NEURO-ENDOSCOPE BOX TRAINER

Abstract

An electro-mechanical box trainer for neurosurgery comprise: (i) a base part which comprises a rubberized working port (11) for insertion of endoscope (26) and tool (25) for manipulation, a microcontroller programmed motorized peg plate (14) placed at 45° degrees of inclination for defining a practice volume according to the neuroendoscopy, a membrane keypad to change the angle of rotation of said peg plate (14) along vertical axis, liquid crystal display (LED) array to illuminate the interior of the box and a removable base plate (6) to house the circuitry; and (ii) a removable part enclosed of five walls such as a front wall (18), two lateral walls (17 and 19), a back wall (20) and a top wall (23), comprises a housing to mount an auxiliary camera (32) to record all the task for evaluation and a slider at the back to adjust the camera focus.

Claims

1. An electro-mechanical box trainer for neurosurgery comprises; (i) a base part which comprises a rubberized working port (11) for insertion of endoscope (26) and tool (25) for manipulation, a microcontroller programmed motorized peg plate (14) placed at 45° degrees of inclination for defining a practice volume according to the neuro-endoscopy, a membrane keypad to change the angle of rotation of said peg plate (14) along vertical axis, liquid crystal display (LED) array to illuminate the interior of the box and a removable base plate (6) to house the circuitry; and (ii) a removable part enclosed of five walls such as a front wall (18), two lateral walls (17 and 19), a back wall (20) and a top wall (23), comprises a housing to mount an auxiliary camera (32) to record all the task for evaluation and a slider at the back to adjust the camera focus.

2. An electro-mechanical box trainer for neurosurgery as claimed in claim 1, wherein the working port (11) leads to an activity area to perform pick and place task by manipulating rubber rings placed on the peg.

3. The electro-mechanical box trainer for neurosurgery as claimed in claim 1, wherein motorized peg plate (14) has a manipulation area of 60×40 mm, through of 10 mm in the middle for providing variable depth of manipulation.

4. The motorized peg plate (14) as claimed in claim 3, further comprises four column and three rows of 4 mm diameter and 15 mm height, among which the lateral columns are on flat region and middle columns are on the through region.

5. The motorized peg plate (14) as claimed in claim 3, which has rubberized surface, rubber rings to perform the activity of pick and place, twelve pegs which are made up of ABS plastic.

6. The removable base plate. (6) as claimed in claim 1, which is fixed to the bottom wall (5) of the base part comprises screw fixator (7) and circuit board fixator (8).

7. The removable base plate (6) as claimed in claim 6, which is fixed to the servomotor (13) with slate providing space for electronic components.

8. The auxiliary camera (32) as claimed in claim 1, is mounted to the stand focuses the interior peg plate (14) and records the activity of the user using a wide angle less and hence suitable for capturing endoscope and instrument motion effectively.

9. The membrane keypad as claimed in claim 1, for determining the angle of the peg plate can be changed from −45° to +45° to decrease the difficulty of the task.

10. The LED array as claimed in claim 1 is placed on the above one-third portion of base port too illuminate the interior of the trainer,

11. The motorized peg plate (14) as claimed in claim 4, which has rubberized surface, rubber rings to perform the activity of pick and place, twelve pegs which are made up of ABS plastic.

Description

BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS

[0038] FIG. 1 is a section view of the Neuro-Endo-Trainer along with the instrument and endoscope in their functional positions entering the base part through the pre-established aperture on the box;

[0039] FIG. 2 is the isometric view of base part.

[0040] FIG. 3 is the isometric view of the rubberized working port.

[0041] FIG. 4 is the top view of base part.

[0042] FIG. 5 is the isometric view of the bottom wall of base part.

[0043] FIG. 6 is the isometric view of the peg plate.

[0044] FIG. 7 is the isometric view of the removable top part.

[0045] FIG. 8 is the front view of the slider.

[0046] FIG. 9 is the back view of removable top part.

[0047] FIG. 10 is the isometric view of the camera mount

[0048] FIG. 11 is the Neuro-Endo Box Trainer.

DETAILED DESCRIPTION OF THE INVENTION

[0049] According to this present invention, there is provided a box trainer for neuro-endoscopy that comprises of a base part and a removable top part. The base consists of a rubberized opening in the front for insertion of endoscope and tool for manipulation, a microcontroller programmed motorized peg plate defining a practice volume according to the neuro-endoscopy working environment for pick and place task, rubber sheet to cover the peg plate and rubber rings for manipulation, a membrane keypad to change the angle of rotation of peg plate along vertical axis, a liquid crystal display in the front to show corresponding angle of peg plate, a stand to mount the servo motor to the bottom of the base part, a removable base plate to house the circuitry and other components, light emitting diode array to illuminate the interior of the box. The top of the box consists a housing to mount the auxiliary camera to record the task for evaluation and a slider at the back to adjust the camera focus.

[0050] FIG. 1 depicted an electro-mechanical box trainer for neurosurgery education and training, particularly for neuro-endoscopic endo-nasal surgical training. The base part formed from opaque ABS plastic material comprises of 5 walls to provide enclosed area.

[0051] The base part depicted in FIG. 2 includes a rubberized working port 11 on the face wall 1 in which the upper one third portion is inclined at 45 degrees 10 and is having a 20 mm aperture as in FIG. 3 with a rubber port in the middle 11 for insertion of endoscope 26 and tool 25. The lateral walls are 2 and 4 and the back wall is 3. The bottom wall is 5 on to which the removable base plate is fixed. Lower two third portion of front wall 1 has slot 9 to fix the liquid crystal display and slot 29 for membrane keypad. The membrane keypad determines the angle of the peg plate, which can be changed from −45 degree to +45 degree to increase the difficulty of the task.

[0052] Inside of base part contains a removable base-plate 6 as in FIG. 4 with a slot 12 to fix the servomotor 13 and has a slot 27 to provide space for electronic components.

[0053] Removable base plate 6 is fixed to the bottom wall 5 of the base part, which contains screw fixators 7 and circuit board fixators 8 as shown in FIG. 5. discloses a LED array which is placed on the above one-third portion of base part to illuminate the interior of the trainer. A 10 mm groove 30 has been made on the top of the inner wall of the base part for firm fixation of the removable upper part. There is a circular opening at the back wall of the base part to provide power supply to the circuit.

[0054] The box trainer for neuro-endoscopic surgical training basically comprising of enclosed working area to block the trainee's direct line of sight of the activity area. Furthermore, the endoscope of brand X and tool of brand Y are inserted through a rubberized working port. The working port leads to an activity area to perform pick and place task by manipulating rubber rings placed on the pegs and there is another rubberized platform placed on the activity area.

[0055] In one aspect a method of psychomotor skills training is provided. Embodiment consists of providing variable depth perception activity with the help of uneven and slanted manipulation area. In another aspect the axial rotation of the activity area further increases the difficulty level of depth manipulation. Dimensional constraints of activity area are provided so as to replicate the real surgery scenario of endo-nasal neuro-endoscopic surgery. Angular constraints of axial rotations of activity area are decided so as to acquaint the trainee with the use of different angled endoscopes.

[0056] From FIG. 6, it is evident that a motorized peg plate 14 with twelve pegs 16 are made of ABS plastic and plate 14 is mounted over to the servomotor 13 using a stand 28. It has rubberized surface 15 and rubber rings around the pegs to perform the activity of pick and place. Peg plate 14 has a manipulation area of 60×40 mm, a trough of 10mm in the middle to provide variable depth of manipulation, four columns and

[0057] three rows of pegs 16 of 4 mm diameter and 15 mm height, among which the lateral columns are on the flat region and middle columns are on the trough region. Height of the pegs has been designed in such a way that it provides a medium level of difficulty during placement of rings of variable diameter (8, 9, 10 mm). On top of peg plate 14, a rubber sheet 15 is placed to provide a sense of tissue.

[0058] FIG. 7 discloses an upper removable part enclosed of 5 walls. It has a front wall 18, two lateral walls 17 and 19, a back wall 20 with a rectangular slider 21 as shown in FIG. 8 for focus adjustment of the camera, a top wall 23 that has a stand 24 towards inside for fixation of the auxiliary camera 32 and a slot 22 for the camera wiring. Lower end of the upper part has an extrusion 31 of 10 mm for its attachment to base part.

[0059] FIG. 9 shows auxiliary camera 32 mounted to the stand 24 focuses the interior peg plate 14 and records the activity of the user using a wide-angle lens 33.

[0060] FIG. 10 discloses the isometric view of the camera mount. The videos are recorded through Ethernet to the desktop or laptop and saved to the hard disk. The placement of camera is appropriately chosen to capture endoscope and instrument motion effectively. The video recordings are used for offline analysis of the psychomotor skills of trainee.

[0061] According to another embodiment of the invention, a camera of brand Z has been placed at the top so as to capture the entire activity inside the box. Thereby, the captured video data can be analyzed offline to score the efficiency of the activity of the trainee. Yet another embodiment of the invention relates to recording the activity using the endoscopic camera of brand X for further analysis of skills.

[0062] The trainee performs the activity of pick and place of the ring in a row-wise manner from right object area to the left target area. After finishing the rows, the trainee replaces the rings to the object area in a diagonal manner.