CA1201512A - Method of forming implantable prostheses for reconstructive surgery - Google Patents
Method of forming implantable prostheses for reconstructive surgeryInfo
- Publication number
- CA1201512A CA1201512A CA000429520A CA429520A CA1201512A CA 1201512 A CA1201512 A CA 1201512A CA 000429520 A CA000429520 A CA 000429520A CA 429520 A CA429520 A CA 429520A CA 1201512 A CA1201512 A CA 1201512A
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- Prior art keywords
- dimensional
- representation
- dimensional coordinates
- generated
- radiant energy
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired
Links
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Classifications
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61F—FILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
- A61F2/00—Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
- A61F2/02—Prostheses implantable into the body
- A61F2/30—Joints
- A61F2/3094—Designing or manufacturing processes
- A61F2/30942—Designing or manufacturing processes for designing or making customized prostheses, e.g. using templates, CT or NMR scans, finite-element analysis or CAD-CAM techniques
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61F—FILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
- A61F2/00—Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
- A61F2/02—Prostheses implantable into the body
- A61F2/28—Bones
- A61F2/2803—Bones for mandibular reconstruction
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23Q—DETAILS, COMPONENTS, OR ACCESSORIES FOR MACHINE TOOLS, e.g. ARRANGEMENTS FOR COPYING OR CONTROLLING; MACHINE TOOLS IN GENERAL CHARACTERISED BY THE CONSTRUCTION OF PARTICULAR DETAILS OR COMPONENTS; COMBINATIONS OR ASSOCIATIONS OF METAL-WORKING MACHINES, NOT DIRECTED TO A PARTICULAR RESULT
- B23Q33/00—Methods for copying
-
- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B19/00—Programme-control systems
- G05B19/02—Programme-control systems electric
- G05B19/42—Recording and playback systems, i.e. in which the programme is recorded from a cycle of operations, e.g. the cycle of operations being manually controlled, after which this record is played back on the same machine
- G05B19/4202—Recording and playback systems, i.e. in which the programme is recorded from a cycle of operations, e.g. the cycle of operations being manually controlled, after which this record is played back on the same machine preparation of the programme medium using a drawing, a model
- G05B19/4207—Recording and playback systems, i.e. in which the programme is recorded from a cycle of operations, e.g. the cycle of operations being manually controlled, after which this record is played back on the same machine preparation of the programme medium using a drawing, a model in which a model is traced or scanned and corresponding data recorded
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61F—FILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
- A61F2/00—Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
- A61F2/02—Prostheses implantable into the body
- A61F2/28—Bones
- A61F2/2875—Skull or cranium
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61F—FILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
- A61F2/00—Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
- A61F2/02—Prostheses implantable into the body
- A61F2/30—Joints
- A61F2/3094—Designing or manufacturing processes
- A61F2/30942—Designing or manufacturing processes for designing or making customized prostheses, e.g. using templates, CT or NMR scans, finite-element analysis or CAD-CAM techniques
- A61F2002/30948—Designing or manufacturing processes for designing or making customized prostheses, e.g. using templates, CT or NMR scans, finite-element analysis or CAD-CAM techniques using computerized tomography, i.e. CT scans
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61F—FILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
- A61F2/00—Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
- A61F2/02—Prostheses implantable into the body
- A61F2/30—Joints
- A61F2/3094—Designing or manufacturing processes
- A61F2/30942—Designing or manufacturing processes for designing or making customized prostheses, e.g. using templates, CT or NMR scans, finite-element analysis or CAD-CAM techniques
- A61F2002/30952—Designing or manufacturing processes for designing or making customized prostheses, e.g. using templates, CT or NMR scans, finite-element analysis or CAD-CAM techniques using CAD-CAM techniques or NC-techniques
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61F—FILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
- A61F2/00—Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
- A61F2/02—Prostheses implantable into the body
- A61F2/30—Joints
- A61F2/3094—Designing or manufacturing processes
- A61F2/30942—Designing or manufacturing processes for designing or making customized prostheses, e.g. using templates, CT or NMR scans, finite-element analysis or CAD-CAM techniques
- A61F2002/30957—Designing or manufacturing processes for designing or making customized prostheses, e.g. using templates, CT or NMR scans, finite-element analysis or CAD-CAM techniques using a positive or a negative model, e.g. moulds
-
- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B2219/00—Program-control systems
- G05B2219/30—Nc systems
- G05B2219/45—Nc applications
- G05B2219/45168—Bone prosthesis
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S623/00—Prosthesis, i.e. artificial body members, parts thereof, or aids and accessories therefor
- Y10S623/901—Method of manufacturing prosthetic device
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S623/00—Prosthesis, i.e. artificial body members, parts thereof, or aids and accessories therefor
- Y10S623/912—Method or apparatus for measuring or testing prosthetic
- Y10S623/914—Bone
Abstract
METHOD OF FORMING IMPLANTABLE PROSTHESES
FOR RECONSTRUCTIVE SURGERY
Inventor David N. White ABSTRACT OF THE DISCLOSURE
Non-invasive method of forming prostheses of skeletal structures internal to a body for use in recon-structive surgery. The selected internal skeletal struc-ture is measured by subjecting the body to radiant energy to produce radiant energy responses that are detected to obtain representations delineating the skel-etal structure. Three dimensional coordinate data defin-ing the skeletal structure is generated from the obtain-ed representations. The coordinate data is employed to control a sculpting tool to form the prosthesis.
FOR RECONSTRUCTIVE SURGERY
Inventor David N. White ABSTRACT OF THE DISCLOSURE
Non-invasive method of forming prostheses of skeletal structures internal to a body for use in recon-structive surgery. The selected internal skeletal struc-ture is measured by subjecting the body to radiant energy to produce radiant energy responses that are detected to obtain representations delineating the skel-etal structure. Three dimensional coordinate data defin-ing the skeletal structure is generated from the obtain-ed representations. The coordinate data is employed to control a sculpting tool to form the prosthesis.
Description
MRTHOD OF ~ G ï~PLANTABLE ~kO~
FOR RECO~ ~uC - lV~ ~iu~;~r Inventor David N. White DESCRIPTION
The present invention relates generally to a method of constructing three dimensional corporeal mod-els of structures internal to bodies and, more parti-cularly, to a method of constructing such models fromthree dimensional representations of the internal struc-tures obtained without physical invasion of the bodies.
A three dimensional corporeal model of a struc-ture whose exact size and/or shape is unknown ordinarily is constructed from direct measurement of the dimension~
of the structure~ Direct measurement of the internal structure has the advantage of providing precise dimen-sional information that enables the construction of a corporeal model which accurately represents the internal structure. Often, however, the structure is confined within a body so as not to be accessable for direct meas-urement. In such cases, the body is`either opened or disassembled to provide access for the measurement of the internal structure of interest. When such opening or disassembly has not been practicabie or desirable, corporeal models have been constructed with the aid of visual inspections of standard radiographic images of the internal structure of interest, externallv formed castings of the body and other techniques of indirect examination of the body. The deficiencies of such tech-niques, however, have made it dif~icult~to con~truct corporeal models that accurately represent internal , .7 ,, 5~2 structures. For the most part, such indirect examina-tion techniques are deficient for such purposes because they provide imprecise dimensional information and structural delineation of structures internal to a body.
Accuracy is particularly important in the con-struction of corporeal models of internal tissue struc-tures of mammalian anatomies. Such models will be refer-red to herein as prostheses, whether in the form of a surgically implantable prosthesis or an external pros-thesis. Though exact measurement and accurate conform-ation are desirable in the construction of implantable prostheses for reconstructive surgery, non-invasive direct measurement of internal anatomic tiss~e struc-tures is not available by present methods and not practi-cable for the fabrication of prostheses. Present methods require fabrication of an implantable prosthesis for correction of bony contour abnormalities on the basis of a plaster casting taken over the area of abnorm-ality with soft tissue interposed between the structuraldefect and the cast. From this cast, a model onlay pros-thesis is constructed by a hand-sculpting method by a skilled prosthetist on a best-approximation basis, attem-pting to allow for the inaccuracies resulting from indirect measurement. Residual inaccuracies must then be modified at the time of implantation when direct surgical examination of deep structures is possible.
Tf a bone graft from the patient is to be fash-ioned to correct a structural defect, the surgeon has no precise representation of the bony abnormality prior to direct examination at the time of surgery, and is then required to alter the abnormality and fashion the implant in the operating room without the benefit of a prior working model.
Construction of accurate preoperative models and correctional implants avoids the shortcomings of the above-noted hand sculptiny technique and diminishes the S~2 morbidity associated with the prolonged anesthesia presently required.
The present invention is a method of constructing a three dimensional corporeal model that accurately represents a selected structure internal to a body. The novel method comp-rises subjectin~ the body to radiant energy to produce radiant energy responses internal to said body, the radiant energy selected to produce radiant energy responses that are charac-teristic of a selected physical property of substances detect-able exterior of the body. Produced radiant energy responsesare detected to obtain representations of substances at loca-tions internal to the body defining structures internal to said body three-dimensionally. One then generates from the representations of the substances a set of three dimensional coordinates defining a three dimensional representation of a selected structure internal to the body. Finally, a sculpting tool is directed into a workpiece in accordance with the gen~
erated set of three dimensional coordinates to form a corpo-real model corresponding to the three dimensional representa-tion of the selected structure.
As will become more apparent upon consideration ofthe description of the preferred embodiment of the present in-vention, noninvasive radiographic image reconstructions tech-niques and automatically controlled machining techniques are adapted and combined to enable the precise measurement of internal structures and the construction of corporeal models that are accurate representations of the internal structures. A radio-graphic image reconstruction technique particularly use-ful in the method of the present invention is computed tomography, according to which a cross sectional tomographic image is constructed from radiant energy transmitted through or reflected from the interior of the body along paths at different angles relative to the body. The image is constructed by computer manipulation of the detected radiant energy according to an algorithm whereby the localized radiant energy responses occurring at the cross section location of the body are computed.
The computed radiant energ~ responses are characteristic of the substances located at the cross section location of the detected radiant energy responses and, therefore, enable formation of an image of the structure at the cross section location. A series of such images is obtained at locations distributed along a line perpendi-cular to the plane of cross section b~ subjecting the body to radiant energy and detecting the transmitted or reflected radiant energy at each of the distributed loca-tions. ~omputerized tomographic devices have employed x-ray, nuclear magnetic resonance (NMR), positron emission (P~T) and ultrasonic radiant energy techniques to ob~ain data for the construction of images of internal struc-tures. Both analog gray-scale pictures of the detected radiant energy responses and paper printouts of mapped numerical value representations of tHe gray-scale values are commonly provided by such computerized tomographic devices. Examples of such devices are described in United States patents 3,673,394, 4,298,800 and Re 30,397, and references cited in the paten~s.
Machine-controlled contour sculpting tool devices have been widely used to reproduce three dimen-sional object surfaces from representations of such surfaces. Some of these devices control tool trajectory relative to a work piece in accordance with numerical data obtained from drawings or photographs of the ~2~
desired object, for example, by the use of contour or profile following instruments. Other contour sculpting devices utilize contour followers adapted to follow a physical model of the desired object and geneLate coord-inate control data used to control the trajectory of thesculpting tool. Some contour followers are mechanically linked to the sculpting tool whereby movement of the con-tour follower directly causes corresponding movement of the sculpting tool. Examples of contour sculpting tool devices are described in United States patents
FOR RECO~ ~uC - lV~ ~iu~;~r Inventor David N. White DESCRIPTION
The present invention relates generally to a method of constructing three dimensional corporeal mod-els of structures internal to bodies and, more parti-cularly, to a method of constructing such models fromthree dimensional representations of the internal struc-tures obtained without physical invasion of the bodies.
A three dimensional corporeal model of a struc-ture whose exact size and/or shape is unknown ordinarily is constructed from direct measurement of the dimension~
of the structure~ Direct measurement of the internal structure has the advantage of providing precise dimen-sional information that enables the construction of a corporeal model which accurately represents the internal structure. Often, however, the structure is confined within a body so as not to be accessable for direct meas-urement. In such cases, the body is`either opened or disassembled to provide access for the measurement of the internal structure of interest. When such opening or disassembly has not been practicabie or desirable, corporeal models have been constructed with the aid of visual inspections of standard radiographic images of the internal structure of interest, externallv formed castings of the body and other techniques of indirect examination of the body. The deficiencies of such tech-niques, however, have made it dif~icult~to con~truct corporeal models that accurately represent internal , .7 ,, 5~2 structures. For the most part, such indirect examina-tion techniques are deficient for such purposes because they provide imprecise dimensional information and structural delineation of structures internal to a body.
Accuracy is particularly important in the con-struction of corporeal models of internal tissue struc-tures of mammalian anatomies. Such models will be refer-red to herein as prostheses, whether in the form of a surgically implantable prosthesis or an external pros-thesis. Though exact measurement and accurate conform-ation are desirable in the construction of implantable prostheses for reconstructive surgery, non-invasive direct measurement of internal anatomic tiss~e struc-tures is not available by present methods and not practi-cable for the fabrication of prostheses. Present methods require fabrication of an implantable prosthesis for correction of bony contour abnormalities on the basis of a plaster casting taken over the area of abnorm-ality with soft tissue interposed between the structuraldefect and the cast. From this cast, a model onlay pros-thesis is constructed by a hand-sculpting method by a skilled prosthetist on a best-approximation basis, attem-pting to allow for the inaccuracies resulting from indirect measurement. Residual inaccuracies must then be modified at the time of implantation when direct surgical examination of deep structures is possible.
Tf a bone graft from the patient is to be fash-ioned to correct a structural defect, the surgeon has no precise representation of the bony abnormality prior to direct examination at the time of surgery, and is then required to alter the abnormality and fashion the implant in the operating room without the benefit of a prior working model.
Construction of accurate preoperative models and correctional implants avoids the shortcomings of the above-noted hand sculptiny technique and diminishes the S~2 morbidity associated with the prolonged anesthesia presently required.
The present invention is a method of constructing a three dimensional corporeal model that accurately represents a selected structure internal to a body. The novel method comp-rises subjectin~ the body to radiant energy to produce radiant energy responses internal to said body, the radiant energy selected to produce radiant energy responses that are charac-teristic of a selected physical property of substances detect-able exterior of the body. Produced radiant energy responsesare detected to obtain representations of substances at loca-tions internal to the body defining structures internal to said body three-dimensionally. One then generates from the representations of the substances a set of three dimensional coordinates defining a three dimensional representation of a selected structure internal to the body. Finally, a sculpting tool is directed into a workpiece in accordance with the gen~
erated set of three dimensional coordinates to form a corpo-real model corresponding to the three dimensional representa-tion of the selected structure.
As will become more apparent upon consideration ofthe description of the preferred embodiment of the present in-vention, noninvasive radiographic image reconstructions tech-niques and automatically controlled machining techniques are adapted and combined to enable the precise measurement of internal structures and the construction of corporeal models that are accurate representations of the internal structures. A radio-graphic image reconstruction technique particularly use-ful in the method of the present invention is computed tomography, according to which a cross sectional tomographic image is constructed from radiant energy transmitted through or reflected from the interior of the body along paths at different angles relative to the body. The image is constructed by computer manipulation of the detected radiant energy according to an algorithm whereby the localized radiant energy responses occurring at the cross section location of the body are computed.
The computed radiant energ~ responses are characteristic of the substances located at the cross section location of the detected radiant energy responses and, therefore, enable formation of an image of the structure at the cross section location. A series of such images is obtained at locations distributed along a line perpendi-cular to the plane of cross section b~ subjecting the body to radiant energy and detecting the transmitted or reflected radiant energy at each of the distributed loca-tions. ~omputerized tomographic devices have employed x-ray, nuclear magnetic resonance (NMR), positron emission (P~T) and ultrasonic radiant energy techniques to ob~ain data for the construction of images of internal struc-tures. Both analog gray-scale pictures of the detected radiant energy responses and paper printouts of mapped numerical value representations of tHe gray-scale values are commonly provided by such computerized tomographic devices. Examples of such devices are described in United States patents 3,673,394, 4,298,800 and Re 30,397, and references cited in the paten~s.
Machine-controlled contour sculpting tool devices have been widely used to reproduce three dimen-sional object surfaces from representations of such surfaces. Some of these devices control tool trajectory relative to a work piece in accordance with numerical data obtained from drawings or photographs of the ~2~
desired object, for example, by the use of contour or profile following instruments. Other contour sculpting devices utilize contour followers adapted to follow a physical model of the desired object and geneLate coord-inate control data used to control the trajectory of thesculpting tool. Some contour followers are mechanically linked to the sculpting tool whereby movement of the con-tour follower directly causes corresponding movement of the sculpting tool. Examples of contour sculpting tool devices are described in United States patents
2,852,189, 3,195,411, 3,259,022 and 3,796,129.
In the preferred embodiment of the method of the present invention, a computerized x-ray tomographic device is operated to provide representations of the absorption coefficient of substances at locations inter-nal to a body. The absorption coefficient representa-tions delineate the internal structures and are examined to derive three dimensional coordinate data defining a three dimensional representation of a selected delineat-ed internal structure. The coordinate data is derivedin a format compatible with a machine-controlled sculpt-ing tool device selected to form the desired corporeal model of the selected internal structure. ~ model is formed from a work piece of suitable material by opera-ting the machine-controlled sculpting tool device to con-trol the trajectory of its cutting sculpting tool rela-tive to the work piece in accordance`with the coordinate data derived from the absorption coefficient representa-tions of the structure obtained by the computerized x-ray tomographic device.
The foregoing and other objects, advantagesand features characterizing the present invention will become more apparent upon consideration of the ~ollowing description of specific embodiments and appended claims taken together with the drawings of which:
Figure 1 is a diagram schematically illustra-ting the steps of the preferred embodiment of the method of the present invention for obtaining three dimensional coordinate data of a selected structure internal to a body and generating a corporeal model thereof;
Figure 2 is a perspective view of a head illu-strating the manner in which three dimensional coordin-ates defining a selected internal anatomic structure are obtained in accordance with the preferred embodiment of the method of ~he present invention;
Figure 3 is a schematic diagram of an exem-plary gray-scale tomographic axial image in a plane taken at lines 3-3 of Figure 2, with the image construct-ed from ~-ray radiation responses obtained from the plane in accordance with the preferred method of the present invention;
Figure 4 is a schematic diagram of an enhance-ment of the exemplary image of Figure 3 depicting a cross seGtion of a mandible selected to be constructed in model form in accordance with the preferred method of the present invention;
Figures 5A and 5B are schematic diagrams illustrating x-ray scanning equipment for obtaining radi-ation responses from cross sections of a body in accord-ance ~ith the preferred method of the present invention;
Figure 6 is a schematic block diagram of a com-puterized x-ray tomographic apparatus for practicing the preferred method of the present invention;
Figure 7 is a schematic representation of an exemplary print o~ a mapped numerical value represent-ation of a reconstructed tomographic image;
Figures 8A, 8B and 8C together comprise a schematic diagram of a machine-controlled sculpting tool ~
apparatus for forming corporeal models of selected structures in accordance with the preferred method of the present invention;
Figures 9A and 9B together comprise a schem-atic diagram illustrating the construction of an onlay prosthesis from three dimensional coordinate data ~a2~
translated in accordance with the preferred method of the present invention; and Figure 10 is a schematic diagram illustrating the construction of an inlay prosthesis from three dimen-sional coordinate data translated in accordance with thepreferred method of the present invention.
The method of the present invention will be described with reference to a preferred embodiment of the present invention arranged to construct a prosthesis of an internal anatomic tissue structure from three dimensional coordinate data defining the internal struc-ture obtained without the physical invasion of the anat-omy. As will be appreciated from the following descrip-tion of the preferred embodiment, however, the method of the present invention can be practiced to obtain defini-tive three dimensional coordinate data and construct corporeal models of structures internal to bodies other than anatomies.
Generally and referring to Figure 1, a corp-oreal model representation of a selected internal struc-ture of a body is constructed by controlling a sculpting tool to follow a trajectory relative to a work piece determined by three dimensional coordinate data that specifies the contour of the selected internal struc-ture. To obtain the three dimensional coordinate datain accordance with the method of the present invention, the selected internal structure is scanned at step 81 by subjecting it to radiant energy to produce radiant energy responses that delineate the selected structure three dimensionally and are detectable at a location exterior to the body. The radiant energy responses are detected at step 82 and the detected responses processed at step 83 to obtain data delineating the selected struc-ture three dimensionally. At step 84, the three dimen-3S sional coordinate data required for the control of thesculpting tool in constructing the desired corporeal model representation of the selected internal structure 15~2 is generated from the data provided by the performance of step 83. As briefly discussed hereinbefore and as will become more apparant upon consideration of the detailed description of the preferred embodiment of the method of the present invention to follow, various corp-oreal model representations of a selected structure can be constructed in accordance ~ith the present invention.
A scale replica of the internal structure in the state found within the body is constructed from three dimen-sional coordinate data defining the selected structureat scale. If other than a scale replica of the internal structure is desired, data is manipulated at step 84 to obtain transformed three dimensional coordinate data for constructing an altered corporeal model representation of the selected internal structure. The manipulation can be performed at the time of the generation of three dimensional coordinate data from the data provided by the performance of step 83, for example, by generating the three dimensional coordinate data according to an algorithm relating the untransformed three dimensional coordinate data to the desired transformed three dimen-sional coordinate data. Alternatively, the transformed three dimensional coordinate data can be obtained by man-ipulation of generated untransformed three dimensional coordinate data, by manipulation of the data delineating the selecting structure before the generation of the three dimensional coordinate data or`by combinations of the aforementioned maripulations. As will be described in further detail hereinafter with reference to the pref-erred method of the present invention, interpolating,form or curve fitting, scaling and translating are manip-ulations particularly useful in constructing external and implantable prostheses and mold cavities for casting models of selected internal structures. In any case, the three dimensional coordinate data is gen~rated in a format determined by the sculpting device used in con-structing the corporeal model representation of the ~5~2 selected internal structure. The desired corporeal model representation is obtained at step 85 by directing a sculpting tool in accordance with the generated three dimensional coordinate data to follow a trajectory rela-tive to a work piece that produces the representationdefined by the three dimensional coordinate data. The corporeal model is fabricated from suitable material sel-ected according to the expected use of the model.
Examples of material suitable for the construction o prostheses are Silastic and Proplast. "Silastic" is a trademark of Dow Corning Corporation used to identify the material it markets. "Proplast" is a trademark of Vitek, Inc. used to identify the material it markets.
A preferred embodiment of the method of the present invention arranged to construct corporeal models of internal anatomic tissue structures will now be described in detaii with reference to Figures 2-7. The pre~erred embodiment will be described in connection with the construction of prostheses of a mandible. ~ore specifically and referring to Figures 2-4, the mandible 10 of the anatomy 11 is specified three dimensionally by subjecting the anatomy to radiant energy to produce radi-ant energy responses within the anatomy that are characteristic of a selected physical property of substances of and detectable at the exterior of the anatomy. Different substances of the anatomy 11 produce different distinguishable characteristic radiant energy responses which, upon detection, provide distinguishable representations of the different substances located within the anatomy. As will be described in greater detail hereinafterr a computerized tomographic imaging device 13 (Figure 6) utilizing x-ray radiation is employed in the practice of the preferred embodiment of the method of the present invention to obtain distinguishable representations of different substances within the anatomy 11. ~s described hereinbefore, computerized tomography devices provide cross sectional _ g _ ~2~LS~;~
representations of the internal structure of the anatomy 11 reconstructed from radiant energy transmitted through or reflected from the interior of the anatomy along paths at different angles relative to the anatomy. In the x-ray tomographic device 13, a narxow x-ray beam 14 (Figures 5A and 5B) is directed through the anatomy 11 along several paths (such as depicted by arrows 16) in a plane and the radiation transmitted through the anatomy is measured by x-ray detectors 17. A transmission 10 measurement taken along each path represents a composite of the absorption characteristics of all elements in the path of the beam. A computerized data processing system 18 (Figure 6) associated with the x-ray tomographic device 13 manipulates the measurements taken along the several paths according to an algorithm to calculate the attenuation coefficient of elements in each X~ plane 19 (Figure 2~ through which the x-ray beam 14 is directed.
The attenuation coefficients o elements in other planes distributed at spaced locations along the 2 axis perpendicular to the XY planes 19, hence the x-ray beam 14, are obtained by relatively moving the body 11 and the x-ray generation and detection apparatus in increments along a line generally perpendicular to the plane of the x-ray beam. Typically, the body 11 is 25 moved through a stationary scanning station at which the x-ray measurements along the several paths in each XY
plane are obtained by rotating opposltely disposed x-ray generator 26 and x-ray detector 17 devices (Figures 5 and 5B) about the body. The calculated attenuation coefficients provide accurate representations of the densities of the substances within the anatomy. In the processing of the measurements, gray-scale values are assigned to the calculated attenuation coefficient values to provide representations of the elements in each plane 19 suited for displaying an image of the structure of the anatomy 11 at the location of the plane.
~2;~3~5~Z
For example, Figures 3 and 4 schematically illustrate different image reconstructions 20 and 20', respectively, of a single cross section of the anatomy 11 shown in Figure 2 taken at a plane 19 extending through the mandible lQ. As can be seen by inspection of Figure 3 and 4, the light gray scale mandible repres-entative values 10 are readily distinguishable from the darker surrounding gray scale representations of other substances. Greater contrast between the mandible representative gray scale values and the gray scale representations of other anatomic tissue substances at the cross section can be obtained by enhancing the image reconstruction in the manner described hereinafter and shown in Figure 4. In both image reconstructions of Figures 3 and 4, the gray scale representations clearly delineate the surface location 12 of the mandible 10, from which the three dimensional coordinates of the mand-ible are derived. ~ series of such gray scale cross sectional representations of the anatomy 11 obtained along the Z axis provides information from which three dimensional coordinate data can be derived. As will be described in further detail hereinafter, three dimension-al coordinate data specifying a selected structure 10 of which a model is to be constructed is derived from a series of such cross sectional repre`sentations of the anatomy 11.
As mentioned hereinbefore,~other noninvasive radiographic imaging devices can be utilized in the practice of the method of the present invention to obtain cross sectional representations of the body 11 from which the desired three dimensional coordinate data defining the structure 10 of interest can be obtained.
In PET devices, for example, radiant energy originates within the anatomy 11 from an in~ravenously administered biologically active substance labeled with a positron-emitting radioactive isotope. The isotope decays by emitting positrons that travel a short distance in tissue before colliding with electrons. A collision bet-ween a positron and elec~ron annihilates both particles, converting the mass of the two particles into energy divided equally between two gamma rays emitted simultane-ously along oppositely directed paths. One PET devicein use includes arrays of scintillation detectors en-circling the subject supported by a mobile table with the region of interest at the axis about which the detec-tors are disposed. The arrays of detectors record simultaneously emitted gamma rays at a plurality of ~spaced axial cross sections of the subject during an imaging cycle, the detectors being linked in opposite pairs so that emitted gamma rays are recorded only when both detectors of a pair simultaneously sense gamma rays. All gamma ray pairs originating within a volume of the subject defined by the cylindrical, colinear field of view joining paired detectors are sensed.
Gamma rays orginating outside that volume are not sensed by the detectors. The sensed gamma ray responses are processed to obtain representations delineating the sub-stances in the field of view. The mobile table moves the subject axially relative to the encircling detectors to enable the detection of radiant energy events and con-comitant generation of representations of substances at a plurality of spaced axial cross sections of the sub-ject.
NMR imaging devices have the advantage of using a non-ioniæing form of radiant energy. In N~IR
devices, the subject is placed in a strong magnetic field while a brief high frequency signal is beamed at the body. Different atoms of substances of the body res-pond by sending out different characteristic radio sig-nals that are detected by tunable receiving antennas placed about the body. The tunable receiving antennas are adjusted to be responsive to selected radio signals and thereby obtain representations of sele~ted substan-ces, which are processed by an associated computerized 5~
data processing system to generate a distinguishablecharacteristic representation of such substance in a plane of the subject. Representations o substances in other parallel planes at spaced locations along a defined line are obtained by moving the subject in incre-ments through the magnetic field and past the receiving an~ennas.
Ultrasonic radiographic imaging devices also can be employed to obtain representations of the inter-nal structure of a body. Like NMR imaging devices,ultrasonic devices have the advantage of using a non-ion-izing form of radiant energy in obtaining the data from which representations of the internal structure of bodies are derived. Most ultrasonic imaging devices generate representations of anatomic structures from detected reflections of high frequency pulsed sound waves directed through the anatomy. ~ series of pulsed sound waves are sent forth into the anatomy by electri-cally pulsed piezoelectric transducers in contact with the anato~y. The transducers employed are capable of reversibly converting electrical to vibratory mechanical energy at the pulse requenc~ of interest. After the transmission of each short burst or pulse of sound energy, the circuitry associated with the transducer is switched to act as a receiver for returning or reflected echos of the transmitted sound waves. Echos are reflect-ed when the pulsed sound encounters àn interface of tissues of different densities. Tissues of different acoustic impedances return different echos. The reflect-ed echos are converted to representative electrical sig-nals by the piezoelectric transducers, from which planar representations of the internal structure of the anatomy are obtained. The data processing system associated with the ultrasonic device converts elapsed time between transmission of a sound pulse and reception of each echo into a measurement of the distance from the transducer to each location of echo reflection.
5~
Each of the radiographic imaging devices described above provides representations of the internal structure of a body by subjecting the body to selected radiant energy. In x-ray, NMR and ultrasonic devices/
the body is subjected to radiant energy projected at it from a location external to the body. With PET devices, however, the body is subjected to radiant energy genera-ted within the body itself. In any case, each of the imaging devices produces radiant energy responses within a body from which distinguishable representations of different internal structures of the body are generated and from which, in turn, three dimensional coordinates defining a selected structure internal to the body are generated for directing a sculpting tool to form a corp-oreal model representation of the selected internalstructure.
A computerized x-ray tomographic system suited for use in obtaining three dimensional coordinate data deining the mandible 10 of the anatomy 11 in accordance with the preferred embodiment of the method of the pre-sent invention is marketed by General Electric Company under the model designation CT/T 8~00 Scanner System.
The preferred method of obtaining three dimensional coordinate data defining the mandible 10 in accordance with the present invention will now be described with reference to the CT/T 8800 Scanner System, which is schematically illustrated in Figures`5 and 6. The compu-terized x-ray tomographic system 13 (Figure 6) is arranged to produce computer reconstructed cross section-al images of any part of the anatomy from multiple x-ray absorption measurements. The system 13 includes a radi-ation scanning assembly 27 having a mobile table 21 (Figure 5B) for supporting and transporting a subject through the x-ray scanning station 22 along a path indi-cated by arrow 23. The table 21 is configured to aid incentering and confining the anatomy 11 in a selected z orientation relative to the x-ray generator 26 and detec-tor 17 (Figures 5A and 5B) of the scanning assembly.
The radiation scanning assembly 27 also in-cludes a gantry 2~ (Figure 5B) positioned along the path 23 for supporting the x-ray generator 26 and x-ray detec-tor 17 for rotation about the mobile table 21 in a selected plane perpendicular or at an angle to the path 23. The x-ray generator 26 emits an x-ray fan beam 14 that is directed at an array of x-ray radiation sensi-tive cells forming the detector 17 at the opposite sideof the gantry 24. The beam 14 is formed and the detec-tor 17 is arranged to permit scanning of an object detec-tion zone 29 (Figure 5A) located in the plane of the beam. Each cell of the detector 17 detects a portion of the x-ray beam 14 after its passage through the object detection zone 29 (and any part of a body 11 located in the zone) and provides data representative of the comp-osite x-ray radiation attentuation coefficient along a path between the x-ray generator 26 and the data cell.
The data provided by the detector 17 as it and the X-ray generator ~6 are rotated about the subject (borne by the table 21) is processed to generate an attenuation coeffi-cient representation for each volume element 31 (Figure 4) of the cross sections of the anatomy 11 scanned by the x-ray beam 14. The resolution capability of the CT/T 8800 system 13 is dependent upon the fan thickness of the x-ray beam 14 and the power of the data reconstru-ction algorithm characterizing the software program employed in the system. A typical CT/T 8300 system generates an attenuation coefficient representation for a volume element 31 having a size on the order of 1.5mm x 0.8mm x 0.8mm, with the long 1.5mm dimension of the volume element 31 extending in the direction of the fan thickness dimension of the beam 14, hence the cross sec-tion of the anatomy 11 scanned. The other dimensions ofthe volume element 31 in the plane of the scanned cross section are largely determined by the software program, and attenuation coefficient representations of volume elements of smaller dimensions in the plane of the scan-ned cross section can be obtained by increasing the power of the data reconstruction software program.
once the anatomy 11 is positioned as desired relative to the scanning station 22, the mobile table 21 and gantry 24 are operated in sequence under control of the computer 32 to (i) position the anatomy 11 within the scanning station 22 at the desired location along 10 path 23, (ii) rotate the x-ray generator 26 and detector 17 for subjecting a cross sectional slice of the anatomy to the x-ray beam 14 and detecting the resulting radia-tion responses, and (iii) increment the table 21 a dis-tance of 1.5mm for scanning another cross sectional slice of the anatomy with the x-ray beam. This opera-tion of the table 21 and gantry 24 continues until data from the desired number of cross sectional slices of the anatomy 11 is obtained. Data from each cross sectional slice is obtained by pulsing the x~ray generator 26 to send pulses of x-ray radiation through the cross section-al slice along several hundred different paths while the gantry 24 is operated to rotate the x-ray generator 26 and detector 17 about the anatomy 11. This provides the radiation responsive data from which cross sectional representations of the anatomy are reconstructed.
The radiation responses detected by the detector 17 are processed by data acquisition circuitry 33 (Figure 6) of the system 13 under control of the comp-uter 32 for storage in a memory 36. ~ reconstruction data processor 37 is controlled by the computer 32 to reconstruct cross sectional representations of the anatomy 11 from the stored data. More specifically, the reconstruction data processor circuitry 37 is controlled by the computer 32 to manipulate the stored data math-ematically according to a reconstruction algorithm tocalculate the attenuation coefficient for each volume element 31 (Figure 4) of each cross sectional slice of ~Z~5~Z
the anatomy 11. The calculated attenuation coefficientdata is stored in the memory 36 for use as needed. For image display purposes, the calculated attenuation coefficients are converted to gray scale values expressed numerically in Hounsfield units, commonly referred to as "CT numbers".
The computerized data processing system 18 is operable through an operator control system 42 to con-struct various selectable representations of the anatomy 11 from the detected radiation response data. For example, the cross sectional representations of the anatomy can be enhanced by selectively narrowing the gray scale range and/or offsetting the gray scale range relative to the range of attenuation coefficients of sub-stances found in the anatomy~ Figures 3 and 4 schemati-cally illustrate an example of the enhancement of the cross sectional representations of the anatomy 11. In the illustrated example, volume elements 31 having atten-uation coefficients within a selected range or window are assigned one gray scale value, such as white, while all volume elements having attenuation coefficients out-side the selected range or window are assigned a black gray scale value. In this example, the gray scale range is centered at the end of the range of attenuation coefficients where that of bone is found. The operator control system 42 also enables the detected radiation response data to be manipulated to rèconstruct sagittal and coronal cross section representations of the anatomy 11 at one or more selected planes orthogonal to the axial plane of the anatomy. Each of the aforementioned reconstructed cross section representations accurately portrays the internal structure of the anatomy 11 at the cross section location of the representation and, there-fore, may be used in deriving three dimensional coord-inate data for use in constructing corporeal models ofinternal structures of the anatomyO
Data from which the desired three dimensional coordinate information can be derived is available from the computerized x-ray tomographic system 13 in various formats. Digital data representations of the recon-structed cross sections of the anatomy 11 are stored inthe memory 36 and are accessible for use in generating the three dimensional coordinate data. In addition, the system 13 includes an image generation system 28 which is operable to provide a paper printout image in the form of mapped numerical value representations of the reconstructed cross section of the anatomy 11, an analog display of gray scale pictures of the reconstructed cross section, or hard copies of the analog gray scale pictures. More specifically, printouts of mapped numeri-cal value representations of selected reconstructedcross sections of the anatomy 11 is provided by a printer 38 included in the image generation system 28.
Analog gray scale pictures of the reconstructed cross sections can be viewed on the CRT dis~lay 39 and hard copies obtained from the x-ray film camera 41.
Control of the computeri~ed x-ray tomographic system 13 in generating reconstructed representations of cross sections of the anatomy 11 is exercised by the operator through the operator control system 42.
Inasmuch as General Electric Company's CT/T 8800 Scanner - System and operator manuals therefor~ are available from which further details of the construction and operation of system 13 can be determined, such details are not des-cribed herein.
To obtain three dimensional coordinate data of the mandible 10 illustrated in Figure 2, the s~stem 13 is operated to obtain radiation response data from a plurality of contiguous 1.5mm axial cross sections of the entire mandible. The radiation response data is pr~-cessed to reconstruct representations of each axialcross section 20, such as illustrated in Figure 3. To facilitate the reconstruction and use of the axial cross 3LZ~L5~
section data, each axial cross section representation is enhanced as illustrated in Figure 4 to distinguish bone substance from all other substances located at the posi-tion of each axial cross section 20'.
Three dimensional coordinate data defining the mandible 10 can be obtained directly from the digital data generated by the computerized x-ray tomographic system 13 and stored in its memory 36. For example, the system 13 generates and manipulates reconstructed digi-tal data representations of cross section volume ele-ments according to the spatial coordinates of the repres-ented volume elements. By accessing such representa-tions within the system 13 according to their spatial coordinates, the three dimensional coordinates of the 15 surface 12 of the mandible 10 can be obtained directly and automatically from the data stored in the memory 36 of the system.
Three dimensional coordinate data also can be obtained directly from analog gray-scale pictures of the reconstructed representations of the axial cross sec-tions, such as illustrated in Figure 4. Each of the series of pictures of the axial cross sections 20' is composed of known gray scale values from which two planar coordinates is determined, such as X and Y. The 25 distribution of gray scale values in the axial direc-tion, as represented by the series of pictures of axially disposed contiguous cross sections of the anatomy at locations including the mandible 10, provides data from which the third coordinate, Z, is determined.
The spatial coordinates defining the three dimension~l surface of the mandible 10 is determined from the coord inate location of the gray scale value representation of the surface 12. This coordinate determination can be accomplished through various measuring methods, in~lud-ing manually defining analog prints or displays of eachcross section 20' in terms of spatial coordinates.
Alternatively, the determination of the coordinates can ~Z~ 2 be carried out th{ough the use of mechanical aids, such as contour or profile follows. Such aids are used to determine the XY planar coordinates of the reconstructed surface representation 12 in each cross section 20', the third coordinate being given by the axial coordinate Z
of each reconstructed cross section. If all reconstruct-ed cross section representations of the mandible 10 are employed in the generation of the three dimensional coordinate data, the Z axial coordinate data is 10 distributed at intervals corresponding to the center-to-center spacing of the cross sections of the body 11 represented by the reconstructed data. When the recon-structed data is obtained from contiguous cross sections of the body, the Z axial coordinate data is at intervals of 1.5mm.
Printouts of mapped numerical value representa-tions of the reconstructed absorption coefficients of the volume elements of eajch reconstructed cross section also can be used to obtain three dimensional coordinate data defining the surface 12 of the mandible 10. Figure 7 is a schematic illustration of such a printout. To facilitate the illustration of a mapped numerical value image of a reconstructed cross section of the anatomy 11, a reconstructed cross section 20" of the anatomy is divided by lines into regions of identified significant numerical values. The lines also are used to identify surface boundaries of significant structures internal to the anatomy 11. As discussed hereinbefore, the recon-structed attenuation coefficients are expressed as a Hounsfield unit and are commonly referred to as "CT num-bers". In the CT/T 8800 system 13, the range of CT num-bers extends from -1000 (which represents air) to +1000 (which represents dense bone). A CT value of 0 repres-ents water. The three dimensional coordinate data defin-ing the surface 12 of the mandible 10 can be obtainedfrom the printouts of mapped CT values in the ways described hereinbefore with reference to the ~se of ~2~5~
analog gray scale pictures or displays of reconstructedaxial cross sections. When using printouts of mapped CT
values defining reconstructed cross sections 20" of the mandible, the three dimensional coordinates defining the surface of the mandible are determined by following the contour of numerical CT values delineating the recon-structed surface 12 of the ~econstructed mandible 10, instead of the contour delineated by a line in an analog gray scale picture or display.
A preferred method of sculpting a corporeal model of a segment 51 (Figures 2-4) of the mandible 10 in accordance with the present invention will now be des-cribed with reference to the machine-controlled contour sculpting tool apparatus 52 illustrated in Figures 8A-15 8C. The machine-controlled sculpting tool apparatus 52 is arranged to control a cutting tool 53 in accordance with cylindrical coordinates defining the shape of the desi~red corporeal model representation of the mandible 10. Therefore, the recon~tructed tomo~raphic representa-tions of the anatomy 11 generated by the computerized x-ray tomographic system 13 illustrated in Figure 6 are utilized to derive radial (r), angular (~) and axial (z) coordinates describing the surface 12 of the mandible segment 51 relative to a selected reference line. ~ref-erably, the selected reference line is a straight linepassing through a point lying along the centric of the mandible segment 51. The reference line is depicted in Figures 2, 3 and 4 by a broken line 54 of alternate long and short lengths. The axial coordinate z e~tends along the reference line 54, and the radial r and angular 9 coordinates are in plane perpendicular to the reference line 54. The deriviation of the cylindrical coordinates relative to the reference line 54 is facilitated by posi-tioning the subject within the scanning station 22 and/or tilting the gantry 24 relative to the mobil table 21 so that the reference line 54 is generally perpendi-cular to the plane of the x-ray beam 14. In this way, ~LZ~5~:
the x-ray tomographic system 13 is operated to provide a series of oblique ~iOe, other than axial, coronal or sag-gital) cross sectional representations of the mandible segment 51 in parallel planes distributed along and per-pendicular to the line 54, with of each cross sectionalrepresentation centered on the line 54. Such positioning reduces the amo~nt of data processing time re~uired to ob~ain the cross sectioned representations from the detected radiant energy responses and, hence, 10 the three dimensioned coordinates of interest. However, such subject positioning and/or gantry tilting is unnecessary when a radiographic tomographic system 13 is employed that is capable of reconstructing oblique cross section representations of internal anatomic structures 15 from radiant energy responses obtained from a subject oriented in the standard supine position with the axis of the body perpendicular to the cross sections of the body ~rom which the radiant energy responses are obtained.
A work piece of a material suitable for con-structing the desired prosthesis is secured to a rotat-able turntable 58 that is coupled to a drive motor 59 by a drive shaft 61. To form the desired model, the drive motor 59 rotates the workpiece 57 about the axis 62 as 25 the trajectory of the cutting tool 53 is controlled to form the desired contour in the workpiece. The axis 62 of rotation of the workpiece 57 is lo~cated to pass through the origin relative to which the c~utting tool 53 is moved in the radial and axial directions in accord-30 ance with the cylindrical coordinates. The origin islocated at a point along re~erence line 54 (Figures 2-4), which for convenience is selected to be at one end 55 of the mandible segment 51 being modeled. In the example, the origin is located at the end 55 o~ the mand-35 ible segment 51 closest to the hinge segment 50 o themandible 10. In generating the three dimensional cylin-drical coordinates from the data obtained by the x-ray ~z~s~z tomoyraphic system 13, the cylindrical coordinates are specified relative to an origin that is to be coincident with the origin of the coordinate system used in the sculpting tool apparatus 52 to specify the spatial loca-tion of the cutting tool 53. The origin of the coordin-ate system of the sculpting tool apparatus illustrated in Figures 8A-8C is located a short distance above the turntable 58.
The cutting tool 53 is moved in the axial z and radial r directions relative to the axis 62 in accordance with the cylindrical coordinate data by coop-erating way and carriage assemblies. Movements in the radial direction, r, are governed by a horizontally extending way 64 and a cooperating carriage 65 that 15 carries the cutting tool 53 for movement along the hori-zontal way. Movements in the axial direction, z, are governed by a pair of vertically extending ways 66a and 66b and cooperating carriages 67a and 67b that support the horizontal way 64 for movement along the vertical way. In the preferred embodiment, the ways 64 and 66 are motor driven lead screws that engage lead screw nut assemblies forming the cooperating carriages 65 and 67.
More specifically, each o~ the vertical lead screws 66a and 66b extends between one of the reversible motors 43a and 43b and one of the cooperating journals 44a and 44b.
The driven end of each lead screw is coupled for rota-tion by the operatively associated motor and the oppos-ite end of that lead screw is seated for rotational sup-port within the cooperating journal. The two motors 43a and 43b are operatively coupled together by a timing chain 45 that maintains the motors in synchronism so that the two lead screws 66a and 66b are synchronously rotated by the two motors. Activation of the motors ~3a and 43b rotates the lead screws 66a and 66b in a direc-tion determined by the controlling cylindrical coordin-ate data, which causes the engaged lead screw nut ~;Z~5~Z
assemblies 67a and 67b to move in the corresponding direction along the rotated lead screws.
Each lead screw nut assembly 67a and 67b is fastened to one of the suppor~ plates 68a and 68b, the two plates serving to support the motor driven horizon-tal lead screw 64, cooperating lead screw nut 65 and cutting tool 53 assemblies relative to the lead screw nut assemblies 67a and 67b and cooperating lead screws 66a and 66b. The driven end of the horizontal lead 10 screw 64 i5 coupled for rotation by a motor ~6 fastened to the support plate 68a. The horizontal lead screw 64 extends from its driven end to an opposite end supported for rotation within a journal 47 fastened to the support plate 68b. The lead screw nut assembly 65 bears a mount-ing plate 69 on its upper side, upon which is fastened amotor 70 for rotating a spindle 71 that carries the cut-ting tool 53 for cutting the workpiece 57. Activation of the motor 46 turns the lead screw 64 in a direction determined by the controlling cylindrical coordinate data, which causes the engaging lead screw nut assembly 65 to move in the corresponding direction along the lead screw.
In the preferred embodiment o~ the machine tool apparatus 52, the work piece 57 is located at one side of the structure that supports the cutting tool 53.
To permit ready access to the work piece 57 by the cutt-ing tool 53 along radially and axially adjustable paths, the vertical lead screws 66a and 66b are horizontally displaced to one side of the horizontal lead screw 64.
Additional support for the cutting tool sup-port and positioning apparatus is provided by four verti-cally extending stationary posts 72 and cooperating sleeve bearings 73. A post 72 is located at each end of eacb of the support plates 68a and 68b. The sleeve bear-ings 73 couple the support plates 68a and 68b to the posts 72 for support while permittin~ the support plates to move relative to the posts when the lead screws 6Sa ~z~s~
and 66b are turned to move the cutting tool 53 in the axial direction, z.
The preferred machine tool apparatus 52 is arranged for constructing models of a wide variety of S sizes. For this reason, the cutting tool 53 is support-ed by a long spindle 71 for movement over a large dis-tance in the radial direction, r. To aid in maintaining the cutting tool 53 in the axial position specified by the cylindrical coordinate data, the spindle 71 is supported for rotational and radial movements by a journ-al 74 at the support plate 68b nearest the turntable 58.
The journal 74 is supported by a platform 75 joined at the top edge of the support plate 68b to extend horizon-tally therefrom in the direction opposite the turntable 58.
The various motors of the machine-controlled contour sculpting tool apparatus 52 are synchronously controlled by the machine tool controller 63 in accord-ance with the cylindrical coordinate data derived from the series of oblique cross sectional representations of the mandible 10 so that the work piece 57 is cut to have a contour corresponding to that represented by the cylin-drical coordinates. More specifically, the derived cylindrical coordinate data is stored in a memory 56 for use by the machine tool controller 63 in controlling the trajectory of the cutting tool relative to the work piece 57. The machine tool controller provides commands to a motor drive circuit 76 coupled to drive the rotary cutting tool 53 at a selected speed suitable for sculpt-ing the work piece 57 into the desired form and finish.In addition, the controller 63 provides commands to the three motor drive circuits 77, 78 and 79, which are coupled respectively to synchronously drive the radial position determining horizontal lead screw motor 46b, the axial position determining vertical lead screw motors 43a and 43b, and the turntable motor 59. Thes~
later commands are provided i~ accordance with ~;~0~5~2 cylindrical coordinate data so that the turntable 58 is rotated and the cutting tool 53 moved relative to the axis 62 whereby the tool follows a trajectory relative to the workpiece 57 productive of the formation of a model that accurately represents the mandible segment 51~
The machine tool controller 63 is arranged to issue commands to the axial motor drive circuit 78 to step the cutting tool 53 in increments along the rota-tional axis 62 of the turntable 58 so that the workpiece 57 is cut along concentric bands, with each band at a location along the axis 62 corresponding to the loc-ation of a plane along line 54 at which a cross section-al representation of the mandible 10 is obtained. In addition, the machine tool controller 63 is able to process the cylindrical coordinate data to calculate, by linear interpolation, the change in the axial coordinate z as a function of the angular coordinate ~ between adja-cent locations of cross sectional representations of the mandible 10. This calculation provides axial and angu-lar coordinate data permitting the cutting tool 53 to be directed along a spiral trajectory in sculpting the work piece 57.
The preferred embodiment of the controlled con-tour machine tool apparatus 52 employs stepping motors for driving the lead screws 64 and 6S and turntable 58.
The apparatus 52 is controllable to ~otate the turntable 58 in steps as small as fractions of an angular minute and to move the rotary cutting tool 53 in the radial, r, and axial, z, directions in steps as small as fractions of a millimeter. For constructing a prosthesis of an internal anatomic tissue structure, such as mandible 10, however, turntable rotation steps on the order of one or two degrees and cutting tool radial and axial movement steps on the order of tenths of a millimeter are satis-factory.
5~L2 The preferred method of the present invention has been described in detail with reference to sculpting a corporeal model replica of a segment 51 of a mandible 10 using a machine-controlled contour sculpting tool apparatus 52 having a single cutting tool 53 controlled in accordance with cylindrical coordinates that define a three dimensional representation of the segment.
However, it will be appreciated that machine-controlled contour sculpting tool apparatus arranged to control the trajectory of a cutting tool specified by three dimen-sional Cartesian coordinates can be employed in the method o~ the present invention to form the corporeal model. Moreover, machine-controlled contour sculpting tool apparatus having a plurality of independently con-trollable cutting tools can be used to ~orm the corp-oreal model in accordance with the method of the present invention. The particular nature of the machine-control-led contour sculpting tool apparatus 52 employed to con-struct a corporeal model representation of a selected structure 10 internal to a body 11 does effect the gener-ation of the three dimensional coordinate data from the cross section representations of the selected structure provided by the tomographic imaging device 13. In some applications, it may be necessary or convenient during the generation and/or use of the three dimensional coord-inate data to translate the coordinate data between diff-erent coordinate systems or between different spatially oriented sets of axes in the identical coordinate system. For example, translations between the Cartesian and cylindrical coordinate systems is achieved by manipu-lating the coordinate data defining each cross section representation of the selected structure 10 according to the coordinate translating equations relatiny rectangu-lar and polar coordinates. Translations between differ-ent spatially orientated sets of axes is achieved by man-ipulating the coordinate data according to vector ~z~s~
normalization equations relating the differently orientated sets of axes.
Thus far, the method of the present inYention has been described in detail as practiced to construct a corporeal model replica of the selected segment 51 of the mandible 10. It should be appreciated, however, that other model representations of a selected structure internal to a body can be constructed through the prac-tice of the method of the present invention. For 10 example, a mold cavity representation of the selected mandible segment 51 can be constructed from which one or more corporeal model replicas of the segment-can be cast. To facilitate the construction of the cavity, it is made in two mating half sections extending in the 15 direction of the line 54. The three dimensional coordin-ate data is generated from the cross section representa-tions ~or translated from previously generated coordin-ate data defining the surface 12 of the segment 51) to define a mating cavity form of each half of the surface 20 12. This coordinate data is employed by the machine-controlled contour sculpting tool apparatus 52 to direct the cutting tool 53 along a trajectory that produces one of the mold cavity half sections from a first work piece 57 and the other of the mold cavity half sections from a 25 second work piece. In sculpting each mold cavity half section, the turntable 58 is incremented slowly to rotate the work piece 57 about the axis 62 at a speed that permits the cutting tool 53 to cut the work piece to the desired shape along a series of parallel radial/axial trajectories relative to the axis 62.
Another salient feature of the method of the present invention relates to the construction of altered corporeal model representations of structures internal to a body. The formation of altered model representa-tions of internal body structures is particularly usefulin the construction of surgically implantable prostheses. Often, a prosthesis is made to replace a 5~2 missing anatomic structure, in which case a representa-tion of the desired prosthesis form will not appear, for example, in the set of cross section images provided by a tomographic imaging device. In accordance with the method of the present invention, however, altered three dimensional coordinate data that de~ines a representa-tion of the missing structure is generated from the set of cross section images that is obtained for use in form-ing a prosthetic model of the missing structure. As will become more apparent from the following detailed description, formation of altered three dimensional representations of structures is particularly useful in constructing prosthetic onlays and inlays. Coordinate transformation is one technique suited to the generation of three dimensional coordinate data for the construc-tion of prosthetic onlays and inlays in accordance with the method of the present invention. An example of the use of coordinate transformation in the construction of a prosthetic onlay will now be described with reerence to Figures 9A and 9B. The coordinate transormation is described as undertaken in the Cartesian coordinate system. However, such transformations can be undertaken in the cylindrical coordinate system as well.
To obtain the necessary coordinate data to construct a prosthesis of, for example, an atrophic mand-ible 91 illustrated in Figures 9A and 9B, data yrids 92, 93 and 94 encompassing the atrophic segment of the mand-ible 91 (indicated by shading in Figure 9A) are identified. Within the identified data grids, three dimensional X, Y, Z coordinates are established for determining the amount and nature of the desired coordinate translation. ~his can conveniently be accomplished with the aid of an ima~e processor, such as the image proces~or marketed by Grinnell, Inc., under the model designation System 271. The Grinnell system is designed to function with a Disital Equipment Corporation (DEC) LSI-11/23 computer apparatus having industry standard I/O data communication terminals, a video terminal and monitor, graphic tablet and graphic printer. The Grinnell image processor and DEC computer apparatus form an image processin~ system arranged to interact with an operator for purposes of image generation and alteration. Image data can be input to the image processing system either from the graphic tablet or from external graphic data sources connected to an I/O data communication terminal of the system.
For the purpose of translating the surface of the atrophic mandible 91, the cross section image repres-entations generated by the CT/T 8800 system 8800 are con-verted to a data format compatible with the image pro-cessing system and input to that system for display and image manipulation purposes through an I/O data communi-cation terminal. The image processing system is oper-able to display two dimensional or three dimensional per-spective representations of objects. The desired coord-inate translation is determined by displaying either a three dimensional representation of the atrophic mand-ible 91 or a sequence of two dimensional cross section representations of the atrophic mandible 91. Cross sections of the mandible generally perpendicular to its centric are preferred for this purpose. By use of the graphic tablet of the image processing system, the atrophic superior surface S of the mandible 91 e~tending from point 92 to point 93 is transla~ed in the direction indicated by the arrows in Figures 9A and 9B to the desired new location S' to form an image of the desired altered mandible.
The translation of the atrophic superior sur-face S can be accomplished in one step, for example, using a three dimensional display of the atrophic mandi-ble 91 (such as seen in Figure 9A), or it can be done cross section-by-cross section using two dimensional images of the atrophic mandible (such as seen in ~igure 9B) at locations along its centric line. In either - 30 ~
L5~2 case, the superior surface is translated by manipulating the graphic tablet instrument while observing the results of the manipulations on the video monitor and operating the image processing system to delete the S atrophic surface S, represented in Figures 9A and 9B as a solid line bounding mandible 91, and create the translated surface S' at the location of the dotted line in Figures 9A ands 9B.
As seen in Figures 9A and 9B, all coordinate points on the new surface S' are displaced relative to the corresponding locations on the atrophic surface S by a uniform distance q in the direction of the Z axis.
For some prostheses, it may be necessary to move differ-ent coordinate points along the atrophic superior sur-face S by different amounts or by an amount that variesin the direction of a selected dimension of the structure according to a defined gradient. If the atrophic superior sur~ace S is irregular, for example, different coordinate translation distances would be required to create a translated regular surface S'. The three dimensional coordinate representation of the desir-ed altered mandible can be derived fxom the altered mand-ible image data present in the Grinnell image processing system in ways like those described hereinbe~ore with 2s reference to the CT/T 8800 system.
Using an image processing system to translate and generate three dimensional coordinate data defining a desired altered structure has the advantage of enabling inspection and adjustment of the translation to produce the desired altered structure before generating the defining three dimensional coordinate data~ When constructing implantable prostheses, for example, it is desirable to preview the translation and adjust it until the displayed altered structure mates with the displayed unaltered structure. This is help~ul in constructing an implantable prosthesis that properly mates with the surrounding anatomic structures. However, the desired ~z~s~
translation and generation can be accomplished in other ways as well. For example, new coordinate data can be obtained by manipulation of the atrophic mandible coord-inate data derived from the CT/T ~800 image representa-tions of the atrophic mandible 910 In either case, the three dimensional coordinate data specifying the altered mandible is obtained by adding a coordinate value corres-ponding to the distance q to the Z axis coordinate value for all specified coordinate points of the atrophic sur-face S.
For purposes of constructing an implantableprosthetic onlay, only the altered segment of the alter-ed mandible 91 is required. A three dimensional coordin-ate specification of only the altered segment is obtain-ed by substracting each Z axis coordinate value definingthe atrophic superior surface S from the axis coordinate value of the translated new surface S' at the correspond-ing X and Y coordinate locations. An implantable prosthetic onlay is formed according to the remainder coordinate values.
Models of deformed or missing segments of internal structures also can be constructed from coordin-ate data specifying the deformed or missing segment that is derived from representations of a normal mirror image segment of the structure. For example, coordinate data defining a mirror image segment of a structure is useful in the construction of an implantablè prosthetic inlay that is to replace a missing segment of a generally sy D etrical internal anatomic structure. Derivation of the mirror image coordinate data can be accomplished through the use of the above-described Grinnell image processor or by manipulation of the coordinate data derived from the data representations provided by the CT/T 8800 system 13. If the image processor is employ-ed, the deformed, but otherwise generally symmetricalstructure is displayed and the deformed or missing seg-ment is altered to the desired form by operator ~2(~5-~Z
manipulation of the graphic tablet, using the video monitor display of the mirror image segment of the structure as a guide. The desired three dimensional coordinate data is generated from the altered segment as described hereinbe~ore with reference to Figures 9A and 9~ .
However, the mirror image coordinate data can be obtained directly from the three dimensional coordin-ate data defining a normal ~egment of an internal struc-ture that is generated directly from the image represent-ations provided by the CT/T 8800 system 13. Referring to Figure 10, a deformed mandible 97 is illustrated in relation to three dimensional X, Y, Z coordinates~ But for the deformation, the mandible is generally symmetri-cal about the Y-Z plane extending through the most anterior point 99 of the mandible 97. ~s seen in Figure 10, the deformation is in the form of a missing segment 100 located at the left side of the XY plane of symmetry. A normal segment 96 of the mandible 97 exists to right of the nominal XY plane of ~eneral symmetry at the mirror image location relative to the missing segment 100. This segment 96 is surrounded by an enclosure 98 that defines data grids including the three dimensional X, Y, Z spatial coordinates defining the normal segment 96. The actual and mirror image coordinates of the normal segment 96 are the same relative to the Y and z coordinate a~es, but are different relative to the X coordinate axis. To obtain the mirror image X coordinate, the distance separating the actual X coordinate value of each coordinate point specifying the normal segment 96 from the X coordinate value of the location of the XY plane of symmetry is multiplied by (-1) and is added to the X coordinate value of the location of the XY plane of symmetry. This coordinate translation technique enables the generation of the mirror image coordinate values of the normal segment 96 by manipulation of the three dimensional 5~
coordinate data generated directl~ from the i~age representations obtained by the CT/T 8800 system 13.
For convenience, the derivation of translated coordinate data has been described ~ith reference to coordinate manipulation in the Cartesian coordinate system and cross section representations of the internal structure that are defined three dimensionally in rela-tion to orthogonal X, Y, Z axes that are oblique to the axial, coronal and sagital planes. Translation of the 10 coordinates from that axis orientation to any other desired axis orientation or to a cylindrical coordinate system can be accom~lished as described in detail herein-before. However generated, three dimensional coordinate data in the form required by the machine-controlled 15 contour sculpting tool apparatus 52 is generated from the translated representations and input to the sculpting tool apparatus to control the trajectory of the cutting tool 53 so that the desired altered corp-oreal model representation of the selected internal structure is formed.
The method of the present invention has been described in detail wi~h reference to the construction of various corporeal model representations of structures internal to bodies from coordinate data obtained from reconstructed representations of contiguous cross sections of the structures. However, corporeal models can be constructed from coordinate d~ta obtained from reconstructed representations of cro~s sections at spaced intervals along the structure as well. For example, a generally uniform structure, such as the femur bone, can be represented by reconstructed representations taken from widely spaced locations along its length. In such applications, the three dimensional coordinates required for the control of the sculpting tool between the widely spaced locations is generated by interpo-lat.ion of the locations of the selecte~
structure intermediate to the spaced locations and ~z~s~L%
generating corresponding three dimensional coordinates that define the interpolated locations. The corporeal model is formed by directing the sculpting tool in accordance with the three dimensional coordinates that define the spaced and intermediate locations of the selected structures.
One preferred embodiment and certain varia-tions of the method of the present invention have been described in detail as arranged to construct corporeal 10 models of selected internal anatomic structures useful in the study of internal structures of anatomies and in the surgical correction of deformed internal structures.
It will be apparent to those skilled in the art, however, that various modifications and changes may be 15 made in the practice and use of the method without departing from the scope of the present invention as set forth in the following appended claims.
In the preferred embodiment of the method of the present invention, a computerized x-ray tomographic device is operated to provide representations of the absorption coefficient of substances at locations inter-nal to a body. The absorption coefficient representa-tions delineate the internal structures and are examined to derive three dimensional coordinate data defining a three dimensional representation of a selected delineat-ed internal structure. The coordinate data is derivedin a format compatible with a machine-controlled sculpt-ing tool device selected to form the desired corporeal model of the selected internal structure. ~ model is formed from a work piece of suitable material by opera-ting the machine-controlled sculpting tool device to con-trol the trajectory of its cutting sculpting tool rela-tive to the work piece in accordance`with the coordinate data derived from the absorption coefficient representa-tions of the structure obtained by the computerized x-ray tomographic device.
The foregoing and other objects, advantagesand features characterizing the present invention will become more apparent upon consideration of the ~ollowing description of specific embodiments and appended claims taken together with the drawings of which:
Figure 1 is a diagram schematically illustra-ting the steps of the preferred embodiment of the method of the present invention for obtaining three dimensional coordinate data of a selected structure internal to a body and generating a corporeal model thereof;
Figure 2 is a perspective view of a head illu-strating the manner in which three dimensional coordin-ates defining a selected internal anatomic structure are obtained in accordance with the preferred embodiment of the method of ~he present invention;
Figure 3 is a schematic diagram of an exem-plary gray-scale tomographic axial image in a plane taken at lines 3-3 of Figure 2, with the image construct-ed from ~-ray radiation responses obtained from the plane in accordance with the preferred method of the present invention;
Figure 4 is a schematic diagram of an enhance-ment of the exemplary image of Figure 3 depicting a cross seGtion of a mandible selected to be constructed in model form in accordance with the preferred method of the present invention;
Figures 5A and 5B are schematic diagrams illustrating x-ray scanning equipment for obtaining radi-ation responses from cross sections of a body in accord-ance ~ith the preferred method of the present invention;
Figure 6 is a schematic block diagram of a com-puterized x-ray tomographic apparatus for practicing the preferred method of the present invention;
Figure 7 is a schematic representation of an exemplary print o~ a mapped numerical value represent-ation of a reconstructed tomographic image;
Figures 8A, 8B and 8C together comprise a schematic diagram of a machine-controlled sculpting tool ~
apparatus for forming corporeal models of selected structures in accordance with the preferred method of the present invention;
Figures 9A and 9B together comprise a schem-atic diagram illustrating the construction of an onlay prosthesis from three dimensional coordinate data ~a2~
translated in accordance with the preferred method of the present invention; and Figure 10 is a schematic diagram illustrating the construction of an inlay prosthesis from three dimen-sional coordinate data translated in accordance with thepreferred method of the present invention.
The method of the present invention will be described with reference to a preferred embodiment of the present invention arranged to construct a prosthesis of an internal anatomic tissue structure from three dimensional coordinate data defining the internal struc-ture obtained without the physical invasion of the anat-omy. As will be appreciated from the following descrip-tion of the preferred embodiment, however, the method of the present invention can be practiced to obtain defini-tive three dimensional coordinate data and construct corporeal models of structures internal to bodies other than anatomies.
Generally and referring to Figure 1, a corp-oreal model representation of a selected internal struc-ture of a body is constructed by controlling a sculpting tool to follow a trajectory relative to a work piece determined by three dimensional coordinate data that specifies the contour of the selected internal struc-ture. To obtain the three dimensional coordinate datain accordance with the method of the present invention, the selected internal structure is scanned at step 81 by subjecting it to radiant energy to produce radiant energy responses that delineate the selected structure three dimensionally and are detectable at a location exterior to the body. The radiant energy responses are detected at step 82 and the detected responses processed at step 83 to obtain data delineating the selected struc-ture three dimensionally. At step 84, the three dimen-3S sional coordinate data required for the control of thesculpting tool in constructing the desired corporeal model representation of the selected internal structure 15~2 is generated from the data provided by the performance of step 83. As briefly discussed hereinbefore and as will become more apparant upon consideration of the detailed description of the preferred embodiment of the method of the present invention to follow, various corp-oreal model representations of a selected structure can be constructed in accordance ~ith the present invention.
A scale replica of the internal structure in the state found within the body is constructed from three dimen-sional coordinate data defining the selected structureat scale. If other than a scale replica of the internal structure is desired, data is manipulated at step 84 to obtain transformed three dimensional coordinate data for constructing an altered corporeal model representation of the selected internal structure. The manipulation can be performed at the time of the generation of three dimensional coordinate data from the data provided by the performance of step 83, for example, by generating the three dimensional coordinate data according to an algorithm relating the untransformed three dimensional coordinate data to the desired transformed three dimen-sional coordinate data. Alternatively, the transformed three dimensional coordinate data can be obtained by man-ipulation of generated untransformed three dimensional coordinate data, by manipulation of the data delineating the selecting structure before the generation of the three dimensional coordinate data or`by combinations of the aforementioned maripulations. As will be described in further detail hereinafter with reference to the pref-erred method of the present invention, interpolating,form or curve fitting, scaling and translating are manip-ulations particularly useful in constructing external and implantable prostheses and mold cavities for casting models of selected internal structures. In any case, the three dimensional coordinate data is gen~rated in a format determined by the sculpting device used in con-structing the corporeal model representation of the ~5~2 selected internal structure. The desired corporeal model representation is obtained at step 85 by directing a sculpting tool in accordance with the generated three dimensional coordinate data to follow a trajectory rela-tive to a work piece that produces the representationdefined by the three dimensional coordinate data. The corporeal model is fabricated from suitable material sel-ected according to the expected use of the model.
Examples of material suitable for the construction o prostheses are Silastic and Proplast. "Silastic" is a trademark of Dow Corning Corporation used to identify the material it markets. "Proplast" is a trademark of Vitek, Inc. used to identify the material it markets.
A preferred embodiment of the method of the present invention arranged to construct corporeal models of internal anatomic tissue structures will now be described in detaii with reference to Figures 2-7. The pre~erred embodiment will be described in connection with the construction of prostheses of a mandible. ~ore specifically and referring to Figures 2-4, the mandible 10 of the anatomy 11 is specified three dimensionally by subjecting the anatomy to radiant energy to produce radi-ant energy responses within the anatomy that are characteristic of a selected physical property of substances of and detectable at the exterior of the anatomy. Different substances of the anatomy 11 produce different distinguishable characteristic radiant energy responses which, upon detection, provide distinguishable representations of the different substances located within the anatomy. As will be described in greater detail hereinafterr a computerized tomographic imaging device 13 (Figure 6) utilizing x-ray radiation is employed in the practice of the preferred embodiment of the method of the present invention to obtain distinguishable representations of different substances within the anatomy 11. ~s described hereinbefore, computerized tomography devices provide cross sectional _ g _ ~2~LS~;~
representations of the internal structure of the anatomy 11 reconstructed from radiant energy transmitted through or reflected from the interior of the anatomy along paths at different angles relative to the anatomy. In the x-ray tomographic device 13, a narxow x-ray beam 14 (Figures 5A and 5B) is directed through the anatomy 11 along several paths (such as depicted by arrows 16) in a plane and the radiation transmitted through the anatomy is measured by x-ray detectors 17. A transmission 10 measurement taken along each path represents a composite of the absorption characteristics of all elements in the path of the beam. A computerized data processing system 18 (Figure 6) associated with the x-ray tomographic device 13 manipulates the measurements taken along the several paths according to an algorithm to calculate the attenuation coefficient of elements in each X~ plane 19 (Figure 2~ through which the x-ray beam 14 is directed.
The attenuation coefficients o elements in other planes distributed at spaced locations along the 2 axis perpendicular to the XY planes 19, hence the x-ray beam 14, are obtained by relatively moving the body 11 and the x-ray generation and detection apparatus in increments along a line generally perpendicular to the plane of the x-ray beam. Typically, the body 11 is 25 moved through a stationary scanning station at which the x-ray measurements along the several paths in each XY
plane are obtained by rotating opposltely disposed x-ray generator 26 and x-ray detector 17 devices (Figures 5 and 5B) about the body. The calculated attenuation coefficients provide accurate representations of the densities of the substances within the anatomy. In the processing of the measurements, gray-scale values are assigned to the calculated attenuation coefficient values to provide representations of the elements in each plane 19 suited for displaying an image of the structure of the anatomy 11 at the location of the plane.
~2;~3~5~Z
For example, Figures 3 and 4 schematically illustrate different image reconstructions 20 and 20', respectively, of a single cross section of the anatomy 11 shown in Figure 2 taken at a plane 19 extending through the mandible lQ. As can be seen by inspection of Figure 3 and 4, the light gray scale mandible repres-entative values 10 are readily distinguishable from the darker surrounding gray scale representations of other substances. Greater contrast between the mandible representative gray scale values and the gray scale representations of other anatomic tissue substances at the cross section can be obtained by enhancing the image reconstruction in the manner described hereinafter and shown in Figure 4. In both image reconstructions of Figures 3 and 4, the gray scale representations clearly delineate the surface location 12 of the mandible 10, from which the three dimensional coordinates of the mand-ible are derived. ~ series of such gray scale cross sectional representations of the anatomy 11 obtained along the Z axis provides information from which three dimensional coordinate data can be derived. As will be described in further detail hereinafter, three dimension-al coordinate data specifying a selected structure 10 of which a model is to be constructed is derived from a series of such cross sectional repre`sentations of the anatomy 11.
As mentioned hereinbefore,~other noninvasive radiographic imaging devices can be utilized in the practice of the method of the present invention to obtain cross sectional representations of the body 11 from which the desired three dimensional coordinate data defining the structure 10 of interest can be obtained.
In PET devices, for example, radiant energy originates within the anatomy 11 from an in~ravenously administered biologically active substance labeled with a positron-emitting radioactive isotope. The isotope decays by emitting positrons that travel a short distance in tissue before colliding with electrons. A collision bet-ween a positron and elec~ron annihilates both particles, converting the mass of the two particles into energy divided equally between two gamma rays emitted simultane-ously along oppositely directed paths. One PET devicein use includes arrays of scintillation detectors en-circling the subject supported by a mobile table with the region of interest at the axis about which the detec-tors are disposed. The arrays of detectors record simultaneously emitted gamma rays at a plurality of ~spaced axial cross sections of the subject during an imaging cycle, the detectors being linked in opposite pairs so that emitted gamma rays are recorded only when both detectors of a pair simultaneously sense gamma rays. All gamma ray pairs originating within a volume of the subject defined by the cylindrical, colinear field of view joining paired detectors are sensed.
Gamma rays orginating outside that volume are not sensed by the detectors. The sensed gamma ray responses are processed to obtain representations delineating the sub-stances in the field of view. The mobile table moves the subject axially relative to the encircling detectors to enable the detection of radiant energy events and con-comitant generation of representations of substances at a plurality of spaced axial cross sections of the sub-ject.
NMR imaging devices have the advantage of using a non-ioniæing form of radiant energy. In N~IR
devices, the subject is placed in a strong magnetic field while a brief high frequency signal is beamed at the body. Different atoms of substances of the body res-pond by sending out different characteristic radio sig-nals that are detected by tunable receiving antennas placed about the body. The tunable receiving antennas are adjusted to be responsive to selected radio signals and thereby obtain representations of sele~ted substan-ces, which are processed by an associated computerized 5~
data processing system to generate a distinguishablecharacteristic representation of such substance in a plane of the subject. Representations o substances in other parallel planes at spaced locations along a defined line are obtained by moving the subject in incre-ments through the magnetic field and past the receiving an~ennas.
Ultrasonic radiographic imaging devices also can be employed to obtain representations of the inter-nal structure of a body. Like NMR imaging devices,ultrasonic devices have the advantage of using a non-ion-izing form of radiant energy in obtaining the data from which representations of the internal structure of bodies are derived. Most ultrasonic imaging devices generate representations of anatomic structures from detected reflections of high frequency pulsed sound waves directed through the anatomy. ~ series of pulsed sound waves are sent forth into the anatomy by electri-cally pulsed piezoelectric transducers in contact with the anato~y. The transducers employed are capable of reversibly converting electrical to vibratory mechanical energy at the pulse requenc~ of interest. After the transmission of each short burst or pulse of sound energy, the circuitry associated with the transducer is switched to act as a receiver for returning or reflected echos of the transmitted sound waves. Echos are reflect-ed when the pulsed sound encounters àn interface of tissues of different densities. Tissues of different acoustic impedances return different echos. The reflect-ed echos are converted to representative electrical sig-nals by the piezoelectric transducers, from which planar representations of the internal structure of the anatomy are obtained. The data processing system associated with the ultrasonic device converts elapsed time between transmission of a sound pulse and reception of each echo into a measurement of the distance from the transducer to each location of echo reflection.
5~
Each of the radiographic imaging devices described above provides representations of the internal structure of a body by subjecting the body to selected radiant energy. In x-ray, NMR and ultrasonic devices/
the body is subjected to radiant energy projected at it from a location external to the body. With PET devices, however, the body is subjected to radiant energy genera-ted within the body itself. In any case, each of the imaging devices produces radiant energy responses within a body from which distinguishable representations of different internal structures of the body are generated and from which, in turn, three dimensional coordinates defining a selected structure internal to the body are generated for directing a sculpting tool to form a corp-oreal model representation of the selected internalstructure.
A computerized x-ray tomographic system suited for use in obtaining three dimensional coordinate data deining the mandible 10 of the anatomy 11 in accordance with the preferred embodiment of the method of the pre-sent invention is marketed by General Electric Company under the model designation CT/T 8~00 Scanner System.
The preferred method of obtaining three dimensional coordinate data defining the mandible 10 in accordance with the present invention will now be described with reference to the CT/T 8800 Scanner System, which is schematically illustrated in Figures`5 and 6. The compu-terized x-ray tomographic system 13 (Figure 6) is arranged to produce computer reconstructed cross section-al images of any part of the anatomy from multiple x-ray absorption measurements. The system 13 includes a radi-ation scanning assembly 27 having a mobile table 21 (Figure 5B) for supporting and transporting a subject through the x-ray scanning station 22 along a path indi-cated by arrow 23. The table 21 is configured to aid incentering and confining the anatomy 11 in a selected z orientation relative to the x-ray generator 26 and detec-tor 17 (Figures 5A and 5B) of the scanning assembly.
The radiation scanning assembly 27 also in-cludes a gantry 2~ (Figure 5B) positioned along the path 23 for supporting the x-ray generator 26 and x-ray detec-tor 17 for rotation about the mobile table 21 in a selected plane perpendicular or at an angle to the path 23. The x-ray generator 26 emits an x-ray fan beam 14 that is directed at an array of x-ray radiation sensi-tive cells forming the detector 17 at the opposite sideof the gantry 24. The beam 14 is formed and the detec-tor 17 is arranged to permit scanning of an object detec-tion zone 29 (Figure 5A) located in the plane of the beam. Each cell of the detector 17 detects a portion of the x-ray beam 14 after its passage through the object detection zone 29 (and any part of a body 11 located in the zone) and provides data representative of the comp-osite x-ray radiation attentuation coefficient along a path between the x-ray generator 26 and the data cell.
The data provided by the detector 17 as it and the X-ray generator ~6 are rotated about the subject (borne by the table 21) is processed to generate an attenuation coeffi-cient representation for each volume element 31 (Figure 4) of the cross sections of the anatomy 11 scanned by the x-ray beam 14. The resolution capability of the CT/T 8800 system 13 is dependent upon the fan thickness of the x-ray beam 14 and the power of the data reconstru-ction algorithm characterizing the software program employed in the system. A typical CT/T 8300 system generates an attenuation coefficient representation for a volume element 31 having a size on the order of 1.5mm x 0.8mm x 0.8mm, with the long 1.5mm dimension of the volume element 31 extending in the direction of the fan thickness dimension of the beam 14, hence the cross sec-tion of the anatomy 11 scanned. The other dimensions ofthe volume element 31 in the plane of the scanned cross section are largely determined by the software program, and attenuation coefficient representations of volume elements of smaller dimensions in the plane of the scan-ned cross section can be obtained by increasing the power of the data reconstruction software program.
once the anatomy 11 is positioned as desired relative to the scanning station 22, the mobile table 21 and gantry 24 are operated in sequence under control of the computer 32 to (i) position the anatomy 11 within the scanning station 22 at the desired location along 10 path 23, (ii) rotate the x-ray generator 26 and detector 17 for subjecting a cross sectional slice of the anatomy to the x-ray beam 14 and detecting the resulting radia-tion responses, and (iii) increment the table 21 a dis-tance of 1.5mm for scanning another cross sectional slice of the anatomy with the x-ray beam. This opera-tion of the table 21 and gantry 24 continues until data from the desired number of cross sectional slices of the anatomy 11 is obtained. Data from each cross sectional slice is obtained by pulsing the x~ray generator 26 to send pulses of x-ray radiation through the cross section-al slice along several hundred different paths while the gantry 24 is operated to rotate the x-ray generator 26 and detector 17 about the anatomy 11. This provides the radiation responsive data from which cross sectional representations of the anatomy are reconstructed.
The radiation responses detected by the detector 17 are processed by data acquisition circuitry 33 (Figure 6) of the system 13 under control of the comp-uter 32 for storage in a memory 36. ~ reconstruction data processor 37 is controlled by the computer 32 to reconstruct cross sectional representations of the anatomy 11 from the stored data. More specifically, the reconstruction data processor circuitry 37 is controlled by the computer 32 to manipulate the stored data math-ematically according to a reconstruction algorithm tocalculate the attenuation coefficient for each volume element 31 (Figure 4) of each cross sectional slice of ~Z~5~Z
the anatomy 11. The calculated attenuation coefficientdata is stored in the memory 36 for use as needed. For image display purposes, the calculated attenuation coefficients are converted to gray scale values expressed numerically in Hounsfield units, commonly referred to as "CT numbers".
The computerized data processing system 18 is operable through an operator control system 42 to con-struct various selectable representations of the anatomy 11 from the detected radiation response data. For example, the cross sectional representations of the anatomy can be enhanced by selectively narrowing the gray scale range and/or offsetting the gray scale range relative to the range of attenuation coefficients of sub-stances found in the anatomy~ Figures 3 and 4 schemati-cally illustrate an example of the enhancement of the cross sectional representations of the anatomy 11. In the illustrated example, volume elements 31 having atten-uation coefficients within a selected range or window are assigned one gray scale value, such as white, while all volume elements having attenuation coefficients out-side the selected range or window are assigned a black gray scale value. In this example, the gray scale range is centered at the end of the range of attenuation coefficients where that of bone is found. The operator control system 42 also enables the detected radiation response data to be manipulated to rèconstruct sagittal and coronal cross section representations of the anatomy 11 at one or more selected planes orthogonal to the axial plane of the anatomy. Each of the aforementioned reconstructed cross section representations accurately portrays the internal structure of the anatomy 11 at the cross section location of the representation and, there-fore, may be used in deriving three dimensional coord-inate data for use in constructing corporeal models ofinternal structures of the anatomyO
Data from which the desired three dimensional coordinate information can be derived is available from the computerized x-ray tomographic system 13 in various formats. Digital data representations of the recon-structed cross sections of the anatomy 11 are stored inthe memory 36 and are accessible for use in generating the three dimensional coordinate data. In addition, the system 13 includes an image generation system 28 which is operable to provide a paper printout image in the form of mapped numerical value representations of the reconstructed cross section of the anatomy 11, an analog display of gray scale pictures of the reconstructed cross section, or hard copies of the analog gray scale pictures. More specifically, printouts of mapped numeri-cal value representations of selected reconstructedcross sections of the anatomy 11 is provided by a printer 38 included in the image generation system 28.
Analog gray scale pictures of the reconstructed cross sections can be viewed on the CRT dis~lay 39 and hard copies obtained from the x-ray film camera 41.
Control of the computeri~ed x-ray tomographic system 13 in generating reconstructed representations of cross sections of the anatomy 11 is exercised by the operator through the operator control system 42.
Inasmuch as General Electric Company's CT/T 8800 Scanner - System and operator manuals therefor~ are available from which further details of the construction and operation of system 13 can be determined, such details are not des-cribed herein.
To obtain three dimensional coordinate data of the mandible 10 illustrated in Figure 2, the s~stem 13 is operated to obtain radiation response data from a plurality of contiguous 1.5mm axial cross sections of the entire mandible. The radiation response data is pr~-cessed to reconstruct representations of each axialcross section 20, such as illustrated in Figure 3. To facilitate the reconstruction and use of the axial cross 3LZ~L5~
section data, each axial cross section representation is enhanced as illustrated in Figure 4 to distinguish bone substance from all other substances located at the posi-tion of each axial cross section 20'.
Three dimensional coordinate data defining the mandible 10 can be obtained directly from the digital data generated by the computerized x-ray tomographic system 13 and stored in its memory 36. For example, the system 13 generates and manipulates reconstructed digi-tal data representations of cross section volume ele-ments according to the spatial coordinates of the repres-ented volume elements. By accessing such representa-tions within the system 13 according to their spatial coordinates, the three dimensional coordinates of the 15 surface 12 of the mandible 10 can be obtained directly and automatically from the data stored in the memory 36 of the system.
Three dimensional coordinate data also can be obtained directly from analog gray-scale pictures of the reconstructed representations of the axial cross sec-tions, such as illustrated in Figure 4. Each of the series of pictures of the axial cross sections 20' is composed of known gray scale values from which two planar coordinates is determined, such as X and Y. The 25 distribution of gray scale values in the axial direc-tion, as represented by the series of pictures of axially disposed contiguous cross sections of the anatomy at locations including the mandible 10, provides data from which the third coordinate, Z, is determined.
The spatial coordinates defining the three dimension~l surface of the mandible 10 is determined from the coord inate location of the gray scale value representation of the surface 12. This coordinate determination can be accomplished through various measuring methods, in~lud-ing manually defining analog prints or displays of eachcross section 20' in terms of spatial coordinates.
Alternatively, the determination of the coordinates can ~Z~ 2 be carried out th{ough the use of mechanical aids, such as contour or profile follows. Such aids are used to determine the XY planar coordinates of the reconstructed surface representation 12 in each cross section 20', the third coordinate being given by the axial coordinate Z
of each reconstructed cross section. If all reconstruct-ed cross section representations of the mandible 10 are employed in the generation of the three dimensional coordinate data, the Z axial coordinate data is 10 distributed at intervals corresponding to the center-to-center spacing of the cross sections of the body 11 represented by the reconstructed data. When the recon-structed data is obtained from contiguous cross sections of the body, the Z axial coordinate data is at intervals of 1.5mm.
Printouts of mapped numerical value representa-tions of the reconstructed absorption coefficients of the volume elements of eajch reconstructed cross section also can be used to obtain three dimensional coordinate data defining the surface 12 of the mandible 10. Figure 7 is a schematic illustration of such a printout. To facilitate the illustration of a mapped numerical value image of a reconstructed cross section of the anatomy 11, a reconstructed cross section 20" of the anatomy is divided by lines into regions of identified significant numerical values. The lines also are used to identify surface boundaries of significant structures internal to the anatomy 11. As discussed hereinbefore, the recon-structed attenuation coefficients are expressed as a Hounsfield unit and are commonly referred to as "CT num-bers". In the CT/T 8800 system 13, the range of CT num-bers extends from -1000 (which represents air) to +1000 (which represents dense bone). A CT value of 0 repres-ents water. The three dimensional coordinate data defin-ing the surface 12 of the mandible 10 can be obtainedfrom the printouts of mapped CT values in the ways described hereinbefore with reference to the ~se of ~2~5~
analog gray scale pictures or displays of reconstructedaxial cross sections. When using printouts of mapped CT
values defining reconstructed cross sections 20" of the mandible, the three dimensional coordinates defining the surface of the mandible are determined by following the contour of numerical CT values delineating the recon-structed surface 12 of the ~econstructed mandible 10, instead of the contour delineated by a line in an analog gray scale picture or display.
A preferred method of sculpting a corporeal model of a segment 51 (Figures 2-4) of the mandible 10 in accordance with the present invention will now be des-cribed with reference to the machine-controlled contour sculpting tool apparatus 52 illustrated in Figures 8A-15 8C. The machine-controlled sculpting tool apparatus 52 is arranged to control a cutting tool 53 in accordance with cylindrical coordinates defining the shape of the desi~red corporeal model representation of the mandible 10. Therefore, the recon~tructed tomo~raphic representa-tions of the anatomy 11 generated by the computerized x-ray tomographic system 13 illustrated in Figure 6 are utilized to derive radial (r), angular (~) and axial (z) coordinates describing the surface 12 of the mandible segment 51 relative to a selected reference line. ~ref-erably, the selected reference line is a straight linepassing through a point lying along the centric of the mandible segment 51. The reference line is depicted in Figures 2, 3 and 4 by a broken line 54 of alternate long and short lengths. The axial coordinate z e~tends along the reference line 54, and the radial r and angular 9 coordinates are in plane perpendicular to the reference line 54. The deriviation of the cylindrical coordinates relative to the reference line 54 is facilitated by posi-tioning the subject within the scanning station 22 and/or tilting the gantry 24 relative to the mobil table 21 so that the reference line 54 is generally perpendi-cular to the plane of the x-ray beam 14. In this way, ~LZ~5~:
the x-ray tomographic system 13 is operated to provide a series of oblique ~iOe, other than axial, coronal or sag-gital) cross sectional representations of the mandible segment 51 in parallel planes distributed along and per-pendicular to the line 54, with of each cross sectionalrepresentation centered on the line 54. Such positioning reduces the amo~nt of data processing time re~uired to ob~ain the cross sectioned representations from the detected radiant energy responses and, hence, 10 the three dimensioned coordinates of interest. However, such subject positioning and/or gantry tilting is unnecessary when a radiographic tomographic system 13 is employed that is capable of reconstructing oblique cross section representations of internal anatomic structures 15 from radiant energy responses obtained from a subject oriented in the standard supine position with the axis of the body perpendicular to the cross sections of the body ~rom which the radiant energy responses are obtained.
A work piece of a material suitable for con-structing the desired prosthesis is secured to a rotat-able turntable 58 that is coupled to a drive motor 59 by a drive shaft 61. To form the desired model, the drive motor 59 rotates the workpiece 57 about the axis 62 as 25 the trajectory of the cutting tool 53 is controlled to form the desired contour in the workpiece. The axis 62 of rotation of the workpiece 57 is lo~cated to pass through the origin relative to which the c~utting tool 53 is moved in the radial and axial directions in accord-30 ance with the cylindrical coordinates. The origin islocated at a point along re~erence line 54 (Figures 2-4), which for convenience is selected to be at one end 55 of the mandible segment 51 being modeled. In the example, the origin is located at the end 55 o~ the mand-35 ible segment 51 closest to the hinge segment 50 o themandible 10. In generating the three dimensional cylin-drical coordinates from the data obtained by the x-ray ~z~s~z tomoyraphic system 13, the cylindrical coordinates are specified relative to an origin that is to be coincident with the origin of the coordinate system used in the sculpting tool apparatus 52 to specify the spatial loca-tion of the cutting tool 53. The origin of the coordin-ate system of the sculpting tool apparatus illustrated in Figures 8A-8C is located a short distance above the turntable 58.
The cutting tool 53 is moved in the axial z and radial r directions relative to the axis 62 in accordance with the cylindrical coordinate data by coop-erating way and carriage assemblies. Movements in the radial direction, r, are governed by a horizontally extending way 64 and a cooperating carriage 65 that 15 carries the cutting tool 53 for movement along the hori-zontal way. Movements in the axial direction, z, are governed by a pair of vertically extending ways 66a and 66b and cooperating carriages 67a and 67b that support the horizontal way 64 for movement along the vertical way. In the preferred embodiment, the ways 64 and 66 are motor driven lead screws that engage lead screw nut assemblies forming the cooperating carriages 65 and 67.
More specifically, each o~ the vertical lead screws 66a and 66b extends between one of the reversible motors 43a and 43b and one of the cooperating journals 44a and 44b.
The driven end of each lead screw is coupled for rota-tion by the operatively associated motor and the oppos-ite end of that lead screw is seated for rotational sup-port within the cooperating journal. The two motors 43a and 43b are operatively coupled together by a timing chain 45 that maintains the motors in synchronism so that the two lead screws 66a and 66b are synchronously rotated by the two motors. Activation of the motors ~3a and 43b rotates the lead screws 66a and 66b in a direc-tion determined by the controlling cylindrical coordin-ate data, which causes the engaged lead screw nut ~;Z~5~Z
assemblies 67a and 67b to move in the corresponding direction along the rotated lead screws.
Each lead screw nut assembly 67a and 67b is fastened to one of the suppor~ plates 68a and 68b, the two plates serving to support the motor driven horizon-tal lead screw 64, cooperating lead screw nut 65 and cutting tool 53 assemblies relative to the lead screw nut assemblies 67a and 67b and cooperating lead screws 66a and 66b. The driven end of the horizontal lead 10 screw 64 i5 coupled for rotation by a motor ~6 fastened to the support plate 68a. The horizontal lead screw 64 extends from its driven end to an opposite end supported for rotation within a journal 47 fastened to the support plate 68b. The lead screw nut assembly 65 bears a mount-ing plate 69 on its upper side, upon which is fastened amotor 70 for rotating a spindle 71 that carries the cut-ting tool 53 for cutting the workpiece 57. Activation of the motor 46 turns the lead screw 64 in a direction determined by the controlling cylindrical coordinate data, which causes the engaging lead screw nut assembly 65 to move in the corresponding direction along the lead screw.
In the preferred embodiment o~ the machine tool apparatus 52, the work piece 57 is located at one side of the structure that supports the cutting tool 53.
To permit ready access to the work piece 57 by the cutt-ing tool 53 along radially and axially adjustable paths, the vertical lead screws 66a and 66b are horizontally displaced to one side of the horizontal lead screw 64.
Additional support for the cutting tool sup-port and positioning apparatus is provided by four verti-cally extending stationary posts 72 and cooperating sleeve bearings 73. A post 72 is located at each end of eacb of the support plates 68a and 68b. The sleeve bear-ings 73 couple the support plates 68a and 68b to the posts 72 for support while permittin~ the support plates to move relative to the posts when the lead screws 6Sa ~z~s~
and 66b are turned to move the cutting tool 53 in the axial direction, z.
The preferred machine tool apparatus 52 is arranged for constructing models of a wide variety of S sizes. For this reason, the cutting tool 53 is support-ed by a long spindle 71 for movement over a large dis-tance in the radial direction, r. To aid in maintaining the cutting tool 53 in the axial position specified by the cylindrical coordinate data, the spindle 71 is supported for rotational and radial movements by a journ-al 74 at the support plate 68b nearest the turntable 58.
The journal 74 is supported by a platform 75 joined at the top edge of the support plate 68b to extend horizon-tally therefrom in the direction opposite the turntable 58.
The various motors of the machine-controlled contour sculpting tool apparatus 52 are synchronously controlled by the machine tool controller 63 in accord-ance with the cylindrical coordinate data derived from the series of oblique cross sectional representations of the mandible 10 so that the work piece 57 is cut to have a contour corresponding to that represented by the cylin-drical coordinates. More specifically, the derived cylindrical coordinate data is stored in a memory 56 for use by the machine tool controller 63 in controlling the trajectory of the cutting tool relative to the work piece 57. The machine tool controller provides commands to a motor drive circuit 76 coupled to drive the rotary cutting tool 53 at a selected speed suitable for sculpt-ing the work piece 57 into the desired form and finish.In addition, the controller 63 provides commands to the three motor drive circuits 77, 78 and 79, which are coupled respectively to synchronously drive the radial position determining horizontal lead screw motor 46b, the axial position determining vertical lead screw motors 43a and 43b, and the turntable motor 59. Thes~
later commands are provided i~ accordance with ~;~0~5~2 cylindrical coordinate data so that the turntable 58 is rotated and the cutting tool 53 moved relative to the axis 62 whereby the tool follows a trajectory relative to the workpiece 57 productive of the formation of a model that accurately represents the mandible segment 51~
The machine tool controller 63 is arranged to issue commands to the axial motor drive circuit 78 to step the cutting tool 53 in increments along the rota-tional axis 62 of the turntable 58 so that the workpiece 57 is cut along concentric bands, with each band at a location along the axis 62 corresponding to the loc-ation of a plane along line 54 at which a cross section-al representation of the mandible 10 is obtained. In addition, the machine tool controller 63 is able to process the cylindrical coordinate data to calculate, by linear interpolation, the change in the axial coordinate z as a function of the angular coordinate ~ between adja-cent locations of cross sectional representations of the mandible 10. This calculation provides axial and angu-lar coordinate data permitting the cutting tool 53 to be directed along a spiral trajectory in sculpting the work piece 57.
The preferred embodiment of the controlled con-tour machine tool apparatus 52 employs stepping motors for driving the lead screws 64 and 6S and turntable 58.
The apparatus 52 is controllable to ~otate the turntable 58 in steps as small as fractions of an angular minute and to move the rotary cutting tool 53 in the radial, r, and axial, z, directions in steps as small as fractions of a millimeter. For constructing a prosthesis of an internal anatomic tissue structure, such as mandible 10, however, turntable rotation steps on the order of one or two degrees and cutting tool radial and axial movement steps on the order of tenths of a millimeter are satis-factory.
5~L2 The preferred method of the present invention has been described in detail with reference to sculpting a corporeal model replica of a segment 51 of a mandible 10 using a machine-controlled contour sculpting tool apparatus 52 having a single cutting tool 53 controlled in accordance with cylindrical coordinates that define a three dimensional representation of the segment.
However, it will be appreciated that machine-controlled contour sculpting tool apparatus arranged to control the trajectory of a cutting tool specified by three dimen-sional Cartesian coordinates can be employed in the method o~ the present invention to form the corporeal model. Moreover, machine-controlled contour sculpting tool apparatus having a plurality of independently con-trollable cutting tools can be used to ~orm the corp-oreal model in accordance with the method of the present invention. The particular nature of the machine-control-led contour sculpting tool apparatus 52 employed to con-struct a corporeal model representation of a selected structure 10 internal to a body 11 does effect the gener-ation of the three dimensional coordinate data from the cross section representations of the selected structure provided by the tomographic imaging device 13. In some applications, it may be necessary or convenient during the generation and/or use of the three dimensional coord-inate data to translate the coordinate data between diff-erent coordinate systems or between different spatially oriented sets of axes in the identical coordinate system. For example, translations between the Cartesian and cylindrical coordinate systems is achieved by manipu-lating the coordinate data defining each cross section representation of the selected structure 10 according to the coordinate translating equations relatiny rectangu-lar and polar coordinates. Translations between differ-ent spatially orientated sets of axes is achieved by man-ipulating the coordinate data according to vector ~z~s~
normalization equations relating the differently orientated sets of axes.
Thus far, the method of the present inYention has been described in detail as practiced to construct a corporeal model replica of the selected segment 51 of the mandible 10. It should be appreciated, however, that other model representations of a selected structure internal to a body can be constructed through the prac-tice of the method of the present invention. For 10 example, a mold cavity representation of the selected mandible segment 51 can be constructed from which one or more corporeal model replicas of the segment-can be cast. To facilitate the construction of the cavity, it is made in two mating half sections extending in the 15 direction of the line 54. The three dimensional coordin-ate data is generated from the cross section representa-tions ~or translated from previously generated coordin-ate data defining the surface 12 of the segment 51) to define a mating cavity form of each half of the surface 20 12. This coordinate data is employed by the machine-controlled contour sculpting tool apparatus 52 to direct the cutting tool 53 along a trajectory that produces one of the mold cavity half sections from a first work piece 57 and the other of the mold cavity half sections from a 25 second work piece. In sculpting each mold cavity half section, the turntable 58 is incremented slowly to rotate the work piece 57 about the axis 62 at a speed that permits the cutting tool 53 to cut the work piece to the desired shape along a series of parallel radial/axial trajectories relative to the axis 62.
Another salient feature of the method of the present invention relates to the construction of altered corporeal model representations of structures internal to a body. The formation of altered model representa-tions of internal body structures is particularly usefulin the construction of surgically implantable prostheses. Often, a prosthesis is made to replace a 5~2 missing anatomic structure, in which case a representa-tion of the desired prosthesis form will not appear, for example, in the set of cross section images provided by a tomographic imaging device. In accordance with the method of the present invention, however, altered three dimensional coordinate data that de~ines a representa-tion of the missing structure is generated from the set of cross section images that is obtained for use in form-ing a prosthetic model of the missing structure. As will become more apparent from the following detailed description, formation of altered three dimensional representations of structures is particularly useful in constructing prosthetic onlays and inlays. Coordinate transformation is one technique suited to the generation of three dimensional coordinate data for the construc-tion of prosthetic onlays and inlays in accordance with the method of the present invention. An example of the use of coordinate transformation in the construction of a prosthetic onlay will now be described with reerence to Figures 9A and 9B. The coordinate transormation is described as undertaken in the Cartesian coordinate system. However, such transformations can be undertaken in the cylindrical coordinate system as well.
To obtain the necessary coordinate data to construct a prosthesis of, for example, an atrophic mand-ible 91 illustrated in Figures 9A and 9B, data yrids 92, 93 and 94 encompassing the atrophic segment of the mand-ible 91 (indicated by shading in Figure 9A) are identified. Within the identified data grids, three dimensional X, Y, Z coordinates are established for determining the amount and nature of the desired coordinate translation. ~his can conveniently be accomplished with the aid of an ima~e processor, such as the image proces~or marketed by Grinnell, Inc., under the model designation System 271. The Grinnell system is designed to function with a Disital Equipment Corporation (DEC) LSI-11/23 computer apparatus having industry standard I/O data communication terminals, a video terminal and monitor, graphic tablet and graphic printer. The Grinnell image processor and DEC computer apparatus form an image processin~ system arranged to interact with an operator for purposes of image generation and alteration. Image data can be input to the image processing system either from the graphic tablet or from external graphic data sources connected to an I/O data communication terminal of the system.
For the purpose of translating the surface of the atrophic mandible 91, the cross section image repres-entations generated by the CT/T 8800 system 8800 are con-verted to a data format compatible with the image pro-cessing system and input to that system for display and image manipulation purposes through an I/O data communi-cation terminal. The image processing system is oper-able to display two dimensional or three dimensional per-spective representations of objects. The desired coord-inate translation is determined by displaying either a three dimensional representation of the atrophic mand-ible 91 or a sequence of two dimensional cross section representations of the atrophic mandible 91. Cross sections of the mandible generally perpendicular to its centric are preferred for this purpose. By use of the graphic tablet of the image processing system, the atrophic superior surface S of the mandible 91 e~tending from point 92 to point 93 is transla~ed in the direction indicated by the arrows in Figures 9A and 9B to the desired new location S' to form an image of the desired altered mandible.
The translation of the atrophic superior sur-face S can be accomplished in one step, for example, using a three dimensional display of the atrophic mandi-ble 91 (such as seen in Figure 9A), or it can be done cross section-by-cross section using two dimensional images of the atrophic mandible (such as seen in ~igure 9B) at locations along its centric line. In either - 30 ~
L5~2 case, the superior surface is translated by manipulating the graphic tablet instrument while observing the results of the manipulations on the video monitor and operating the image processing system to delete the S atrophic surface S, represented in Figures 9A and 9B as a solid line bounding mandible 91, and create the translated surface S' at the location of the dotted line in Figures 9A ands 9B.
As seen in Figures 9A and 9B, all coordinate points on the new surface S' are displaced relative to the corresponding locations on the atrophic surface S by a uniform distance q in the direction of the Z axis.
For some prostheses, it may be necessary to move differ-ent coordinate points along the atrophic superior sur-face S by different amounts or by an amount that variesin the direction of a selected dimension of the structure according to a defined gradient. If the atrophic superior sur~ace S is irregular, for example, different coordinate translation distances would be required to create a translated regular surface S'. The three dimensional coordinate representation of the desir-ed altered mandible can be derived fxom the altered mand-ible image data present in the Grinnell image processing system in ways like those described hereinbe~ore with 2s reference to the CT/T 8800 system.
Using an image processing system to translate and generate three dimensional coordinate data defining a desired altered structure has the advantage of enabling inspection and adjustment of the translation to produce the desired altered structure before generating the defining three dimensional coordinate data~ When constructing implantable prostheses, for example, it is desirable to preview the translation and adjust it until the displayed altered structure mates with the displayed unaltered structure. This is help~ul in constructing an implantable prosthesis that properly mates with the surrounding anatomic structures. However, the desired ~z~s~
translation and generation can be accomplished in other ways as well. For example, new coordinate data can be obtained by manipulation of the atrophic mandible coord-inate data derived from the CT/T ~800 image representa-tions of the atrophic mandible 910 In either case, the three dimensional coordinate data specifying the altered mandible is obtained by adding a coordinate value corres-ponding to the distance q to the Z axis coordinate value for all specified coordinate points of the atrophic sur-face S.
For purposes of constructing an implantableprosthetic onlay, only the altered segment of the alter-ed mandible 91 is required. A three dimensional coordin-ate specification of only the altered segment is obtain-ed by substracting each Z axis coordinate value definingthe atrophic superior surface S from the axis coordinate value of the translated new surface S' at the correspond-ing X and Y coordinate locations. An implantable prosthetic onlay is formed according to the remainder coordinate values.
Models of deformed or missing segments of internal structures also can be constructed from coordin-ate data specifying the deformed or missing segment that is derived from representations of a normal mirror image segment of the structure. For example, coordinate data defining a mirror image segment of a structure is useful in the construction of an implantablè prosthetic inlay that is to replace a missing segment of a generally sy D etrical internal anatomic structure. Derivation of the mirror image coordinate data can be accomplished through the use of the above-described Grinnell image processor or by manipulation of the coordinate data derived from the data representations provided by the CT/T 8800 system 13. If the image processor is employ-ed, the deformed, but otherwise generally symmetricalstructure is displayed and the deformed or missing seg-ment is altered to the desired form by operator ~2(~5-~Z
manipulation of the graphic tablet, using the video monitor display of the mirror image segment of the structure as a guide. The desired three dimensional coordinate data is generated from the altered segment as described hereinbe~ore with reference to Figures 9A and 9~ .
However, the mirror image coordinate data can be obtained directly from the three dimensional coordin-ate data defining a normal ~egment of an internal struc-ture that is generated directly from the image represent-ations provided by the CT/T 8800 system 13. Referring to Figure 10, a deformed mandible 97 is illustrated in relation to three dimensional X, Y, Z coordinates~ But for the deformation, the mandible is generally symmetri-cal about the Y-Z plane extending through the most anterior point 99 of the mandible 97. ~s seen in Figure 10, the deformation is in the form of a missing segment 100 located at the left side of the XY plane of symmetry. A normal segment 96 of the mandible 97 exists to right of the nominal XY plane of ~eneral symmetry at the mirror image location relative to the missing segment 100. This segment 96 is surrounded by an enclosure 98 that defines data grids including the three dimensional X, Y, Z spatial coordinates defining the normal segment 96. The actual and mirror image coordinates of the normal segment 96 are the same relative to the Y and z coordinate a~es, but are different relative to the X coordinate axis. To obtain the mirror image X coordinate, the distance separating the actual X coordinate value of each coordinate point specifying the normal segment 96 from the X coordinate value of the location of the XY plane of symmetry is multiplied by (-1) and is added to the X coordinate value of the location of the XY plane of symmetry. This coordinate translation technique enables the generation of the mirror image coordinate values of the normal segment 96 by manipulation of the three dimensional 5~
coordinate data generated directl~ from the i~age representations obtained by the CT/T 8800 system 13.
For convenience, the derivation of translated coordinate data has been described ~ith reference to coordinate manipulation in the Cartesian coordinate system and cross section representations of the internal structure that are defined three dimensionally in rela-tion to orthogonal X, Y, Z axes that are oblique to the axial, coronal and sagital planes. Translation of the 10 coordinates from that axis orientation to any other desired axis orientation or to a cylindrical coordinate system can be accom~lished as described in detail herein-before. However generated, three dimensional coordinate data in the form required by the machine-controlled 15 contour sculpting tool apparatus 52 is generated from the translated representations and input to the sculpting tool apparatus to control the trajectory of the cutting tool 53 so that the desired altered corp-oreal model representation of the selected internal structure is formed.
The method of the present invention has been described in detail wi~h reference to the construction of various corporeal model representations of structures internal to bodies from coordinate data obtained from reconstructed representations of contiguous cross sections of the structures. However, corporeal models can be constructed from coordinate d~ta obtained from reconstructed representations of cro~s sections at spaced intervals along the structure as well. For example, a generally uniform structure, such as the femur bone, can be represented by reconstructed representations taken from widely spaced locations along its length. In such applications, the three dimensional coordinates required for the control of the sculpting tool between the widely spaced locations is generated by interpo-lat.ion of the locations of the selecte~
structure intermediate to the spaced locations and ~z~s~L%
generating corresponding three dimensional coordinates that define the interpolated locations. The corporeal model is formed by directing the sculpting tool in accordance with the three dimensional coordinates that define the spaced and intermediate locations of the selected structures.
One preferred embodiment and certain varia-tions of the method of the present invention have been described in detail as arranged to construct corporeal 10 models of selected internal anatomic structures useful in the study of internal structures of anatomies and in the surgical correction of deformed internal structures.
It will be apparent to those skilled in the art, however, that various modifications and changes may be 15 made in the practice and use of the method without departing from the scope of the present invention as set forth in the following appended claims.
Claims (31)
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:
1. A method of fabricating a three dimensional corpo-real model of a structure internal to a body, comprising sub-jecting the body to radiant energy to produce radiant energy responses internal to said body, the radiant energy selected to produce radiant energy responses that are characteristic of a selected physical property of substances detectable exterior of the body; detecting produced radiant energy responses to obtain representations of substances at locations internal to the body defining structures internal to said body three-dimensionally; generating from the representations of the sub-stances a set of three dimensional coordinates defining a three dimensional representation of a selected structure internal to the body; and directing a sculpting tool into a workpiece in accordance with the generated set of three dimen-sional coordinates to form a corporeal model corresponding to the three dimensional representation of the selected struc-ture.
2. The method of claim 1 wherein the subjecting step and detecting step are performed exterior to the body in which said selected structure is located.
3. The method of claim 1, further comprising: dis-playing a visual representation of the selected structure de-fined by the set of three dimensional coordinates; and select-ively adjusting the three dimensional coordinates; and wherein the sculpting tool is directed into the workpiece in accord-ance with the adjusted three dimensional coordinates.
4. The method of claim 1 wherein: the generated set of three dimensional coordinates defines an altered three dimensional representation of the selected structure; and the formed corporeal model corresponds to the altered three dimen-sional representation of the selected structure.
5. The method of claim 4 wherein a set of transformed three dimensional coordinates are generated from the obtained representations of the substances to define the altered three dimensional representation of the selected structure, further comprising: displaying a visual representation of the altered three dimensional representations of the selected structure defined by the set of transformed three dimensional coordin-ates; and selectively adjusting the transformed three dimen-sional coordinates; and wherein the sculpting tool is directed into the workpiece in accordance with the transformed and sel-ectively adjusted three dimensional coordinates.
6. The method of either claim 3, 4 or 5 wherein: the generated set of three dimensional coordinates defines an un-uniformly altered three dimensional representation of the sel-ected structure; and the directed sculpting tool forms a corp-oreal model corresponding to the ununiformly altered three di-mensional representation of the selected structure.
7. The method of claim 6 wherein the generated set of three dimensional coordinates defines an altered three dimen-sional representation of the selected structure having a sel-ected surface segment altered in a coordinate direction to effect a unidirectional translation of a corresponding select-ed surface segment in the formed corporeal model.
8. The method of either claim 3, 4 or 5 wherein: the generated set of three dimensional coordinates defines a mir-ror image three dimensional representation of the selected structure; and the directed sculpting tool forms a corporeal model corresponding to the mirror image three dimensional representation of the selected structure.
9. The method of claim 8 wherein: the selected structure is a segment of a larger structure internal to the body having a nominal plane of general symmetry; and the gen-erated set of three dimensional coordinates defines a three dimensional representation of a mirror image of the selected structure taken relative to a mirror plane located at the nom-inal plane of general symmetry.
10. The method of claim 1 wherein the selected struc-ture is a segment of a larger structure internal to the body having a nominal plane of general symmetry, and said segment is located at one side of said nominal plane of symmetry, fur-ther comprising: transforming the three dimensional coordin-ates generated from the obtained representations of substances to define a mirror image three dimensional representation of the segment; and wherein the sculpting tool is directed into the workpiece in accordance with the transformed three dimen-sional coordinates to form a mirror image corporeal model of the segment corresponding to the mirror image three dimension-al representation.
11. The method of claim 10, further comprising: dis-playing a visual representation of the mirror image three di-mensional representations of the segment defined by the trans-formed three dimensional coordinates; and selectively ad-justing the transformed three dimensional coordinates; and wherein: the sculpting tool is directed into the workpiece in accordance with the transformed and selectively adjusted three dimensional coordinates.
12. The method of claim 1 wherein: the generated set of three dimensional coordinates defines a three dimensional mold cavity representation of the selected structure; and fur-ther comprising directing the sculpting tool into the work-piece to form a mold cavity in accordance with the three di-mensional mold cavity representation; casting a corporeal model replica of the selected structure defined by the mold cavity.
13. The method of claim 1 wherein: representations of the substance are obtained for spaced locations defining sur-faces of structures; and the generated set of three dimension-al coordinates includes coordinates of spaced locations defining a three dimensional representation of the surface of the selected structure; and further comprising interpolating locations of the surface of the selected structure intermed-iate to the spaced locations and generating from said inter-polations of the intermediate locations three dimensional co-ordinates defining the surface of the selected structure at locations between spaced locations; and wherein the sculpting tool is directed into the workpiece in accordance with the three dimensional coordinates of the spaced locations and of the interpolated locations.
14. A method of fabricating a three dimensional corpo-real model of a selected structure internal to a body by a sculpting tool from three dimensional coordinates defining a three dimensional representation of said selected structure, said data obtained by subjecting the selected structure within the body to radiant energy selected to be productive of sel-ected radiant energy responses that are characteristic of sub-stances and detectable at the exterior of said body, detecting the radiant energy responses to obtain representations of the selected structure, and generating from the representations the three dimensional coordinates, comprising: directing the sculpting tool into a workpiece in accordance with the gen-erated three dimensional coordinates to form a corporeal model corresponding to the three dimensional representation of the selected structure.
15. The method of claim 14 wherein: the generated three dimensional coordinates data define a three dimensional mold cavity representation of the selected structure; and fur-ther comprising directing the sculpting tool into the work-piece to form a mold cavity in accordance with the three di-mensional mold cavity representation; casting a material rep-lica of the selected structure defined by the mold cavity.
16. The method of claim 14 wherein: representations of the substances are obtained for spaced locations defining surfaces of structures; the generated three dimensional coord-inates include coordinates of spaced locations defining a three dimensional representation of the surface of the sel-ected structure; and further comprising interpolating loca-tions of the surface of the selected structure intermediate to the spaced locations and generating from said interpolations of the intermediate locations three dimensional coordinates defining the surface of the selected structure at locations between spaced locations; and wherein the sculpting tool is directed into the workpiece in accordance with the three dimensional coordinates of the spaced locations and of the interpolated locations.
17. A method of generating three dimensional coordin-ates for directing a sculpting tool to form a three dimension-al corporeal model of a structure internal to a body, compris-ing: subjecting the body to radiant energy to produce radiant energy responses internal to said body that are characteristic of substances and detectable at the exterior of the body;
detecting produced radiant energy responses to obtain repres-entations of substances at locations internal to the body de-fining structures internal to the body three dimensionally;
and generating from the representations of the substances three dimensional coordinates defining a three dimensional representation of a selected structure internal of the body, the three dimensional coordinates generated for directing the sculpting tool into a workpiece to form a corporeal model cor-responding to the three dimensional representation of the sel-ected structure.
detecting produced radiant energy responses to obtain repres-entations of substances at locations internal to the body de-fining structures internal to the body three dimensionally;
and generating from the representations of the substances three dimensional coordinates defining a three dimensional representation of a selected structure internal of the body, the three dimensional coordinates generated for directing the sculpting tool into a workpiece to form a corporeal model cor-responding to the three dimensional representation of the sel-ected structure.
18. The method of claim 17 wherein the generated three dimensional coordinates define an altered three dimensional representation of the selected structure.
19. The method of claim 17, further comprising: dis-playing a visual representation of the selected structure defined by the generated three dimensional coordinates; and selectively adjusting the three dimensional coordinates; and wherein the three dimensional coordinates generated for directing the sculpting tool correspond to the adjusted three dimensional coordinates.
20. The method of claim 19 wherein transformed three dimensional coordinates are generated from the obtained repre-sentation of the substances to define an altered three dimen-sional representation of the selected structure; a visual representation of altered three dimensional representation of the selected structure is displayed; and the transformed three dimensional coordinates are selectively adjusted.
21. The method of claim 17 wherein the generated three dimensional coordinates define a three dimensional mold cavity representation of the selected structure.
22. The method of claim 17 wherein: representations of the substances are obtained for spaced locations defining surfaces of structures; and the generated three dimensional coordinates include coordinates of spaced locations defining a three dimensional representation of the surface of the selected structure; and further comprising interpolating loca-tions of the surface of the selected structure intermediate to the spaced locations and generating from said interpolations of the intermediate locations three dimensional coordinates defining the surface of the selected structure at locations between spaced locations; and wherein the three dimensional coordinates generated for directing the sculpting tool include the three dimensional coordinates generated from the inter-polations of the intermediate locations.
23. A method of fabricating a three dimensional corpo-real model of selected tissue structure internal to an ana-tomy, comprising: subjecting the anatomy to radiant energy to produce radiant energy responses internal to said anatomy that are characteristic of tissue structure of said anatomy and that are detectable at the exterior of said anatomy at a plur-ality of locations each of which is along a path extending in a different selected direction relative to the selected tissue structure; detecting produced radiant energy responses at the exterior of the anatomy at selected locations of the plurality of locations to obtain representations of the selected tissue structure that are definitive of a selected three dimensional representation thereof; generating from the obtained repres-entations of the selected tissue structure selected three dimensional coordinates defining the selected three dimension-al representation of the selected tissue structure; and directing a sculpting tool into a workpiece in accordance with the generated selected three dimensional coordinates to form a corporeal model corresponding to the selected three dimension-al representation of the selected tissue structure.
24. The method of claim 23 wherein transformed three dimensional coordinates are generated from the obtained representations of the selected tissue structure to define an altered selected three dimensional representation of the sel-ected tissue structure.
25. The method of either claim 23 or claim 24, further comprising: displaying a visual representation of the select-ed tissue structure defined by the three dimensional coord-inates generated from the obtained representations; select-ively adjusting the generated three dimensional coordinates to define the selected three dimensional representation of the selected tissue structure; and wherein the sculpting tool is directed into the workpiece in accordance with the adjusted three dimensional coordinates.
26. The method of claim 23 as arranged to fabricate a surgically implantable prosthesis type corporeal model of a selected skeletal tissue structure of a mammalian anatomy wherein: the mammalian anatomy is subjected to radiant energy to produce radiant energy responses at locations definitive of the surgically implantable prosthesis to be fabricated; and the generated three dimensional coordinates define a three dimensional representation of the surgically implantable pros-thesis.
27. The method of claim 26 wherein the sculpting tool is directed into the workpiece to form the surgically implant-able prosthesis.
28. The method of claim 26 wherein: the generated three dimensional coordinates define a three dimensional mold cavity representation of the surgically implantable pros-thesis; and the sculpting tool is directed into the workpiece to form a mold cavity in accordance with the three dimensional mold cavity representation; and further comprising casting a surgically implantable prosthesis defined by the mold cavity.
29. A method of fabricating a prosthesis representa-tive of a selected tissue structure internal to a mammalian anatomy, comprising: subjecting the anatomy to radiant energy; detecting exterior of said anatomy, resulting radiant energy responses produced at a plurality of parallel planes distributed at spaced locations in a selected direction rela-tive to the said anatomy, the radiant energy selected to pro-duce radiant energy responses internal to said anatomy that are characteristic of tissue structure of the anatomy and that are detectable from the exterior of said anatomy, the anatomy subjected to the radiant energy and resulting radiant energy responses detected to be productive of selected representa-tions of the structure internal to the anatomy definitive of the prosthesis to be fabricated; generating from the selected representations of the structure internal to the anatomy sel-ected three dimensional coordinates defining a selected rep-resentation of the prosthesis; and directing a sculpting tool into the workpiece in accordance with the generated selected three dimensional coordinates to form the selected representa-tion of the prosthesis.
30. The method of claim 29 wherein the selected rep-resentation of the prothesis is a replica of the selected tis-sue structure.
31. The method of claim 29 wherein: the generated three dimensional coordinates define a three dimensional mold cavity representation of the prosthesis; and the sculpting tool is directed into the workpiece to form a mold cavity in accordance with the three dimensional mold cavity representa-tion; and further comprising casting a prosthesis defined by the mold cavity.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
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US06/384,646 US4436684A (en) | 1982-06-03 | 1982-06-03 | Method of forming implantable prostheses for reconstructive surgery |
US384,646 | 1982-06-03 |
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CA1201512A true CA1201512A (en) | 1986-03-04 |
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CA000429520A Expired CA1201512A (en) | 1982-06-03 | 1983-06-02 | Method of forming implantable prostheses for reconstructive surgery |
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US3259022A (en) * | 1963-12-17 | 1966-07-05 | Ibm | Object scanning techniques |
US3796129A (en) * | 1970-09-25 | 1974-03-12 | J Cruickshank | Apparatus for the manufacture of three-dimensional reproduction of an object |
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1982
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- 1983-06-02 CA CA000429520A patent/CA1201512A/en not_active Expired
- 1983-06-03 JP JP58098131A patent/JPH062137B2/en not_active Expired - Lifetime
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US4436684B1 (en) | 1988-05-31 |
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DE3366423D1 (en) | 1986-10-30 |
US4436684A (en) | 1984-03-13 |
EP0097001B1 (en) | 1986-09-24 |
EP0097001A1 (en) | 1983-12-28 |
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