Guiding apparatus for minimally invasive pedicle screws insertion

Abstract

A guiding apparatus for pedicle screws insertion, including: two orientation rods, used to be fixed on a bone to provide two non-parallel rod bodies; an orientation board, having a first orientation tube, a second orientation tube, a lengthy lateral opening, and a plurality of sleeve combinations, the second orientation tube having a vertical opening connected with the lengthy lateral opening, so that when one rod body of the two non-parallel rod bodies passes through the first orientation tube, the other rod body of the two non-parallel rod bodies will move through the lengthy lateral opening and enter the second orientation tube via the vertical opening; and a plurality of metal pins, used to be inserted into the bone through the plurality of sleeve combinations, and guide a plurality of pedicle screws to be screwed into the bone after inner sleeves of the sleeve combinations are removed.

Claims

1. A guiding apparatus for minimally invasive pedicle screws insertion, including: two orientation rods, each having a fixing end for fixing on a bone of a spine of a patient to provide two non-parallel rod bodies; an orientation board, having a board body, a first orientation tube and a second orientation tube installed inside two orientation holes of the board body respectively, and a plurality of sleeve combinations installed on the board body, wherein, each of the sleeve combinations has an inner sleeve and an outer sleeve, each said inner sleeve is inserted into a corresponding guiding hole, the board body has a lengthy lateral opening, and the second orientation tube has a vertical opening connected with the lengthy lateral opening, so that when one rod body of the two non-parallel rod bodies passes through the first orientation tube, the other rod body of the two non-parallel rod bodies will move through the lengthy lateral opening and enter the second orientation tube via the vertical opening, thereby completing an orientation process; and a plurality of metal pins, used to be inserted into the bone of the spine through the plurality of sleeve combinations after the orientation process is completed, and used to guide a plurality of pedicle screws to be screwed into the bone of the spine after the inner sleeves of the sleeve combinations are removed.

2. The guiding apparatus for minimally invasive pedicle screws insertion as disclosed in claim 1, wherein each said fixing end includes a socket and a screw, the screw being used to be screwed into the bone of the spine, and the socket being used to connect with the screw.

3. The guiding apparatus for minimally invasive pedicle screws insertion as disclosed in claim 1, wherein the guiding apparatus for minimally invasive pedicle screws insertion further includes two clamping units, one of which being used for clamping together one of the two orientation rods and the first orientation tube, and the other of which being used for clamping together the other of the two orientation rods and the second orientation tube after the orientation process is completed.

4. The guiding apparatus for minimally invasive pedicle screws insertion as disclosed in claim 1, wherein the metal pins are made of steel or titanium alloy.

5. The guiding apparatus for minimally invasive pedicle screws insertion as disclosed in claim 1, wherein the board body has a curved surface and the plurality of guiding holes are determined according to an X-ray computed tomography image, which contains an image of the bone of the spine and an image of the two orientation rods fixed on the bone of the spine.

6. A guiding apparatus for minimally invasive pedicle screws insertion, including: an orientation rod, having a fixing end and a rod body, the fixing end being used for fixing on a bone of a spine of a patient to make the rod body extending outside the bone of the spine; an orientation board, having a board body, an orientation unit installed inside an orientation hole of the board body, and a plurality of sleeve combinations installed on the board body, wherein, the orientation unit includes a tube and an orientation socket connected with the tube, and each of the sleeve combinations has an inner sleeve and an outer sleeve, each said inner sleeve is inserted into a corresponding guiding hole, so that after the orientation rod is fixed on the bone of the spine, the tube and the orientation socket of the orientation unit will pass through the rod body and the orientation socket will socket a local area of the bone of the spine, thereby completing an orientation process; and a plurality of metal pins, used to be inserted into the bone of the spine through the plurality of sleeve combinations after the orientation process is completed, and used to guide a plurality of pedicle screws to be screwed into the bone of the spine after the inner sleeves of the sleeve combinations are removed.

7. The guiding apparatus for minimally invasive pedicle screws insertion as disclosed in claim 6, wherein each said fixing end includes a socket and a screw, the screw being used to be screwed into the bone of the spine, and the socket being used to connect with the screw.

8. The guiding apparatus for minimally invasive pedicle screws insertion as disclosed in claim 6, further including a clamping unit for clamping together the orientation rod and the orientation unit after the orientation process is completed.

9. The guiding apparatus for minimally invasive pedicle screws insertion as disclosed in claim 6, wherein the metal pins are made of steel or titanium alloy.

10. The guiding apparatus for minimally invasive pedicle screws insertion as disclosed in claim 6, wherein the board body has a curved surface and the plurality of guiding holes are determined according to an X-ray computed tomography image, which contains an image of the bone of the spine and an image of the orientation rod fixed on the bone of the spine.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 illustrates an exploded view of a guiding apparatus for minimally invasive pedicle screws insertion of the present invention according to a preferred embodiment of the present invention.

(2) FIG. 2 illustrates a situation that two non-parallel rods of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 1 are screwed into a bone of a spine.

(3) FIG. 3a-3c illustrate an orientation process of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 1, in which a second rod gradually moves along a lengthy lateral opening of an orientation board to enter a second orientation tube.

(4) FIG. 4 illustrates a scenario that an inner tube of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 1 is to be installed into an outer tube.

(5) FIG. 5 illustrates a situation that two metal pins of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 1 are guided by two tube combinations to penetrate into a bone of a spine.

(6) FIG. 6 illustrates a scenario that one inner tube is removed and the other inner tube is to be removed after an orientation process of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 1 is completed.

(7) FIG. 7-8 illustrate a screw-insertion process of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 1, in which two pedicle screws are guided by two metal pins respectively to be screwed into a bone of a spine.

(8) FIG. 9 illustrates an outline of a bone of a spine fixed with two pedicle screws after the operation of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 1 is completed.

(9) FIG. 10 illustrates an exploded view of a guiding apparatus for minimally invasive pedicle screws insertion of the present invention according to another preferred embodiment of the present invention.

(10) FIG. 11 illustrates a situation that two metal pins of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 10 are guided by two tube combinations to penetrate into a bone of a spine.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(11) Please refer to FIG. 1, which illustrates an exploded view of a guiding apparatus for minimally invasive pedicle screws insertion of the present invention according to a preferred embodiment of the present invention.

(12) As illustrated in FIG. 1, the guiding apparatus for minimally invasive pedicle screws insertion includes two orientation rods 100, an orientation board 200, and a plurality of metal pins 300. In this embodiment, two metal pins 300 are used.

(13) The two orientation rods 100, each of which has a fixing end 110 for fixing on a bone of a spine of a patient to provide two non-parallel rod bodies 121, 122, the fixing end 110 includes a socket 111 and a screw 112, wherein the socket 111 is used to connect with the screw 112, and the screw 112 is used to be screwed into the bone of the spine.

(14) The orientation board 200 has a board body 210, which can be a plain board body or a curved-surface board body, and the board body 210 includes a first orientation hole 220 and a first orientation tube 221 installed inside the first orientation hole 220, a second orientation hole 230 and a second orientation tube 231 installed inside the second orientation hole 230, a plurality of guiding holes 240 and a plurality of sleeve combinations 241 installed inside the plurality of guiding holes 240, and each of the sleeve combinations 241 has an inner sleeve 242 and an outer sleeve 243. In this embodiment, two guiding holes 240 and two sleeve combinations 241 are used.

(15) Please refer to FIG. 2, which illustrates a situation that two non-parallel rods of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 1 are screwed into a bone of a spine.

(16) As illustrated in FIG. 2, each of the two orientation rods 100 has a fixing end 110 fixed on a bone 400 of a spine of a patient to provide two non-parallel rod bodies 121, 122.

(17) Besides, by performing an X-ray computed tomography scan on the bone 400 of the spine and the two non-parallel rod bodies 121, 122 extending from the bone 400 of the spine, a stereo image can be derived and used for determining the positions and orientations of the first orientation hole 220, the second orientation hole 230, and the plurality of guiding holes 240 on the orientation board 200.

(18) Please refer to FIG. 3a-3c, which illustrate an orientation process of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 1, wherein, the rod body 122 gradually moves along a lengthy lateral opening 260 of the orientation board 200 to enter the second orientation tube 231.

(19) As illustrated in FIG. 3a, when the board body 210 is at an initial position away from the bone 400 of the spine, the rod body 122 is located at an entrance of the lengthy lateral opening 260.

(20) As illustrated in FIG. 3b, as the board body 210 approaches the bone 400 of the spine, the rod body 122 moves along the lengthy lateral opening 260 to approach a vertical opening 250 of the second orientation tube 231, the vertical opening 250 being connected with the lengthy lateral opening 260.

(21) As illustrated in FIG. 3c, an orientation process is completed when the board body 210 reaches a position near the bone 400 of the spine to make the rod body 122 enter the second orientation tube 231 via the vertical opening 250.

(22) Please refer to FIG. 4-6, wherein FIG. 4 illustrates a scenario that an inner tube of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 1 is to be installed into an outer tube; FIG. 5 illustrates a situation that two metal pins of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 1 are guided by two tube combinations to penetrate into a bone of a spine; and FIG. 6 illustrates a scenario that one inner tube is removed and the other inner tube is to be removed after an orientation process of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 1 is completed.

(23) As illustrated in FIG. 4, the two orientation rods 100 further includes two clamping units 130, one of which being used for clamping together one of the two orientation rods 100 and the first orientation tube 221, and the other of which being used for clamping together the other of the two orientation rods 100 and the second orientation tube 231 after the orientation process is completed. After that, as illustrated in FIG. 5, two inner sleeves 242 are installed into two outer sleeves 243 to form two sleeve combinations 241, and two metal pins 300 are guided by the two sleeve combinations 241 respectively to penetrate into the bone 400 of the spine, wherein the metal pins 300 are preferably made of a metal material having proper hardness, such as steel or titanium alloy, etc. After the two metal pins 300 are inserted into the bone 400 of the spine, as illustrated in FIG. 6, the inner sleeves 242 of the sleeve combinations 241 are removed to enable the sleeve combinations 241 to guide two pedicle screws 310 to be screwed into the bone 400 of the spine.

(24) Please refer to FIG. 7-8, which illustrate a screw-insertion process of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 1, in which two pedicle screws 310 are guided by two metal pins 300 respectively to be screwed into the bone 400 of the spine. After the two pedicle screws 310 are screwed into the bone 400 of the spine, all the two orientation rods 100, the orientation board 200, and the two metal pins 300 are removed, and the bone 400 of the spine is fixed with two pedicle screws 310 as illustrated in FIG. 9.

(25) Please refer to FIG. 10, which illustrates an exploded view of a guiding apparatus for minimally invasive pedicle screws insertion of the present invention according to another preferred embodiment of the present invention.

(26) As illustrated in FIG. 10, the guiding apparatus for minimally invasive pedicle screws insertion includes an orientation rod 100, an orientation board 200, and a plurality of metal pins 300. In this embodiment, two metal pins 300 are used.

(27) The orientation rod 100 has a fixing end 110 and a rod body 120, the fixing end 110 being used for fixing on a bone 400 of a spine of a patient to make the rod body 120 extending outward from the bone 400 of the spine. The fixing end 110 includes a socket 111 and a screw 112, wherein the socket 111 is used to connect with the screw 112, and the screw 112 is used to be screwed into the bone 400 of the spine.

(28) The orientation board 200 has a board body 210, an orientation unit 271 installed inside an orientation hole 270 of the board body 210, and a plurality of sleeve combinations 241 installed inside a plurality of guiding holes 240 of the board body 210, wherein each of the sleeve combinations 241 has an inner sleeve 242 and an outer sleeve 243. In this embodiment, two guiding holes 240 and two sleeve combinations 241 are used.

(29) The orientation unit 271 includes a tube 272 and an orientation socket 273 connected with the tube 272, so that after the orientation rod 100 is fixed on the bone 400 of the spine (not shown in this figure), the tube 272 and the orientation socket 273 of the orientation unit 271 will pass through the rod body 120 and the orientation socket 273 will socket a local area of the bone 400 of the spine, thereby completing an orientation process.

(30) Besides, the orientation rod 100 can further include a clamping unit 130 for clamping together the orientation rod 100 and the orientation unit 271 after the orientation process is completed.

(31) The board body 210 can be a plain board body or a curved-surface board body, and the plurality of guiding holes 240 are determined according to an X-ray computed tomography image (not shown in the figure), which contains an image of the bone 400 of the spine and an image of the orientation rod 100 fixed on the bone 400 of the spine.

(32) FIG. 11 illustrates a situation that two metal pins of the guiding apparatus for minimally invasive pedicle screws insertion of FIG. 10 are guided by two tube combinations to penetrate into a bone of a spine. As illustrated in FIG. 11, two metal pins 300 are guided by two tube combinations 241 to penetrate into the bone of the spine after the orientation process is completed, and the two metal pins 300 are preferably made of a metal material having proper hardness, such as steel or titanium alloy, etc. After the inner sleeves 242 of the sleeve combinations 241 are removed, the two pedicle screws 310 can thereby be guided to be screwed into the bone 400 of the spine, and after the two pedicle screws 310 are screwed into the bone 400 of the spine, all the two orientation rods 100, the orientation board 200, and the two metal pins 300 will be removed to complete a pedicle fixation surgery.

(33) Thanks to the designs disclosed above, the present invention possesses the advantages as follows:

(34) 1. The guiding apparatus for minimally invasive pedicle screws insertion of the present invention can provide a high accuracy guiding operation and thereby result in an excellent fixation effect.

(35) 2. The guiding apparatus for minimally invasive pedicle screws insertion of the present invention can provide a high accuracy guiding mechanism to allow a minimally invasive surgery to reduce operative incisions and prevent hurting vessels and nervous tissues around the spine.

(36) 3. The guiding apparatus for minimally invasive pedicle screws insertion of the present invention can provide accurate insertion paths of pedicle screws for a surgeon so that the surgeon can perform the surgery without the need of adjusting the insertion positions and angles of the pedicle screws, thereby shortening the surgery time.

(37) While the invention has been described by way of example and in terms of preferred embodiments, it is to be understood that the invention is not limited thereto. On the contrary, it is intended to cover various modifications and similar arrangements and procedures, and the scope of the appended claims therefore should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements and procedures.

(38) In summation of the above description, the present invention herein enhances the performance over the conventional structure and further complies with the patent application requirements and is submitted to the Patent and Trademark Office for review and granting of the commensurate patent rights.