Device and Method for Securely Holding Breast on Mammography Imaging System

According to one aspect of an exemplary embodiment of the disclosure, an imaging device or system, e.g., a mammography imaging system or device, includes a breast holding pad disposed on one or both of a compression paddle and a compression surface on the imaging device. The breast holding pad is formed with a central layer, a first, securing adhesive layer on one side of the central layer and a second, biocompatible adhesive layer disposed on the opposite side of the central layer. The biocompatible adhesive operates to securely hold the breast during any imaging and/or biopsy procedure performed utilizing the imaging system. Further, with the use of one or both pads, the amount of compression force required to hold the breast in a stationary position between the compression paddle and the compression surface can be reduced, thereby decreasing the discomfort to the patient during the imaging and/or biopsy procedure performed.

FIELD OF THE DISCLOSURE

The present disclosure relates generally to medical imaging systems, including mammography systems and devices, and more specifically to patient holding systems utilized with a medical imaging device.

BACKGROUND OF THE DISCLOSURE

Embodiments of the invention relate generally to X-ray medical imaging, and more particularly to devices, systems and methods employed to perform various imaging procedures, such as mammography imaging procedures including but not limited to spectral mammography (SM), such as 2D/3D dual-energy contrast-enhanced (CE) mammography exams, full-field digital mammography (FFDM) or digital breast tomosynthesis (DBT) mammography exams.

Spectral mammography (SM) is an X-ray imaging modality used to scan breasts for screening, diagnosis and/or interventional examinations. The effectiveness of spectral mammography is affected by numerous factors, one of which is the two-dimensional (2D) rendering of images obtained using SM.

Alternative systems to SM are also known for breast imaging. Some examples include full-field digital mammography, which captures the image directly onto a flat-panel detector, computed radiography, which involves the use of a cassette that contains an imaging plate), or digital breast tomosynthesis (DBT). A digital breast tomosynthesis (DBT) or mammography-tomography (mammo-tomo) system is a dedicated mammography system that acquires several (e.g., tens of) angularly offset projection X-ray images and uses the resulting X-ray image data to reconstruct three-dimensional (3D) image datasets.

The 3D image datasets are used to form various volumetric representations of the imaged breast, including an entire 3D volume of the breast, and various 3D sections of the 3D volume, such as slices or slabs constituting specified thicknesses of the 3D volume oriented to provide the desired view of one or more regions of interest (ROI) detected within the 3D image dataset.

In addition, when the 3D image datasets of the breast have been produced, after being utilized in a suitable diagnosis procedure, they can be utilized to guide a biopsy device employed with the DBT system into the breast to obtain a biopsy of the region of interest (ROI) identified within the 3D image datasets. In DBT systems, the biopsy device is disposed directly on the DBT system in order to be able to perform the biopsy utilizing the 3D image dataset to guide the biopsy device to the ROI.

With regard to the use of mammography devices, the process of obtaining high quality mammographic images from breast tissue requires a technician to position the breast of a patient between one or more paddles and/or support surfaces that compress the breast in order to immobilize and flatten it during image acquisition. The compression force applied to a breast improves image quality by reducing the thickness of the breast while spreading the breast tissue over a larger area, which facilitates interpretation of obtained imagery since the amount of overlying tissue for structures within the imaged breast is minimized.

Reduction of the breast thickness by compression is also important in managing patient radiation dosage. In general, the thicker the compressed breast, the more x-ray attenuation. Therefore, a higher x-ray dosage is necessary when imaging thicker breast tissue as compared to the dosage required for thinner tissue. While greater compression forces are desirable for obtaining clear images with lower radiation dosages, greater compression forces may contribute to patient pain or discomfort. Such patients may not schedule or may delay any future examinations due to the fear of an uncomfortable procedure, thereby possibly increasing the risk that a serious medical condition may not be detected in a timely fashion.

In many diagnostic mammography imaging devices, such that disclosed in US Patent Application Publication No. US20200060632, entitled Apparatus And Method For Mammographic Breast Compression, the entirety of which is expressly incorporated herein by reference for all purposes, the compression of the breast on the mammography imaging device is controlled by the technician using a footswitch with a binary positioning system, i.e., the footswitch is moveable between an “on” position to cause movement of the compression paddle(s) and an “off” position where the compression paddle(s) are stationary. When the footswitch is on the “on’ position, the paddle(s) is moved towards the breast under the full operational speed of the motor operably connected to the paddle(s) until contact of the paddle(s) with the breast is detected.

The contact between the paddle and the breast is detected in various manners, including the view of the technician seeing the paddle contacting and compressing the breast and/or through the use of various systems such as, for example, force sensors disposed on the paddle or other breast-contacting surface that measure the force applied to the breast to maintain the compression forces below certain predetermined thresholds. Depending on the patient, however, even compression forces below predetermined thresholds may cause pain or discomfort.

In addition, as the movement of the paddle towards the breast prior to contact with the breast is at a relatively high rate of speed, which can create unease in the patient upon viewing the fast movement of the paddle, on many occasions due to the delay in reaction by the technician controlling the movement of the paddle via the footswitch and/or the detection by force sensors of the contact of the paddle with the breast, the speed of the paddle upon contact with the breast can create compressive forces on the breast that exceed the predetermined threshold. Further, though the technician can attempt to avoid this by incrementally using the footswitch, the delay can still cause the paddle to contact the breast at a higher rate of speed than desired. Though this initial high compressive force on the breast is normally short in duration, as they are detected by the technician and/or force sensor shortly after initial contact of the paddle with the breast, with the speed of the paddle being quickly reduced or stopped, the initial contact can result in pain or discomfort to the patient.

Furthermore, either just prior to or after the paddle is moved into initial contact with the patient, the movement of the paddle is controlled in a finer manner by the technician to slowly achieve a desired compression force on the breast for optimal imaging of the breast. In performing this more closely controlled, finer movement of the paddle, the technician employs the footswitch to move the paddle, but by activating the footswitch in successive short intervals or periods of time to incrementally move the paddle towards the breast and reach the target compressive force to be exerted on the breast. In addition to, or alternatively to the footswitch, the mammography imaging device may include a fine movement adjustment knob. Rotation of the knob by the technician causes the paddle to move towards or away from the breast in a finer manner than the footswitch to more accurately position the paddle against the breast to achieve the desired compressive force on the breast.

However, even though the technician can closely control the movement of the paddle to contact the breast with the desired compressive force and attempt to minimize any unnecessary pain or discomfort to the patient, the balance between sufficiently compressing the breast and minimizing patient discomfort can result in situations where the breast moves between the paddle(s) and/or breast-contacting support surfaces during the imaging or biopsy procedure. This result is highly undesirable as it requires repositioning and recompression of the breast to perform a subsequent imaging and/or biopsy procedure.

In addition to the adjustment of the position of the paddle(s) and/or other breast-support surface(s), to accommodate and minimize discomfort from compression of the breast, other devices have been developed that are attached to the imaging device or system. In particular, U.S. Pat. Nos. 6,765,984 and 7,505,555, the entirety of which are each expressly incorporated herein by reference for all purposes, disclose a radiolucent cushion or pad that is attached to a breast support surface. In certain embodiments of the pad, the pad can be formed with an adhesive on one side of the pad, such as a double sided adhesive tape, to adhere the tape to the pad and to a backing member attached to the support surface or directly to the support surface in order to hold the pad on the compression surface. Alternatively, the '555 patent discloses that various coatings, layers or other materials can be applied to the material forming the pad, such as a gel, in order to provide the adherence to the paddle or compression/support surface. The material forming the pad itself, such as the gel, may also have any inherent tacky surface that is able to hold the pad on the compression surface.

However, as also disclosed in the '555 patent, the tacky surface is undesirable for patient contact. As such, while the pad provides an enhancement to the comfort for the breast of the patient, the pad does not provide any enhancement to the ability of the paddle and or compression surfaces including the pad to hold the breast in position on the mammography device.

Therefore, with regard to the aforementioned shortcomings of prior art imaging systems concerning the ability of those imaging systems to adequately hold the compressed breast in position during imaging and biopsy procedures, it is desirable to develop an improved device, system and method for the maintaining the position of the breast during the operation of the of the imaging system and/or biopsy system.

SUMMARY OF THE DISCLOSURE

According to one aspect of an exemplary embodiment of the present disclosure, a breast holding pad for a mammography imaging system includes a central layer and a biocompatible adhesive layer disposed on one side of the central layer.

According to still another aspect of an exemplary embodiment of the present disclosure, a mammography system includes a gantry including radiation source, a detector alignable with the radiation source and defining a compression surface, and a compression paddle moveable relative to the compression surface to secure a patient breast therebetween, a controller operably connected to the gantry to control the operation and movement of the compression paddle, radiation source and detector to generate image data, the controller including a central processing unit and interconnected database for processing the image data from the detector, a display operably connected to the controller for presenting information to a user, and a user interface operably connected to the controller to enable user input to the controller, and at least one breast holding pad disposed on the gantry to hold the compressed the breast on the gantry, wherein the at least one breast holding pad is formed of a central layer, and a biocompatible adhesive layer disposed on one side of the central layer.

According to still another aspect of an exemplary embodiment of the present disclosure, a method for holding an object to be imaged on an imaging system includes the steps of providing an imaging system including a gantry disposed movably disposed on a support surface and including a radiation source, a detector alignable with the radiation source, the detector having a compression surface on which an object to be imaged is adapted to be positioned, and a compression paddle moveable relative to the compression surface to secure the object therebetween, a controller operably connected to the gantry to control the operation and movement of the compression paddle, the radiation source and detector to generate image data in an imaging procedure performed by the imaging system, the controller including a central processing unit and interconnected database for processing the image data from the detector to create images, a display operably connected to the controller for presenting information to a user, and a user interface operably connected to the controller to enable user input to the controller, positioning at least one object holding pad on the gantry, the at least one object holding pad including a central layer and a biocompatible adhesive layer disposed on one side of the central layer, positioning the object on the compression surface between the radiation source and the detector, and operating the compression paddle to compress the object between the compression paddle and the compression surface to engage the object with the at least one object holding pad.

These and other exemplary aspects, features and advantages of the invention will be made apparent from the following detailed description taken together with the drawing figures.

DETAILED DESCRIPTION OF THE DRAWINGS

As used herein, “electrically coupled”, “electrically connected”, and “electrical communication” mean that the referenced elements are directly or indirectly connected such that an electrical current may flow from one to the other. The connection may include a direct conductive connection, i.e., without an intervening capacitive, inductive or active element, an inductive connection, a capacitive connection, and/or any other suitable electrical connection. Intervening components may be present.

Further, while the embodiments disclosed herein are described with respect to a mammography apparatus for the 2-dimensional imaging of breast tissue, it is to be understood that embodiments of the invention may be applicable to other types of imaging devices for both 2-dimensional and 3-dimensional imaging including, for example, fluoroscopy, full-filed digital mammography, digital breast tomosynthesis (DBT) and spectral mammography (single or multi-energy), as well as for imaging procedures for tissue other than breast tissue. Further still, embodiments of the invention may be used to analyze tissue, generally, and are not limited to analyzing human tissue.

Referring now toFIGS.1and2, the major components of an exemplary imaging system10formed as a mammography system12for imaging breast tissue according to an embodiment of the invention are shown. The system10, such that disclosed in US Patent Application Publication No. US20200060632, entitled Apparatus And Method For Mammographic Breast Compression, the entirety of which is expressly incorporated herein by reference for all purposes, includes a radiation source/x-ray source16, a radiation detector18, and a collimator20. The radiation source16is movable between a variety of imaging positions relative to the detector18, and is operative to emit radiation rays22(FIG.2) that are received by the radiation detector18to provide an image of an object, such as a breast52. In embodiments, the system10may include a patient shield24mounted to the radiation source16via face shield rails26to prevent the patient's head from obstructing the radiation rays and protecting the patient from the radiation rays22.

Referring still further toFIGS.1and2, the system10also includes a compression paddle or plate28and a support structure30to which one or more of the radiation source16, radiation detector18, and/or compression plate28may be mounted to. In embodiments, the system10may further include a controller32. The controller32may be a workstation having at least one processor/central processing unit/computer and a memory device/database that stores information and/or instructions for the operation of the system10that are employed by the controller32, as shown inFIG.1or, in other embodiments, the controller32may be embedded/integrated into one or more of the various components of the system10disclosed above. In embodiments, the controller32may be in electrical communication with the radiation source16, radiation detector18, and/or the compression plate28via a cable34. As will be appreciated, in embodiments, the connection34may be a wireless connection. In embodiments, the controller32may include a radiation shield36that protects an operator of the system10from the radiation rays22emitted by the radiation source16. The controller32may further include a display38, a keyboard40, mouse42, and/or other appropriate user input devices that facilitate control of the system10via a user interface44.

As further shown inFIGS.1and2, the radiation source16, along with the radiation detector18, forms part of an x-ray system which provides x-ray imagery for the purpose of imaging a body part of a patient, such as breast52. As stated above, the radiation source16emits the radiation rays22such that the radiation rays22travel from the radiation source16to the radiation detector18. While the radiation rays22are discussed herein as being x-rays, it is to be understood that the radiation source16may emit other types of electromagnetic rays which can be used to image a patient. The radiation source16may be mounted to the support structure30such that the radiation source can rotate around an axis46in relation to the radiation detector18, although movement of the radiation source16in paths other than rotation about a fixed axis, such as during digital breast tomosynthesis (DBT), are also envisioned. In embodiments, the radiation detector18may be configured to rotate or translate within its housing, such as in the directions indicated by arrows53and55.

In the illustrated exemplary embodiment ofFIG.1the radiation source16and the detector18are mounted to a gantry90that is secured to the support structure30. The support structure30houses a translation mechanism92that is operably connected to the gantry90. The translation mechanism92is operable to move the gantry90vertically with respect to the support structure30in order to position the gantry90at the appropriate height to accommodate the dimensions of the patient on which the system10is being utilized. The translation mechanism92is also operable to rotate the gantry90relative to the support structure30about the horizontal axis46in order to position the gantry90rotationally with regard to the patient, as necessary.

The gantry90includes a generally C-shaped body94with the radiation source16at one end and the detector18at the opposite end. In this configuration, regardless of the vertical and/or rotational orientation of the gantry90, such as to position the radiation source16and detector18relative to the patient breast52to obtain x-ray images at various orientations, such as for craniocaudal (CC) or mediolateral oblique (MLO) views, among others, the radiation source16is disposed in alignment with the detector18. In this position, the detector18is capable of receiving the x-rays22emitted from the radiation source16that pass through the portion of the patient, i.e., patient breast52, located between the radiation source16and the detector18in order to generate image data for transmission to the control system32of the mammography device/system10to create/reconstruct a 3D image dataset for viewing by a physician, such as by using DBT, among other known methods.

Additionally, in another embodiment the radiation source16can be attached to the gantry90to rotate and/or move independently of the gantry90and detector18in order to enable the radiation source16to take x-ray images of the patient breast at various angles relative to the detector18, e.g., between +/−60°. The images obtained between these angles for the radiation source16can be used either for creation of stereoscopic images in a biopsy procedure using the system10or for DBT when operating the system10in an imaging mode.

As stated above, the radiation detector18receives the radiation rays22emitted by the radiation source16. In embodiments, data regarding the radiation rays22received by the radiation detector18may be electrically communicated to the controller32from the radiation detector18via cable/electronic connection34such that the controller32generates one or more images which may be shown on the display38and stored in the memory device.

The compression plate28is operative, in response to instruction from the controller32or in response to instructions from controller(s) on or near the mammography system10or switch controllers80, to move towards and away from the radiation detector18as indicated by arrows/compression axis48such that the compression plate28flattens and holds a body part, e.g., breast52, in place against the surface50of the radiation detector18. In this respect, the radiation detector18and the surface50thereof is referred to herein as a “compression surface or support plate” that cooperates with the compression plate28to compress and clamp a breast of a patient therebetween.

In one exemplary embodiment, in order to maintain the position of the patient breast52stationary during the imaging and/or biopsy procedures, the compression plate28is attached to a plate or paddle support mechanism45located on and/or within the gantry90that positions the compression plate28directly over and in alignment with the detector18/support plate and operably connected to the controller32. The plate support mechanism45is operable within the gantry90at any rotational or vertical position of the gantry90to move the plate28in a line either towards or away from the detector18/support plate. The mechanism45can have any of a number of different configurations, but in one exemplary embodiment takes the form of a compression screw mechanism that is operable to move the plate28into engagement with the patient breast52to exert a predetermined pressure/compression on the breast52to retain the breast52in a stationary position between the plate28and the detector18/support plate during imaging and/or biopsy procedures.

In operation, in accordance with an embodiment, the breast52of the patient may be placed onto the compression surface50of the radiation detector18. The compression plate28, under control of the plate support mechanism45by the controller32, moves towards the detector18to compress the breast52against the surface50of the detector18such that the breast52is immobilized. Movement of the compression plate28towards the detector18to compress the breast52against the support plate/detector18defines a compression phase of the system10. Once a target compression is achieved, movement of the compression plate28is halted and the compression plate28and the support plate18are held in fixed position to clamp the breast52therebetween (referred to herein as the clamping phase) so that imaging or procedures, e.g., a biopsy, may be commenced. During an imaging procedure, the radiation source16is selectively adjusted such that it is moved/rotated to a first scanning position and scans the breast52. The radiation detector18receives the radiation rays22passing through the breast52and sends data to the controller32which then generates one or more x-ray images of the breast52. Once imaging is complete, the controller32moves the compression plate28away from the support plate18to free the breast52.

Referring still further toFIG.1, in an embodiment, the system10may include one or more physiological monitoring or sensor devices54,56,58,60communicatively coupled with the controller32for monitoring one or more physiological parameters of a patient (and for transmitting physiological parameter data to the controller32). WhileFIG.1illustrates that the sensor devices54,56,58are connected to the controller32, in some embodiments, one or more of the sensor devices may be communicatively coupled with the mammography apparatus, without departing from the broader aspects of the invention. The sensor devices may be selected to monitor and/or measure any physiological information of a patient desired, including, but not limited to, diastolic blood pressure, systolic blood pressure, body temperature, blood oxygen level, patient weight, skin conductance, pulse rate, etc. As illustrated inFIG.1, one or more of the sensor devices, e.g., sensor device60, may be physically integrated with the compression plate28and/or the detector/support plate18. By incorporating the sensor devices into the support plate18or compression plate28, physiological parameter data of the patient may be acquired and transmitted to the controller32without requiring any additional intervention by the system operator.

In an embodiment, the sensor device60may be a force sensor for measuring the amount of pressure or compressive force applied to the breast52. Additional sensors for measuring physiological parameters may be configured to either directly measure or allow the calculation of variables such as force, pressure, temperature, rigidity, elasticity, breast size and/or volume, and/or tissue density and could be embedded in compression plate28or support plate18or attached as part of mammography system10.

Referring once again toFIG.1, in an embodiment, operation of the system10during the compression phase and the clamping phase may be controlled by the patient using switch controls80, e.g., footswitch controls, such as disclosed in U.S. Pat. No. 10,004,470, which is hereby incorporated by reference herein in its entirety. Switch controls80are typically connected via a cable/wire82to mammography imaging system10. The controls are also often mirrored on the opposite side of mammography imaging system10(not shown). Other controls (not shown) may be present on particular accessories placed either in the paddle/breast support area. In an embodiment, rather than being footswitch controls, the switch controls may be a handheld control unit84with a wired, wireless, Bluetooth or other connection with the system10. In an embodiment, the patient may control the rate of compression and/or pressure or force applied during the compression phase and/or clamping phase using the switch controls. A feedback device, e.g. controller32, may be configured to give feedback information about the image to obtain and may designed such that the feedback information is operatively perceivable by the patient (e.g., through an audible or visual indication). The feedback device, e.g., controller32, may be configured to provide feedback information to the patient regarding the rate of compression (greater or lower rate of compression) and/or amount of pressure (higher or lower) required to produce an optimal image, in dependence upon the information received from the various sensor devices54,56,58,60. In this respect, the feedback device informs the patient when compression rate and/or pressure applied is sufficient to obtain a quality image, as determined from a blood pressure or other measurement taken from the patient through sensing devices54,56,58, or60, before or during the compression and/or clamping phase.

Referring now toFIG.4, the imaging system10may further, or alternatively, include a biopsy system100, such as that disclosed in which may be selectively removable from the imaging system10. In such an embodiment, the radiation source16, along with the radiation detector18, forms part of an x-ray system which provides x-ray imagery for the purpose of guiding the biopsy tool100to a suspect site within a body part of a patient. As shown inFIG.4, in embodiments, the biopsy system100, may be disposed on the support structure30such that it also rotates about the axis46, in a manner similar to the radiation source16, and/or moves in a vertical and/or horizontal direction, in a manner similar to the compression plate28.

Looking now at the exemplary illustrated embodiments ofFIGS.3-7, the mammography imaging system10, with or without the biopsy system100, includes a breast holding pad200on at least one of the compression plate28and the compression surface50. The breast holding pad200operates to frictionally grip the breast52between the compression paddle28and the compression surface50in order to securely hold the breast52therebetween during any imaging and/or biopsy procedure performed utilizing the imaging system10. Further, with the use of one or both pads200, the amount of compression force required to hold the breast52in a stationary position between the paddle28and the compression surface50can be reduced, thereby decreasing the discomfort to the patient during the imaging and/or biopsy procedure performed using the mammography imaging system10.

In the embodiment shown inFIGS.4-6, the breast holding pad200is formed with a central layer202, a first, securing or adhesive layer204on one side205of the central layer202and a second, biocompatible securing or adhesive layer206disposed on the opposite side207of the central layer202from the first adhesive layer204. The first and second adhesive layers204,206can each be covered by a release liner(s)210that protect the first and second adhesive layers204,206prior to use of the pad200and are readily removable from the first and second adhesive layers204,206when the pad200is ready for use on one of the paddle28or the compression surface50. The release liner(s)210can be formed from multiple components212(FIG.6) attached to opposed sides of one or both of the first and second securing or adhesive layers204,206, and disposed in an overlapping configuration, where one of the components212can be removed to enable one side of the first or second securing layer204,206to be affixed to the compression surface50. After affixing or securing the exposed end, the second component212can be removed to secure the opposite side of the first or second securing layer204,206to the compression surface50.

The central layer202is formed of an x-ray transparent or radiolucent material, such as those disclosed in U.S. Pat. Nos. 6,765,984 and 7,505,555, the entirety of which are each expressly incorporated herein by reference for all purposes. The central layer202can be formed of a compressible material, such as a foam or gel material, that functions as a cushion for the breast52in addition to acting to securely hold the breast52in the manner to be described. The central layer202can have any desired shape and/or configuration, and in the illustrated exemplary embodiment the pads200are each shaped to be complementary to the shape of the paddle28and the compression surface50, respectively. In an alternative embodiment, the central layer202can be formed as a thin carrier layer, with the first adhesive layer204and the second adhesive layer206applied to either side in the form of a dual sided tape. In one exemplary embodiment, the pad200has a thickness of less than 1.0 mm, and in another exemplary embodiment less than 0.50 mm, and in still a further exemplary embodiment, a thickness of less than 0.25 mm.

The first adhesive layer204applied on one side205of the central layer202is utilized to secure the pad200/central layer202to the paddle28or to the compression surface50. Further, the first adhesive layer204is selected to be at least partially formed from an adhesive that is x-ray transparent or radiolucent and that securely holds the pad200on the paddle28or compression surface50, while also leaving no residue on the paddle28or compression surface50when the pad200is removed. In an alternative embodiment, the first adhesive layer204can be omitted where the central layer202is attached to the paddle28or compression surface50in an alternative manner, such as by a mechanical securement, or where the central layer202is formed of a material having an inherent adhesive capability that can secure the central layer202directly to the paddle28or compression surface50.

Opposite the first adhesive layer204, the second adhesive layer206is applied to the other side207of the central layer202and utilized to engage and frictionally hold the breast52in a stationary position with regard to the pad200. The second adhesive layer206can optionally be the same or different than the first adhesive layer204, and optionally can be formed from a tacky but non-adhesive material, such as a silicon or silicon rubber material, and is selected to be at least partially a material or an adhesive that is x-ray transparent or radiolucent and that is biocompatible with the breast52to securely frictionally hold the breast52on the pad200in the compressed position, while also leaving no residue on the breast52when the compression applied to the breast52via the pad200is removed. The second adhesive layer206can be formed to cover the entire side of the central layer202or one or more portions thereof, in order to provide secure engagement of the second adhesive layer206with the breast52. Further, the second adhesive layer206can be formed of a high friction material that is applied to the entire side207or on selected portions of the side207, such as silicone rubber material.

In an alternative embodiment, as shown inFIG.7the pad200can be formed of a single layer208of a material that can be used to from the second adhesive layer206, but that is applied directly to one or both of the paddle28and the compression surface50. In one embodiment, the single layer208can be formed of a high friction, biocompatible material, such as a silicone rubber, that is applied in a suitable pattern on the paddle28and/or compression surface50, such as a grid or a concentric circular pattern, among others, in order to hold the breast52securely in position with regard to the paddle28and compression surface50.

In addition, while prior exemplary embodiments have disclosed that the central layer202, the securing adhesive204and the biocompatible adhesive206forming the pad200are each x-ray transparent, in alternative embodiments various portions of one or more of the central layer202, the securing adhesive204and the biocompatible adhesive206can be formed of non-x-ray translucent materials, as these portions of the central layer202, the securing adhesive204and the biocompatible adhesive206are disposed outside of the field of view of the imaging system10. For example, the securing adhesive204can be disposed on the central layer202in a pattern that lies at least partially outside of the field of view, e.g., around the perimeter of the central layer202, such that the securing adhesive204is not required to be x-ray transparent. Further, the central layer202, the securing adhesive layer204and/or the biocompatible adhesive layer206can each include portions212,214,216within the field of view that are x-ray transparent and portions218,220,222outside of the field of view that are non-x-ray transparent. In addition, in another exemplary embodiment, for use in conjunction with a biopsy device or system100, the pad200, and in particular the various layers constituting the pad200, can include one or more apertures (not shown) therein optionally in alignment with suitable openings (not shown) present in the paddle28, which allow for the biopsy needle to extend through the pad200into the breast52to perform the biopsy procedure without engaging any portion of the pad200. Thus, the pad200can securely hold the breast52in the desired position relative to the paddle28, the compression surface50and the biopsy system100without interfering with the performance of the biopsy procedure.

With regard to another exemplary embodiment of the disclosure, the pad200can be formed with a central layer/carrier202formed of plastic material, such as thermoplastic elastomer, including a polypropylene film, among others, and the first adhesive layer204and the second adhesive layer206each formed of a silicone adhesive or an acrylic adhesive, among others. Further the release liner can be formed from a coated (silicon or fluoro-silicon coated) or uncoated material, such as a polypropylene, a polyester or a paper, e.g., kraft paper, material.

It is understood that the aforementioned compositions, apparatuses and methods of this disclosure are not limited to the particular embodiments and methodology, as these may vary. It is also understood that the terminology used herein is for the purpose of describing particular exemplary embodiments only, and is not intended to limit the scope of the present disclosure which will be limited only by the appended claims.