression surface  102  and a second compression surface  104 . The first compression surface  102  is approximately perpendicular to the lip  106  of the paddle. The second compression surface  104  compresses the nipple end  110  of the breast  112  in a satisfactory manner in this design. However, since the majority of breast cancers occur in the zone  114  or  40  shown, i.e., the approximately posterior ½ of the breast. It is particularly important to image this zone, or area as clearly as possible. The known prior art of  FIG. 4  has a dead zone in this area. 
     The first and second compression surfaces  102 , 104  meet at an angle of 8°–10° in the Bennett paddle  100 . This angular displacement is believed to be so great that it creates a dead zone  116  shown within the common cancer zone  114  or  40  where breast compression is incomplete. Since some cancers could be as small as two tiny dots of calcium on an image, it could be possible to miss these two dots within the dead zone  116  even though the remainder of the breast  112  were adequately imaged. Accordingly, a need exists to improve over this prior art design. 
       FIG. 3  shows the preferred embodiment of the compression system  10  in operation. The slight downward angle of the first compression surface  26  is believed to adequately compress the breast  36  at the chest end  38  of the breast  36  without any significant backward displacement of breast tissue. This slight angle is relative to a horizontal plane extending through first compression surface  26 . 
     The preferred downward angle of the second compression surface  28  relative to the first compression surface  26  is less than 5° and preferably about 2° so that the angle intermediate the first and second compression surfaces  26 , 28  is about 178°. The second compression surface  28  is preferably located entirely in the zone  40  or  114  where the highest percentage of cancers have been detected in women. At the end of the second compression surface  28 , the third compression surface  30  begins and extends to the lip or nipple end of the paddle. Once again, the third compression surface  30  is angled at less than 5° and preferably at about 2° relative to a plane extending through the second compression surface  28 . Accordingly, the second and third compression surfaces  28 , 30  meet at an angle of about 178°. 
     The use of the small or slight angles of downward displacement of the successive compression surfaces  26 , 28 , 30  has been found to optimally compress all portions of the breast. 
       FIG. 5  shows an alternative embodiment of a compression system  200 . The paddle  202  has slightly different construction than the preferred embodiment. The first compression surface  204  is a concave portion which meets a second compression surface  206  at transition point  208 , illustrated. The concave portion of first compression surface  204  preferably has a radius of about 5 inches, however, parabolic curves or other curved shapes may be utilized in other embodiments. The first compression surface  204  begins at the lip  210  or chest wall and extends no more than 2 inches from the chest wall or lip  210 , and preferably about an inch and a half, about an inch or even a half inch from the lip  210 . A plane along the second compression surface preferably forms an angle with the lip  210  between about 90 to about 98 degrees. 
     The second alternatively preferred embodiment of a paddle  300  is illustrated in  FIG. 6 . In this embodiment, a first planar compression surface  302  is illustrated connected to a second concave compression surface  304  which is connected to a third planar compression surface  306 . The first planar compression surface  302  is adjacent to lip  308 . The principal difference between this embodiment and the preferred embodiment is that the second compression surface  304  is not planar this embodiment but instead is curved such as a curve having a radius of approximately 5 inches. Of course, the radial curvature need not be constant across the compression surface  304  as it could be parabolic or some other form of curved shape. 
     Numerous alterations of the structure herein disclosed will suggest themselves to those skilled in the art. However, it is to be understood that the present disclosure relates to the preferred embodiment of the invention which is for purposes of illustration only and not to be construed as a limitation of the invention. All such modifications which do not depart from the spirit of the invention are intended to be included within the scope of the appended claims.