Medical device for surgical navigation system and corresponding method of manufacturing

Abstract

A device and manufacturing method for a surgical navigation system, comprising a frame member having an attachment location and a rigid mounting device disposed in the attachment location. The frame member comprises an upper straight portion connected to a lower straight portion via a bent portion, wherein the lower straight portion comprises a plurality of mounts each having a top surface. A centerline extending through the rigid mounting device is level with each of the top surfaces.

Claims

1. A device for a surgical navigation system, comprising: a frame member having an attachment location; a rigid mounting device disposed in the attachment location; and wherein the frame member comprises an upper portion connected to a lower portion via a bent portion, wherein the lower portion comprises a plurality of mounting posts each having a top surface, wherein a centerline extends through the rigid mounting device such that a horizontal plane running through the centerline aligns with each of the top surfaces, wherein marker elements are mounted to the plurality of mounting posts such that upon mounting, a centerline of the marker elements aligns with the centerline extending through the rigid mounting device.

2. The device of claim 1, wherein the marker elements are spherical.

3. The device of claim 2, wherein the marker elements are light-reflecting spherical markers.

4. The device of claim 1, wherein the frame member is plastic.

5. The device of claim 4, wherein the plastic is selected from one of a polycarbonate, polyetheretherketone, and a polyetherimide material.

6. The device of claim 1, wherein the mounting device is metal.

7. The device of claim 6, wherein the metal is selected from one of aluminum, anodized aluminum, and stainless steel.

8. The device of claim 1, wherein the lower portion extends into a flared extension portion.

9. The device of claim 8, wherein the flared extension portion comprises an asymmetric configuration.

10. The device of claim 9, wherein the asymmetric configuration comprises an astroid design having four cusps.

11. The device of claim 10, wherein one of the plurality of mounting posts is disposed at endpoints of the astroid design.

12. The device of claim 11, wherein the astroid design comprises three endpoints having a respective one of the plurality of mounting posts attached thereto.

13. The device of claim 1, wherein the device comprises indicia disposed on the frame member.

14. A method of manufacturing a device comprising: (a) configuring a frame member to form an upper portion and a lower portion connected by a bent portion; (b) mounting a rigid mounting device to an attachment location of the upper portion, wherein a centerline extends through the rigid mounting device; (c) connecting a plurality of mounting posts on the lower portion, wherein each plurality of mounting posts has a top surface, wherein the bent portion is configured such that a horizontal plane running through the centerline aligns with each top surface of the plurality of mounting posts; and (d) mounting a marker element on each mounting post such that a centerline of each mounted marker element aligns with the top surface of the mounting post.

15. The method of claim 14, further comprising: (e) extending the lower portion into a flared extension portion.

16. The method of claim 15, wherein the flared extension portion comprises an asymmetric configuration.

17. The method of claim 16, the asymmetric configuration comprises an astroid design having four cusps.

18. The method of claim 17, wherein one of the plurality of mounting posts is disposed at endpoints of the astroid design.

19. A method of manufacturing a medical device comprising: (a) configuring a frame member to form an upper portion and a lower portion connected by a bent portion; (b) mounting a rigid mounting device to an attachment location of the upper portion, wherein a centerline extends through the rigid mounting device; and (c) mounting marker elements on the frame member, wherein the bent portion is configured such that a horizontal plane running through the centerline aligns with a centerline of each mounted marker element.

20. The method of claim 19, further comprising: (d) extending the lower portion into a flared extension portion.

21. The method of claim 20, wherein the flared extension portion comprises an asymmetric configuration.

22. The method of claim 21, the asymmetric configuration comprises an astroid design having four cusps.

23. The method of claim 22, wherein the marker elements are mounted to a plurality of mounting posts disposed at endpoints of the astroid design.

24. A device for a surgical navigation system, comprising: a frame member having an attachment location; and a rigid mounting device disposed in the attachment location, wherein a centerline extends through the rigid mounting device, wherein the frame member comprises an upper portion connected to a lower portion via a bent portion, wherein the lower portion comprises a plurality of mounting posts, wherein marker elements are mounted to the plurality of mounting posts such that upon mounting, a centerline of the marker elements aligns with the centerline extending through the rigid mounting device.

25. The device of claim 24, wherein each of the plurality of mounting posts has a top surface, wherein a horizontal plane running through the centerline extending through the rigid mounting device aligns with each of the top surfaces.

26. The device of claim 24, wherein the lower portion extends into a flared extension portion.

27. The device of claim 26, wherein the flared extension portion comprises an asymmetric configuration.

28. The device of claim 27, wherein the asymmetric configuration comprises an astroid design having four cusps.

29. The device of claim 28, wherein one of the plurality of mounting posts is disposed at endpoints of the astroid design.

30. The device of claim 29, wherein the astroid design comprises three endpoints having a respective one of the plurality of mounting posts attached thereto.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The accompanying drawings, which are incorporated herein and constitute to part of this specification, illustrate exemplary embodiments of the invention, and, together with the general description given above and the detailed description given below, serve to explain the features of the invention.

(2) FIG. 1 is a perspective view of a disposable medical device for a surgical navigation system according to an embodiment of the present invention.

(3) FIG. 2 is a side view of the disposable medical device of FIG. 1 for a surgical navigation system according to an embodiment of the present invention.

(4) FIG. 3 is a detail view a section of the disposable medical device of FIG. 2 according to one embodiment of the present invention.

(5) FIG. 4 is a top view of the disposable medical device of FIG. 1 for a surgical navigation system according to an embodiment of the present invention.

(6) FIG. 5 is a detail view a section of the disposable medical device of FIG. 4 according to one embodiment of the present invention.

(7) FIG. 6 is a side view of the disposable medical device of FIG. 1 including a mounted marker element according to an embodiment of the present invention.

(8) FIG. 7 is a detail view of the mounted marker element of FIG. 6 according to one embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(9) Definitions

(10) Where the definition of terms departs from the commonly used meaning of the term, applicant intends to utilize the definitions provided below, unless specifically indicated.

(11) For the purposes of the present invention, directional terms such as top, bottom, upper, lower, above, below, left, right, horizontal, vertical, upward, downward, etc., are merely used for convenience in describing the various embodiments of the present invention.

(12) For purposes of the present invention, the term astroid refers to a geometric design of a hypocycloid with four cusps, the curve of which includes a variety of names, including tetracuspid, cubocycloid, and paracycle.

(13) For purposes of the present invention, the term indicia refers distinctive marks, characteristic markers or indications.

(14) For purposes of the present invention, the term registering refers to a process for determining the geometric relationship between an anatomic structure(s) of interest and a dimensional (3D) computer image constructed, for example, from the preoperative CT scan. By way of this registration, a correct, spatial reference between the 3D image data and the position and orientation of the body part of the patient, observed by means of referencing device, can be produced.

(15) For purposes of the present invention, the term surgical navigation refers to computer assisted surgery (CAS) representing a surgical concept and set of methods that use computer technology for pre-surgical planning and for guiding or performing surgical interventions. CAS is also known as computer aided surgery, computer assisted intervention, image guided surgery and surgical navigation.

(16) For purposes of the present invention, the term surgical navigation system refers a system that allows visualization of an operative site and surgical instruments simultaneously and relates them to the patient's diagnostic images (e.g., computed tomographic (CT) scans and magnetic resonance imaging (MRI)). A surgical navigation system is used to guide the surgeon's movements during an operation. It may display the real-time position of each instrument and anatomical structure. These systems are used in orthopedics, ENT, neurology and other surgical specialties. Real-time observations occur via. MRI, scanner, video camera or another imaging process. Navigation data are incorporated into the image to help the surgeon determine precise position within the organism. Medical imaging is sometimes used to plan an operation before surgery. Data integration enables the system to compare the actual position of the target object with the ideal location established during the planning phase. Such systems may be mechanical, electromagnetic or optical. The most common are optical devices, either passive or active. In the former, cameras locate specific markers such as reflective targets, particular shapes or colors. Active systems locate LEDs.

(17) For purposes of the present invention, the term x-direction refers to the direction aligned with the x-axis of a coordinate system.

(18) For purposes of the present invention, the term y-direction refers to the direction aligned with the y-axis of a coordinate system.

(19) For purposes of the present invention, the term z-direction refers to the direction aligned with the z-axis of a coordinate system.

(20) Description

(21) The invention will now be described with reference to the drawing figures, in which like reference numerals refer to like parts throughout. The following detailed description is of example embodiments of the presently claimed invention with references to the accompanying drawings. Such description is intended to be illustrative and not limiting with respect to the scope of the present invention. Such embodiments are described in sufficient detail to enable one of ordinary skill in the art to practice the subject invention, and it will be understood that other embodiments may be practiced with some variations without departing from the spirit or scope of the subject invention.

(22) The disclosed invention contemplates the fabrication and use of a disposable, single-use medical device. Turning to FIG. 1, a disposable medical device 100 for use in a surgical navigation system is illustrated including a reference frame of the disclosed invention. The reference frame comprises a trackable target probe 104 coupled to a mounting device 106 at a mounting or attachment location 112. Attachment location 112 may comprise a receiving structure such as a hole for accepting and securing an end of mounting device 106. Trackable target probe 104 comprises a frame member 116. In one disclosed embodiment, frame member 116 includes a bend or gooseneck bend 114 which extends into a flared extension portion 118. A plurality of ridges 134 may be designed into the framework of frame member 116 to provide increased structural integrity to medical device 100.

(23) The embodiment of the disclosed flared extension portion 118 includes an asymmetric configuration. The asymmetric configuration may include an astroid design 120, for example, having four cusps 108. While four exemplary cusps 108 are shown for illustrative purposes, one skilled in the art will readily appreciate more or fewer cusps 108 may be employed by disclosed embodiments. A support member 110 extends between cusps 108 to provide strength to the integral design. The asymmetric astroid design 120 of flared extension portion 118 provides three notable extensions: first extension 122, second extension 124 and third extension 126. Mounting posts 102 are disposed on flared extension portion 118. In some embodiments, mounting posts 102 are generally disposed at end points 128, 130, and 132 of first extension 122, second extension 124 and third extension 126, respectively. Mounting posts 102 may also be selectively mounted at other locations of trackable target probe 104, as described below.

(24) Turning to FIG. 2, an embodiment of frame member 116 depicts gooseneck bend 114 to include a first straight portion 202, transitioning and extending into a bent portion 212, transitioning and extending into a second straight portion 204 before frame member 116 finally extends into flared extension portion 118. As viewed from the illustrated side view, first straight portion 202 may be regarded as an upper straight portion, and second straight portion 204 may be regarded as lower straight portion.

(25) As stated above, mounting posts 102 are disposed on flared extension portion 118 at prescribed locations 208. Additional mounting posts 102 may be selectively attached, for example, on lower straight portion 204. In a preferred embodiment, one mounting post 102 is disposed on lower straight portion 204 generally at a location 214, approximately right before a transition of an extended portion 218 of the lower straight portion 204 into the flared extension portion 118. Another mounting post 102 is preferably disposed on lower straight portion 204, generally at a location 216 approximately slightly before a transition into bent portion 212. Location 216 may be determined, for example, by measuring a distance d.sub.1 from a center line extending upwardly through the elongated portion of mounting post 102 to a point located on lower straight portion 204 right at bend 114. Hence, d.sub.1 may measure 0.24 inches0.01. Location 216 may also be determined, for example, by measuring a distance d.sub.2 from a center line extending upwardly through the elongated portion of mounting post 102 to a point located on upper straight portion 206 right at bend 114. Hence, d.sub.2 may measure 0.88 inches0.01. Thus, a prescribed number of mounting posts 102 are disposed at prescribed locations 206 along extended portion 218 of the lower straight portion 204.

(26) Attachment location 112 is designed and configured to accept and maintain mounting device 106 such that a centerline 200 runs generally through the center length of mounting device 106, through the center of upper straight portion 202 and extends down and along the middle of the rest of frame member 116 see top view of FIG. 4). As depicted in the side view of FIG. 2, centerline 200 also aligns with the top 210 of each mounting post 102 such that centerline 200 extending through is level with each of top surfaces 210. Thus, a horizontal plane running through centerline 200 aligns each top 210 of mounting post 102 with the center of upper straight portion 202, mounting device 106 and with each other.

(27) To this extent, and to achieve and maintain the alignment of centerline 200, frame member 116 and mounting device 106 are manufactured to a sufficient rigidity. In some disclosed embodiments, frame member 116 and mounting device 106 may be manufactured from plastic materials. For example, the manufacturing process may comprise molded plastic materials which allows reproducibility and accuracy in design.

(28) In some preferred embodiments, the plastic comprises polycarbonate, polyetherimide (PEI) or another glass filled polymer such as poiyetheretherketone (PEEK). A PEEK product description includes a high performance thermoplastic, unreinforced polyetheretherketone, semi crystalline, including granules for injection molding and extrusion, standard flow, FDA food contact compliant, color natural/beige. PEEK is applicable for applications for higher strength and stiffness as well as high ductility. It is chemically resistant to aggressive environments and suitable for sterilization for medical and food contact applications. PEEK property data table is provided as follows:

(29) TABLE-US-00001 TABLE 1 Nominal Value (English) Nominal Value (SI) Test Method Physical Density ISO 1183 Crystalline 1.30 g/cm.sup.3 1.30 g/cm.sup.3 Amorphous 1.26 g/cm.sup.3 1.26 g/cm.sup.3 Mechanical Tensile Modulus (73 F. 537000 psi 3700 Mpa ISO 527-2 (23 C.)) Tensile Stress (Yield, 14500 psi 100 Mpa ISO 527-2 73 F. (23 C.)) Tensile Strain (Break, 45% 45% ISO 527-2 73 F. (23 C.)) Flexural Strength 73 F. (23 C.) (at yield) 23900 psi 165 Mpa 3.5% Strain, 73 F. (23 C.) 18100 psi 125 Mpa 257 F. (125 C.) 12300 psi 85.0 Mpa 347 F. (175 C.) 2610 psi 18.0 Mpa 527 F. (275 C.) 1890 psi 13.0 MPa Compressive Stress ISO 604 73 F. (23 C.) 18100 psi 125 Mpa 248 F. (120 C.) 10200 psi 70.0 Mpa Hardness Shore Hardness (Shore D, 85 85 ISO 868 73 F. (23 C.)) Thermal Heat Defiection ISO 75-2/A Temperature 264 psi (1.8 MPa), Un- 306 F. 152 C. annealed Glass Transition 289 F. 143 C. ISO 11357-2 Temperature Melting Temperature 649 F. 343 C. ISO 11357-3 CLTE Flow: <289 F. (<143 C.) 0.000025 in/in/ F. 0.000045 cm/cm/ C. Flow: >289 F. (>143 C.) 0.000067 in/in/ F. 0.00012 cm/cm/ C. Transverse: <289 F. (< 143 C.) 0.000031 in/in/ F. 0.000055 cm/cm/ C. >289 F. (>143 C.) 0.000078 in/in/ F. 0.00014 cm/cm/ C. Specific Heat (73 F. 0.526 Btu/lb/ F. 2200 J/kg/ C. DSC (23 C.)) Thermal Conductivity 2.0 Bti-in/hr/ft.sup.2/ F. 0.29 W/m/K ISO 22007-4 (73 F. (23 C.)) Electrical IEC 60093 Volume Resistivity 73 F. (23 C.) 1.0E+16 ohm .Math. cm 1.0E+16 ohm .Math. cm 257 F. (125 C.) 1.0E+35 ohm .Math. cm 1.0E+15 ohm .Math. cm 437 F. (225 C.) 1.0E+9 ohm.Math. cm 1.0E+9 ohm .Math. cm Electric Strength IEC 60093 0.00197 in (0.0500 mm) 4800 V/mil 190 kV/mm 0.0787 in (2.00 mm) 580 V/mil 23 kV/mm Dielectric Constant 73 F. (23 C.), 50 Hz 3.00 3.00 73 F. (2.3 C.), 1 kHz 3.10 3.10 257 F. (125 C.), 50 Hz 4.50 4.50 Fill Analysis ISO 11443 Melt Viscosity (752 F. 350 Pa .Math. s 350 Pa .Math. s (400 C.)) Injection Drying Temperature 248 to 302 F. 120 to 150 C. Drying Time 3.0 to 5.0 hr 3.0 to 5.0 hr

(30) A polycarbonate product description includes a glass and carbon fiber reinforced, mineral and process additive filled structural compound material. The polycarbonate product may be offered in all infinity base resins. The polycarbonate product provides improvements in strength, stiffness, creep resistance, fatigue endurance and impact and dimensional stability. Additional properties include increased thermal heat deflection temperature or heat distortion temperature (HDTUL) and long term heat resistance. Polycarbonate property data table is provided as follows:

(31) TABLE-US-00002 TABLE 2 Nominal Value Nominal Value (English) (SI) Test Method Physical Specific Gravity 1.34 1.34 g/cm.sup.3 ASTM D792 Specific Volume 20.7 in.sup.3/lb 0.747 cm.sup.3/g 1.26 g/cm.sup.3 Mechanical Tensile Strength (Yield) 16000 psi 110 MPa ASTM D638 Tensile Elongation 2.0 to 4.0% 2.0 to 4.0%i ASTM D638 (Yield) Flexural Modulus 1.00E+6 psi 6890 MPa ASTM D790 Flexural Strength 25000 psi 172 Mpa ASTM D790 Thermal Deflection Temperature ASTM D648 Under Load 264 psi (1.8 MPa), 295 F. 146 C. Unannealed CLTE - Flow 0.000015 in/ 0.000027 cm/ ASTM D696 in /F. cm /C. Electrical Surface Resistivity 1.0E+7 ohm 1.0E+17 ohm ASTM D257 Injection Drying Temperature 250 F. 121 C. Drying Time 4.0 hr 4.0 hr Processing (Melt) Temp. 540 to 630 F. 282 to 332 C. Mold Temperature 200 F. 93.3 C.

(32) Polyetherimide (PEI) property data table is provided as follows:

(33) TABLE-US-00003 TABLE 3 ASTM English SI Metric TEST Performance Specific Gravity 1.27 1.27 D 792 Melt Flow Rate #337 C./6.6 kg 17.80 g/10 min 17.80 g/10 min D 1238 Molding Shrinkage in (3.2 mm) 0.0050-0.0070 in/in 0.50-0.70% D 955 section Mechanical Tensile Strength 16000 psi 110 MPa D 638 Tensile Elongation >10.0% >10.0% D 638 Tensile Modulus 0.52 10.sup.6 psi 3585 MPa D 638 Flexural Strength 24000 psi 165 MPa D 790 Flexural Modulus 0.50 10.sup.6 psi 3448 MPa D 790 General Processing for Injection Molding Injection Pressure 12000-18000 psi 83-124 MPa Melt Temperature 670-750 F. 354-399 C. Mold Temperature 275-350 F. 135-177 C. Drying 4 hrs @ 300 F. 4 hrs @ 149 C. Moisture Content Dew Point 0.04% 0.04% 20 F. 20 C.

(34) In an alternative embodiment, mounting device 106 may comprise a rigid metal. The metal may comprise aluminum, anodized aluminum and stainless steel. For 6000 Series Aluminum Alloy; Aluminum Alloy; Metal; Nonferrous Metal, a property data table is provided as follows:

(35) TABLE-US-00004 TABLE 4 Component Wt. % Al 95.8-98.6 Cr 0.04-0.35 Cu 0.15-0.4 Fe Max 0.7 Mg 0.8-1.2 Mn Max 0.15 Other, each Max 0.05 Other total Max 0.15 Si 0.4-0.8 Ti Max 0.15 Zn Max 0.25

(36) TABLE-US-00005 TABLE 5 Metric English Physical Properties Density 2.7 g/cc 0.0975 lb/in.sup.3 Mechanical Properties Hardness Brinell 95 95 Hardness Knoop 120 120 Hardness Rockwell A 40 40 Hardness Rockwell B 60 60 Hardness Vickers 107 107 Ultimate Tensile Strength 310 Mpa 45000 psi Tensile Yield Strength 276 MPA 40000 psi Modulus of Elasticity 68.9 GPa 10000 ksi Poisson's Ratio 0.33 0.33 Fatigue Strength 96.5 Mpa 14000 psi Shear Modulus 26 GPa 3770 ksi Shear Strength 207 Mpa 30000 psi Electrical Properties Electrical Resistivity 3.99e066 ohm-cm 3.99e066 ohm-cm

(37) The detail view of FIG. 3 illustrates an exploded view of exemplary mounting posts 102 attached to frame member 116. In some preferred embodiments, mounting post 102 includes a chamfered edge 300. Chamfered edge includes a dimensional measurement of approximately 0.15 inches0.005 as measured from top 210 of mounting post 102 towards prescribed location 208. The chamfer may be cut at approximately a 45.00 angle. Mounting post 102 extends approximately 90.00 from a top surface of frame member 116. Chamfer cut 302 measures approximately .10 inches0.01 from an outside diameter of mounting post 102 towards the center (see also FIG. 5).

(38) Turning to FIG. 4, centerline 200 runs generally down the middle of mounting device 106 and frame member 116 of trackable target probe 104. The asymmetry of cusps 108 of the astroid design is illustrated, for example, as shown about a z-plane running along center axis 400. An exemplary configuration of medical device 100 includes select dimensions to achieve proportions of medical device 100 components and a preferred asymmetric design of the present invention. For example, a length d.sub.3 of mounting device 106 extending from attachment location 112 of trackable target probe 104 may be approximately 4.310 inches0.005. The distance d.sub.4 as measured from a first centerline 402 (corresponding to a first mounting post 102) measured to the end of mounting device 106 may be approximately 4.310 inches0.005. The distance d.sub.5 as measured from a second centerline 404 (corresponding to a second mounting post 102) measured to the end of mounting device 106 may be approximately 9.000 inches0.005. The distance d.sub.6 as measured from a third centerline 406 (corresponding to a third mounting post 102) measured to the end of mounting device 106 may be approximately 10.017 inches0.005. The distance d.sub.7 as measured from a fourth centerline 408 (corresponding to a fourth mounting post 102) measured to the end of mounting device 106 may be approximately 10.338 inches0.005. The distance d.sub.8 as measured from a fifth centerline 410 (corresponding to a fifth mounting post) 102 measured to the end of mounting device 106 may be approximately 11.950 inches0.005. The height distance h.sub.1 as measured from a vertical distance from the fifth centerline 410 (corresponding to a fifth mounting post 102) intersecting a perpendicular horizontal plane extending through the third centerline 406 (corresponding to a third mounting post 102) may be approximately 1.714 inches0.005. The height distance h.sub.2 as measured from a vertical distance from the fifth centerline 410 (corresponding to a fifth mounting post 102) intersecting a perpendicular horizontal plane extending through the fourth centerline 408 (corresponding to a fourth mounting post 102) may be approximately 1.734 inches0.005. Thus d.sub.7>d.sub.6, and h.sub.2>h.sub.1.

(39) FIG. 6 illustrates trackable target probe 104 having a marker element 600 mounted on mounting post 102. Marker element 600 may be designed as spherical marker element including a retro-reflective marker sphere, also referred to as passive reflective marker. Embodiments of retro-reflective marker spheres may include those used to aid registration and instrument tracking during image guided surgery procedures such as neurological procedures, spine procedures and orthopedic procedures. Embodiments may include a retro-reflective marker sphere having a high coefficient of retro-reflection on the external surface to provide feedback to the system/camera. Such surfaces may consist of micro glass spheres that reflect light. Depending on the medical application, different numbers and arrangements of retro-reflective marker spheres may be mounted on various types of surgical tools that may be used including that disclosed herein. Once mounted on a surgical probe, retro-reflective marker spheres provide an accuracy reference point for the surgical probe in three-dimensional space.

(40) FIG. 7 is a detail view of the mounted marker element 600. Embodiments of marker element 600 may include internal structure 700 for receiving and mating with mounting post 102. In the disclosed embodiment, internal structure 700 is designed to not only mount marker element 600 to mounting post 102, but ensure that marker element 600 is consistently and accurately mounted such that a centerline 704 of marker element 600 is aligned with centerline 200 after mounting to frame member 116. For example, embodiments of the disclosed invention may provide an internal stop surface 702 that abuts the top 210 of mounting post 102. Upon doing so, centerline 704 of marker element 600 is aligned with centerline 200 of mounting device 106. Thus the rigidity of mounting device 106 is paramount to the design of the disclosed invention. Mounting device 106 does not flex in order to maintain this important attribute. Each mounting post 102 and marker element 600 of the disclosed invention is appropriately dimensioned such that in this manner, all mounted marker elements 600 mounted on trackable target probe 104 are automatically in alignment with centerline 200 when mounted in the disclosed manner.

(41) Furthermore, embodiments of the disclosed invention provide that the materials and material characteristics described herein are well suited for medical device 100 to be utilized as a disposable single-use device being manufactured with marker elements 102 pre-attached to trackable probe 104 during the manufacturing process. A sterile single-use disposable marker device 100 of the disclosed invention may be packaged to maintain its sterile integrity and be ready for use upon request with the setup of the pre-attached marker elements 102 ready for use and correctly aligned along frame member 116. In operation, when a surgeon, for instance, opens the package containing the disclosed medical device 100, medical device 100 may be configured and employed within a surgical navigation system such as via mounting device 106. Upon assembly, the unique design of the disclosed embodiment automatically and consistently aligns marker elements 102 in alignment with suitable tolerance levels of the surgical navigation system requirements. The rigid mounting device 106 in combination with the gooseneck bend 114 design of the rigid frame marker 116 supports the correct and consistent alignment of marker elements 102 with respect to centerline 200 of mounting device 106. Disclosed embodiments provide centerline 200 automatically sync in correct alignment with the entire navigation system when mounted into a corresponding structure of the navigation system, such as via mounting device 106. This more easily facilitates setup efforts of the navigation system in a cost efficient manner and eliminates additional pre-registration and formatting procedures.

(42) Having described the many embodiments of the present invention in detail, it will be apparent that modifications and variations are possible without departing from the scope of the present invention defined in the appended claims. For example, disclosed embodiments may provide certain indicia and/or colors on components of the disclosed disposable medical device such as, but not limited to, mounting device 106, frame member 116, flared extension portion 118, cusps 108, mounting posts 102 and/or marker elements 600. Such specific uses or applications associated with said indicia and/or colors may be employed, for example, in specific prescribed distinct surgical procedures or in certain environments or medical situations, or by specific groups of surgeons or individuals. These may include, but not limited to, for example, use in neuro and ENT surgery, spinal applications, soft/sensitive tissue applications and/or applying force applications. Additionally, other custom features may be employed and configured into the disclosed disposable medical device 100 such as pre-fashioned and custom made ergonomic grips/handles attachable to medical device 100, for example, via mounting device 100. An example of a coloring scheme is presented as follows:

(43) TABLE-US-00006 TABLE 6 Color of Component (e.g., handle/grip) Probe Name Tip Specific Orange Blunt Pointer Pointer used for Neuro and ENT use; tip is slightly rounded (R 0.25 mm). Blue Sharp Pointer Pointer used for spinal application; tip is harp, so that anatomical landmarks on bones can be acquired. Green Ball Pin Pointer Pointer for touching soft, sensitive tissue; tip with ball (R 1.5 mm). Yellow Extra Strong Pointer for applying force, pointer Pointer tip with big diameter (R 2.5 mm).

(44) Furthermore, it should be appreciated that pies in the present disclosure, while illustrating many embodiments of the present invention, are provided as non-limiting examples and are, therefore, not to be taken as limiting the various aspects so illustrated.

(45) While the present invention has been disclosed with references to certain embodiments, numerous modifications, alterations, and changes to the described embodiments are possible without departing from the spirit and scope of the present invention, as defined in the appended claims. Accordingly, it is intended that the present invention not be limited to the described embodiments, but that it has the full scope defined by the language of the following claims, and equivalents thereof.