JP2011512986A - Method and configuration for mobile imaging system - Google Patents

Abstract

An object of the present invention is to enable easy placement at any position and reduce interference with a doctor or patient.
The support assembly includes an offset arm pivotally coupled from a carriage about a first axis. An elbow is pivotally coupled at the offset arm about the second axis. The first and second axes are vertically aligned and spaced apart from each other by a fixed offset distance. A movable arm supports the image detector. The movable arm is pivotally coupled at the elbow about a third axis that is horizontally aligned and aligned with the central longitudinal axis of the table in the vertical plane. The movable arm is also horizontally aligned and supported to rotate about a fourth axis that is aligned perpendicular to the third axis. The first, second, third and fourth axes all contain a common intersection with each other.
[Selection] Figure 1

Description

  The subject matter of this document relates generally to image acquisition, and more specifically to methods and configurations for mobile imaging machines or imaging systems. This mobile imaging machine or imaging system may be configured for medical diagnostic imaging or industrial imaging.

  Medical diagnostic imaging systems include various imaging modalities such as X-ray systems, computed tomography (CT) systems, ultrasound systems, electron beam tomography (EBT) systems, and magnetic resonance (MR) systems. Is included. A medical diagnostic imaging system forms an image of an object, such as a patient, for example, through exposure with an energy source, such as x-rays that pass through the patient. The formed image can be used for many purposes. For example, a target internal defect can be detected. In addition, changes in internal structure or alignment can be determined. It can also represent the flow of fluid within the subject. Furthermore, the image can indicate the presence or absence of the subject in the patient. Information obtained from medical diagnostic imaging can be applied in many fields, including medicine and manufacturing.

  One conventional medical diagnostic imaging system includes a movable C-arm system. The mobile C-arm system can be used, for example, in general surgery, vascular procedures, and cardiac procedures. A conventional movable C-arm system is equipped with a radiation source or a transmitter provided in a relationship opposite to a radiation detector (for example, an image intensifier), and the C-arm system is mounted on a table top. It is moved with respect to the placed object or patient. With the patient positioned between the radiation source and the detector, the C-arm system is moved or rotated so that the radiation passes through the object to be imaged from various directions. As the radiation passes through the patient, the anatomy produces a variable attenuation of the passed radiation that is received at the detector. The detector converts the attenuated radiation into an image used for diagnostic evaluation. In a typical medical procedure centered on such a diagnostic imaging system, a large number of doctors, nurses and technicians are placed in close proximity to the object to be imaged.

  There is a need for a medical diagnostic imaging system that has increased mobility and reduced interference with a physician or patient so that it can be easily placed anywhere in a dense work environment.

  The need described above is addressed by the embodiments described herein in the following description.

  In one embodiment, a support assembly is provided that movably supports a collaborative radiation source and detector for acquiring a radiographic image of a subject placed on a table. The table is defined by a central longitudinal axis. The support assembly includes an offset arm that is pivotally coupled from a movable carriage about a first axis that is generally vertically aligned. An elbow is pivotally coupled to the offset arm about the second axis. The first and second axes are each generally vertically aligned and spaced from each other at an offset distance. A movable arm is mounted to support the radiation source and detector. The movable arm is pivotally coupled to the elbow about a third axis that is generally horizontally aligned and generally aligned with the central longitudinal axis of the table in the vertical plane. The movable arm is also supported for rotation about a fourth axis that is generally horizontally aligned and generally vertically aligned with the third axis. The first axis, the second axis, the third axis, and the fourth axis all include a common intersection with each other.

  In another embodiment, a configuration operable to acquire a diagnostic image of a subject is provided. This configuration includes a table for accommodating a subject to be imaged, a carriage, an offset arm, and an elbow. The table is defined by a central longitudinal axis. The carriage is operable to move relative to the table. The offset arm includes a first end located opposite the second end. The first end of the offset arm is pivotally supported on the carriage about a first axis that is generally vertically aligned. The elbow is pivotally supported at the second end of the offset arm about a second axis that is generally vertically aligned and spaced an offset distance from the first axis. Yes. The arrangement further includes a radiation source configured to communicate with the radiation detector to obtain a diagnostic image, and a movable arm that supports the radiation source and the radiation detector. The movable arm is pivotally supported from the elbow around a third axis that is generally horizontally aligned above the central longitudinal axis of the table in the vertical plane. The movable arm is also slidably supported for rotation about a fourth axis that is generally horizontally aligned and perpendicular to the third axis. The first axis, the third axis, and the fourth axis all include a common intersection with each other.

  In yet another embodiment, a method for delivering radiation from a radiation source through a table to a radiation detector is provided. The method includes sliding the carriage in a linear direction along a rail positioned fixedly upward in the vertical direction with respect to the table, and moving the first end of the offset arm with respect to the carriage about the first axis. An elbow with respect to the second end of the offset arm around a second axis that is pivoted and generally vertically aligned and spaced apart from the first axis by a horizontal offset distance Pivoting the movable arm with respect to the elbow around a third axis that is generally horizontally aligned and generally aligned with the central longitudinal axis of the table in the vertical plane; and Rotating the movable arm with respect to the elbow around a fourth axis that is generally horizontally aligned and generally perpendicular to the third axis; Includes operation and for transmitting radiation toward the radiation source located at the free end of the radiation detector.

  This document describes a range of configurations. In addition to the aspects and advantages described in this summary, further aspects and advantages will become apparent by reference to the drawings and the following detailed description.

It is an elevational schematic diagram showing an embodiment of the configuration of an imaging system in combination with a table that supports an object to be imaged. It is the schematic diagram seen along line 2-2 of FIG. FIG. 2 is a schematic top view showing a movable arm that is offset laterally from the table and aligned with respect to the imaging system shown in FIG. 1. FIG. 2 is a schematic top view showing movable arms aligned perpendicular to a table for the imaging system shown in FIG. 1. It is a top surface schematic diagram which shows another embodiment of an imaging system regarding the table which supports a to-be-imaged body. FIG. 6 is a schematic top view showing a movable arm aligned in parallel with a table in the imaging system shown in FIG. 5. FIG. 6 is a top schematic view showing movable arms that are aligned perpendicular to the table for the imaging system shown in FIG. 5.

  In the following detailed description, references are made to the accompanying drawings that form a part hereof, and in which are shown by way of illustration specific embodiments that may be practiced. These embodiments have been described in sufficient detail to enable those skilled in the art to practice the embodiments, other embodiments may be utilized, and without departing from the scope of the embodiments It should be understood that logical, mechanical, electrical and other modifications can be made. The following detailed description is, therefore, not to be construed in a limiting sense.

  FIG. 1 illustrates one embodiment of an arrangement 100 that includes an imaging system 105 that is operable to acquire a radiographic image of an object 110 disposed on a table 115. The imaged object 110 is typically a patient or some part of a patient. The imaging system 105 can be operated remotely, for example, so that an operator can be shielded from radiation. Alternatively, the imaging system 105 may be placed in an examination room or operating room so that medical personnel can view images while performing medical procedures on the imaged object 110.

  The table 115 generally includes a table top 120 that is supported from a platform 125 that is independent of the imaging system 105. The table top 120 is generally configured to accommodate the imaging target 110 along a central longitudinal axis 128 (see FIGS. 2 to 4). The table 115 may be fixed or movable. In addition, the table 115 may be a variety of conventional forward / backward mechanisms operable to move the table top 120 and the imaged object 110 to a desired lift / down position, tilt position, and / or forward / backward position. , A vertical movement mechanism, and / or a tilting mechanism may be included. Accordingly, the table 115 communicates with the imaging system 105 to communicate the control of the table 115 and the arrangement with respect to the imaging system 105.

  With continued reference to FIG. 1, the illustrated imaging system 105 is a mobile X-ray imaging system that operates to detect diagnostic images and process them for interpretation after passing X-rays through the patient. Is possible. However, the type of imaging system 105 (eg, magnetic resonance imaging, radiation, etc.) may vary. The illustrated imaging system 105 generally includes a radiation source 130 and a radiation detector or receiver 135. The exemplary radiation source 130 generates x-ray photons, which are preferably irradiated to pass through a collimator to form an x-ray beam. The x-ray beam has an axis 138 that is substantially aligned with the center of the active area of the detector 135. The x-ray beam has a vector defined by the x-ray beam axis in the direction of the detector 135. Although the illustrated radiation source 130 is operable to generate x-rays, the type of radiation source 130 and each detector 135 may vary.

  The imaging system 105 further includes a support assembly 140 that movably supports the radiation source 130 and the detector 135 with respect to the imaged object 110 mounted on the table 115. Support assembly 140 includes a movable arm 145 supported by elbow 150 from movable carriage system 155. The illustrated movable arm 145 is a C-arm having a pair of opposing free ends 160 and 165. The radiation source 130 is connected to the first free end 160, and the radiation detector 135 is opposed to the second free end 165 so as to receive the attenuated radiation that has passed through the imaging object 110 positioned therebetween. It is connected. However, the shape of the movable arm 145 may be a curve or may have a ridge angle, and is not limited.

  With continued reference to FIG. 1, a collar assembly or trolley assembly 170 is configured to slidably receive a movable arm 145 through the collar assembly 170, and the movable arm 145 is generally The rotating shaft 175 (see FIG. 2) that is horizontally aligned with the central longitudinal axis 128 of the table top 120 is vertically rotatable. An electric driver 180 is configured to move the movable arm 145 through the collar assembly 170 about the axis of rotation 175 in a sliding relationship.

  The elbow 150 is connected by pivotally supporting the collar assembly 170 and the movable arm 145. The illustrated elbow 150 is generally L-shaped and includes an upper free end 185 and a lower free end 190. The lower free end 190 of the elbow 150 is connected to the collar assembly 170 and the movable arm 145 in a rotational manner so as to rotate about the rotation axis 195. The axis of rotation 195 is generally horizontally aligned and is aligned vertically to the axis of rotation 175 of the movable arm 145 with respect to the collar assembly 170. The axis of rotation 195 is also aligned generally parallel to the central longitudinal axis 128 of the table top 120 (see FIGS. 2-4). Although the illustrated elbow 150 is L-shaped, the shape of the elbow 150 may vary. The electric driver 200 is generally operable to rotate the movable arm 145 and the collar assembly 170 about the elbow 150 about the rotation axis 195. The support assembly 140 is configured such that the rotational axis 175 intersects the rotational axis 195 of the movable arm 145 at the intersection 205, which is also referred to herein as the isocenter 205.

  As shown in more detail in FIG. 1, the movable carriage system 155 is generally operable to move the collar assembly 170 and the movable arm 145 in a linear direction 212 along the rail support structure 215. A carriage 210 is included. The illustrated rail support structure 215 includes a pair of parallel aligned rails 220 secured to an aerial (eg, ceiling 225) and configured to receive the carriage 210 therebetween. The rail support structure 215 generally defines a central longitudinal axis 230 in parallel with the linear travel direction 212 of the carriage 210. The central longitudinal axis 230 of the rail support structure 215 is generally located above the rotational axis 195 of the movable arm 145 and the central longitudinal axis 128 of the table top 120 in the vertical direction. Further, the central longitudinal axis 230 of the rail support structure 215 is located between the central longitudinal axis 230 of the rail support structure 215, the rotation axis 195 of the movable arm 145, and the central longitudinal axis 128 of the table top 120 as viewed from above. Are aligned so that there is no offset.

  An offset arm 240 is connected to the elbow 150 and the movable arm 145 from the movable carriage system 155 in a rotational manner. An electric swivel driver 245 is connected to rotate the offset arm 240 relative to the carriage 210 about the first axis 250. An elbow driver 255 is connected to rotate the elbow 150 about the offset arm 240 about the second axis 260. The first and second shafts 250 and 260 are parallel to each other and both are aligned vertically, and are spaced apart from each other in a generally horizontal direction when viewed from above. Or offset. A central longitudinal axis 262 of the offset arm 240 is generally linearly aligned and extends through the first and second axes 250 and 260.

  When viewed from the top, as shown in FIG. 2, the illustrated offset arm 240 has opposing curved free ends 265 and 270 and a pair of opposing generally linear sides 275 and 280 extending therebetween. Including. As shown in FIG. 3, the overall diameter 282 of the curved free ends 265 and 270 is larger than the width 284 of the linear sides 275 and 280 and forms an overall 8-shape. When viewed from the side elevation as in FIG. 1, the free ends 265 and 270 of the offset arm 240 and the sides 275 and 280 of the offset arm 240 are rounded or curved in the overall vertical direction. This configuration of the offset arm 240 provides improved operability and an aesthetically appealing appearance.

  The description of the construction of the embodiment of the configuration 100 of the imaging system 105 and the table 115 has been generally given above, and the configuration 100 for acquiring the medical diagnostic image of the subject 110 arranged on the table 115 will be described below. A general explanation of the operation of

  First, assume that the support assembly 140 of the imaging system 105 is in an exemplary parked or zero position as shown in FIGS. In this stop position, the central longitudinal axis 230 of the offset arm 240 and the rotational axis 195 of the movable arm 145 are aligned in parallel with the central longitudinal axis 128 of the table top 120. The first axis 250, which is the center when the offset arm 240 rotates with respect to the carriage 210, intersects at the isocenter 205 of the support assembly 140. The support assembly 140 is operable to move the movable arm 145 and the mounted radiation source 130 and detector 135 in a linear direction 212 with respect to the central longitudinal axis 128 of the table top 120. The pivot driver 245 is operable to rotate the offset arm 240 relative to the carriage 210 about the first axis 250 in such a manner that the first axis 250 always intersects the isocenter 205 of the support assembly 140. is there. Accordingly, as shown in FIGS. 2 and 4 as viewed from the top, the movable arm 145 and the mounted radiation source 130 and detector 135 (see FIG. 1) are isocentered 205 (see FIG. 1). Can be rotated around the first axis 250 and / or the rotation axis 195 while keeping the point of interest on the object 110 to be imaged.

  As shown in FIG. 3, the pivot driver 245 (see FIG. 1) is operable to rotate the offset arm 240 about the first axis 250 relative to the carriage 210 and the movable arm 145 is It is possible to arrange the table 115 and the image pickup object 110 to be offset in the lateral direction. The elbow 150 also relates to the offset arm 240 about the second axis 260 so as to align the rotational axis 195 of the movable arm 145 parallel to the longitudinal axis 128 of the table top 210 in a desired manner. Can rotate. As is apparent from FIG. 3, movement of the movable arm 145 and the mounted radiation source 130 and detector 135 (see FIG. 1) to a position offset laterally from the table 115 may be a clinician or internal medicine. A doctor (for example, anesthesiologist) is strengthened from approaching the head of the imaging object 110 from above during a medical procedure in a desired manner.

  FIG. 4 is a top view of the movable arm 145 rotated by the elbow driver about the first axis 250 until the axis of rotation 195 is aligned generally perpendicular to the central longitudinal axis 128 of the table top 120. Indicates. Due to this rotation of the movable arm 145, the axis 138 (see FIG. 1) extending between the radiation source 130 and the detector 135 (see FIG. 1) is in vertical alignment with the first axis 250. Keep. Movement of the movable arm 145 in the linear direction 212 causes the radiation source 130 and the detector 135 to allow the clinician or physician to approach the head of the imaged object 110 while the subject 110 from head to toe. Operable to capture a radiographic image of In an inverted manner, the imaging system 105 can easily return to the parked position shown in FIGS.

  3 and 4 show that the movement of the movable arm 145 is offset laterally with respect to the table top 120 of the table 115 and the right side of the imaging target 110, the movable arm 145 is It should be understood that the table top plate 210 and the object to be imaged 110 can be moved to the opposite laterally offset positions in a similar manner.

  5-7 illustrate another configuration 300 that includes an imaging system 305 operable to capture a diagnostic image of a subject 310 mounted on a table 315, similar to configuration 100 described above. An embodiment is shown. Referring to FIG. 5 in detail, the imaging system 305 includes a support assembly 340 that supports a movable arm 345 by an elbow 350 and an offset arm 440 from a carriage 410 that is movable along a ceiling mounted rail support structure 415. The construction and operation are similar to the movable arm 145, elbow 150, rail support structure 215, and offset arm 240 of the support assembly 140 described above. The offset arm 440 is connected to rotate about the carriage 410 about the first axis 450 and the elbow 350 is connected to rotate about the offset arm 440 about the second axis 460. The first and second axes 450 and 460 are each generally vertically aligned and are spaced apart by a fixed distance (indicated by an arrow and reference number 465), offset arms passing through these axes. A central longitudinal axis 470 of 440 is generally defined.

  With continued reference to FIG. 5, the rail support structure 415 of the support assembly 340 is spaced apart from the table top plate 495 of the table 315 by a clearance distance 490 in the horizontal direction when viewed from above. Accordingly, any part of the support assembly 340, including the movable arm 345, elbow 350, rail support structure 415, and carriage 410 supported by the support assembly 340, and any part of the offset arm 440 may be the table 315. It is not located above the image pickup object 310 placed on the camera. With this configuration, the approach of a clinician or physician (for example, anesthesiologist) from above the head of the imaging target 310 can be enhanced. In addition, the position of the rail support structure 415 of the support assembly 340 is offset, reducing the possibility of interference with the ability of the treatment room illumination system to properly illuminate the region of interest of the imaged object 310. In addition, because the position of the rail support structure 415 of the support assembly 340 is offset, the conventional manner relative to the imaged object 310 to maintain a boost zone that enhances the sterilization environment for the region of interest of the imaged object 310 Reducing the possibility of interference with the air flow typically provided.

  FIG. 6 is a top view illustrating rotation of the offset arm 440 until it is aligned generally perpendicular to the central longitudinal axis 500 of the rail support structure 415. In this rotated position, the linear movement direction (indicated by the arrow and reference numeral 502) of the carriage 410 along the central longitudinal axis 500 of the rail support structure 415 is a constant distance 505 from the central longitudinal axis 510 of the table top 315. Are spaced apart. The distance 505 is approximately equal to the offset distance 465 between the first axis 450 and the second axis 460, respectively, which are generally vertically aligned. Accordingly, the table top 495 of the table 315 when the central longitudinal axis 470 of the offset arm 440 is aligned generally perpendicular to the central longitudinal axis 500 of the rail support structure 315 and the linear movement direction 502 of the carriage 410. The central longitudinal axis 510 of the imaging system 305 extends through the isocenter 512 of the imaging system 305 and the generally vertical rotation axis 460 of rotation of the elbow 350 about the offset arm 440.

  6 shows that the central longitudinal axis 500 of the rail support structure 415 is offset from the central longitudinal axis 510 of the table 315 in one direction (eg, the left side of the subject 310). It is understood that the axis 500 may also be offset in the opposite direction from the central longitudinal axis 510 of the table 315, which is also encompassed herein.

  FIG. 7 shows a top view when the movable arm 345 rotates about the elbow 350 about the second axis 460. The generally vertically aligned rotational axis 460 of the elbow 350 with respect to the offset arm 440 is a generally horizontal distance 515 from the rotational axis 480 of the movable arm 345 with respect to the isocenter 512 and the collar 170 (see FIG. 1). Are spaced apart. The generally horizontal distance 515 is approximately equal to the distance 505 such that the central longitudinal axis 510 of the table top 495 is generally aligned with the rotational axis 480 of the movable arm 345 relative to the collar 170 (see FIG. 1). It has become. Accordingly, the configuration 300 enables the table top plate 495 and / or the carriage 410 to move relative to each other in the linear direction 502 so as to easily acquire a radiation image from the head of the imaging target 310 to the toe. The above-described subject matter is desirable when, for example, a radiation dye is passed through the circulation system of the imaging target system 310.

  In operation, it is first assumed that the support assembly 340 is located in the parked or zero position shown in FIG. 5, in which the generally horizontal axis of rotation 480 of the movable arm 345 with respect to the collar assembly 170. (See FIG. 6) is aligned perpendicular to the central longitudinal axis 500 of the rail support structure 475. The movable arm 345 and the rail support structure 415 are laterally offset from the table top plate 490 by a distance 505 on one side. In this stop position shown in FIG. 5, none of the movable arm 345 and the rail support structure 415 of the support assembly 340 are aligned above the table top 490 and the imaging target 310 in the vertical direction. Accordingly, the ceiling-mounted support assembly 340 enhances the clearance for the approach from above the image pickup object 310 and the approach of the doctor, and is applied to the table 315 and the image pickup object 310 in a desired manner. This reduces the possibility of interference with the above-described air laminar flow and the boost zone. As shown in FIG. 6, the carriage 410 is rotated by rotating the offset arm 440 until it is aligned generally perpendicular to the central longitudinal axis 500 of the rail support structure 415 and the central longitudinal axis 510 of the table top 495. And / or movement of the table top 495 in the linear direction 502 may allow the isocenter 512 of the imaging system 305 to maintain an overall continuous alignment with the central longitudinal axis 510 of the table top 495 when viewed from above. And facilitates easy reference and acquisition of radiographic images from the imaged object 310 while allowing enhanced access to both sides of the imaged object 310. Referring now to FIG. 7, the rotation of the movable arm 345 relative to the offset arm 440 about the second axis 460 causes movement of the carriage 410 and / or movement of the table top 495 in the linear direction 502 to The isocenter 512 allows the overall continuous alignment with the central longitudinal axis 510 of the table top 495 to be maintained in this case as well, so that the clinician at the head end along the right side of the imaged object 310. Alternatively, it is possible to easily capture a radiographic image of the subject 310 from the head to the toe while allowing the physician close access. In an inverted manner, the imaging system 305 can easily return from any position shown in FIGS. 6 and 7 to the parked position shown in FIG.

  This written description uses examples to disclose the invention, including the best mode, and to enable any person skilled in the art to make and use the invention. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Where such other examples have structural elements that do not differ from the written language of the claims, or include equivalent structural elements that have insubstantial differences from the written language of the claims, It is intended to be within the scope of the claims.

DESCRIPTION OF SYMBOLS 100 Configuration 105 Imaging system 110 Imaged object 115 Table 120 Table top plate 125 units 128 Central longitudinal axis 130 Radiation source 135 Radiation detector 138 Axis 140 Support assembly 145 Movable arm 150 Elbow 155 Movable carriage system 160, 165 Free End 170 Color assembly 175 Rotating shaft 180 Electric driver 185 Upper free end 190 Lower free end 195 Rotating shaft 200 Electric driver 205 Intersection 210 Carriage 212 Linear direction 215 Rail support structure 220 Rail 225 Ceiling 230 Center longitudinal axis 240 Offset Arm 245 Electric swing drive 250 First shaft 255 Elbow drive 260 Second shaft 262 Central longitudinal axis 265, 270 Curved free end 275, 280 side Surface 282 Curved free end diameter 284 Side width 300 Configuration 305 Imaging system 310 Subject 315 Table 340 Support assembly 345 Movable arm 350 Elbow 410 Carriage 415 Ceiling-mounted rail support structure 440 Offset arm 450 First axis 460 Second axis 465 Distance between first axis and second axis 470 Central longitudinal axis 480 Rotating axis of movable arm 485
490 Clearance distance 495 Table top plate 500 Central longitudinal axis 502 Linear movement direction of carriage 505 Distance from central longitudinal axis of table top plate 510 Central longitudinal axis 512 Isocenter 515 Horizontal distance

Claims (20)

A support assembly that movably supports a cooperating radiation source and detector for acquiring a radiographic image of a subject disposed on a table having a central longitudinal axis;
An offset arm pivotally coupled from a movable carriage about a first axis that is generally vertically aligned;
An elbow pivotally coupled at the offset arm about a second axis that is generally vertically aligned and spaced an offset distance from the first axis;
A movable arm that supports the radiation detector in opposition to the radiation detector and is generally horizontally aligned and aligned generally parallel to the central longitudinal axis of the table in a vertical plane; A fourth axis that is pivotally coupled at the elbow about a third axis and that is generally horizontally aligned and generally vertically aligned with respect to the third axis. A movable arm supported to rotate about an axis, wherein the first axis, the third axis, and the fourth axis all include a common intersection with each other. Out,
Support assembly.   The assembly of claim 1, wherein the movable carriage is movable in a linear direction along a central longitudinal axis of a fixed rail structure located higher than the table.   The assembly of claim 2, wherein the central longitudinal axis of the fixed rail structure is generally aligned with the central longitudinal axis of the table in a vertical plane.   The assembly of claim 2, wherein the central longitudinal axis of the fixed rail structure is spaced an offset distance in a generally horizontal plane from the central longitudinal axis of the table.   The assembly according to claim 4, wherein no part of the fixed rail structure is aligned above any part of the table in the vertical direction.   The assembly of claim 1, further comprising an electric driver operable to drive rotation of the elbow and movable arm with respect to the offset arm about the second axis.   The assembly of claim 1, further comprising an electric driver operable to drive rotation of the offset arm and movable arm with respect to the carriage about the first axis.   The assembly of claim 1, wherein the offset arm includes opposed generally curvilinear ends, with generally linear sides extending therebetween.   The assembly of claim 1, wherein a central longitudinal axis of the offset arm is generally linearly aligned between the first axis and the second axis. A configuration operable to acquire a diagnostic image of a subject,
A table having a central longitudinal axis and containing the imaged target;
A carriage operable to move relative to the table;
An offset arm having a first end located opposite the second end, the first end of the offset arm being generally vertically aligned An offset arm pivotally supported on the carriage about an axis;
Pivotally supported at the second end of the offset arm about a second axis that is generally vertically aligned and spaced an offset distance from the first axis. The elbow
A radiation source configured to communicate with the radiation detector and acquire the diagnostic image;
A movable arm that supports the radiation source and the radiation detector from the elbow about a third axis that is generally horizontally aligned above the central longitudinal axis of the table in a vertical plane and above the central longitudinal axis. A movable arm that is pivotally supported and slidably supported to rotate about a fourth axis that is generally horizontally aligned perpendicular to the third axis. The first axis, the third axis, and the fourth axis all include a common intersection with each other,
Constitution.   The arrangement of claim 10, wherein the radiation source is in communication and alignment with the radiation detector along a generally linear vertical axis that is aligned generally parallel to the first axis.   11. The arrangement of claim 10, wherein the carriage is movable along the elevated support structure in a linear direction, generally aligned with the central longitudinal axis of the table in a vertical plane.   The configuration according to claim 12, wherein a central longitudinal axis of the elevated support structure is spaced from the central longitudinal axis of the table by an offset distance when viewed from above.   The configuration according to claim 12, wherein no part of the elevated support structure is aligned above the table in the vertical direction.   The arrangement of claim 12, wherein the linear direction of the carriage is generally parallel to the central longitudinal axis of the table.   11. The arrangement of claim 10, further comprising an electric driver operable to rotate the elbow and movable arm with respect to the offset arm about the second axis.   The arrangement of claim 10, wherein the imaging system is a radiation imaging system.   The configuration of claim 10, wherein a central longitudinal axis of the offset arm is generally linearly aligned between the first axis and the second axis. A method of transmitting radiation from a radiation source through a table to a radiation detector,
An operation of sliding the carriage in a linear direction along a rail positioned fixedly upward in the vertical direction with respect to the table;
Pivoting the first end of the offset arm about the carriage about a first axis;
Rotating the elbow with respect to the second end of the offset arm about a second axis that is generally vertically aligned and spaced horizontally from the first axis by an offset distance Operation and
Pivoting the movable arm with respect to the elbow about a third axis that is generally horizontally aligned and generally aligned with the central longitudinal axis of the table in a vertical plane;
Rotating the movable arm relative to the elbow around a fourth axis that is generally horizontally aligned and generally perpendicular to the third axis;
Transmitting radiation from a radiation source located at one free end of the movable arm toward the radiation detector.   The movement of sliding the carriage in the linear direction is aligned generally parallel to the central longitudinal axis of the table and is positioned at an offset distance in the horizontal direction from the central longitudinal axis of the table. The method of claim 19, wherein the method is performed along a longitudinal central axis of the rail.

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