Abstract:
A hand manipulated endoscopic medical device includes a body having a proximal end, which is hand manipulated, a distal end which includes a manipulator, a light emitting device at the distal end, an imaging device at the distal end. A tool for extracting an artificial lumbar disc from between a pair of vertebral plates includes a handle, a member for transmitting force, and a sharpened end, specially configured to be placed between the artificial disc and the vertebral plate. A tool for implanting or explanting a ball to or from an artificial lumbar disc includes a pinion shaft and a pinion shaft enclosure, with a tightening knob at the proximal end of the shaft enclosure and coupled to the pinion shaft, a pinion at the distal end of the pinion shaft, a grappling device at the pinion, and a pair of semi-circular rings.

Description:
[0001]    This application is continuation-In-Part of copending application Ser. No. 10/964,633, filed on Oct. 15, 2004, which claims the benefit under Title 35, U.S.C. §119 (e) of U.S. provisional application 60/578,319 filed on Jun. 10, 2004; 60/573,346 filed on May 24, 2004; 60/572,468 filed on May 20, 2004; 60/570,837 filed on May 14, 2004; and 60/570,098 filed on May 12, 2004, the entire contents of which are hereby incorporated by reference and for which priority is claimed under 35 U.S.C. §120. 
     
    
     BACKGROUND OF THE INVENTION 
       [0002]    The history of artificial disc placements in the entire human spine, and in particular the lumbar spine has been thoroughly reviewed in our previous co-pending patent application Ser. No. 10/964,633, filed on Oct. 15, 2004, co-pending patent application Ser. No. 11/487,415, filed Jul. 17, 2006, and in our issued U.S. Pat. No. 7,083,650. In our &#39;650 patent, we described the surgical posterior unilateral placement of an artificial lumbar disc. Prior to its surgical placement into a disc space, a complete unilateral discectomy (removal of disc material) must be performed to denude the opposing vertebral body endplates to ensure that the spikes of the artificial disc plates can penetrate the vertebral bodies, and that the disc material is freed from the disc space to allow unencumbered disc motion, and prevention of recurrent disc herniations. 
         [0003]    During surgical placement of anterior artificial lumbar discs, visualization of the disc space is not a technical problem because the entire diameter and depth of the disc space can be exposed anteriorly with adequate visualization needed to accomplish surgical disc denudement. This is not as easily accomplished through the unilateral posterior discectomy, where visualization is limited to the side of unilateral implantation, and the middle and contralateral disc can not be visualized completely without causing undue retraction of the lumbar nerve root, and even then, full visualization is not adequately achieved. 
         [0004]    To remedy this problem, we disclosed in the &#39;650 patent a wired action-ended pituitary rongeur endoscope with centralized illumination emanating between upper and lower pituitary forceps. The advantage of that design was that it could more easily be placed in the small disc space and provide centralized illumination, neither of which is available in another wired action-ended endoscope design described in U.S. Pat. No. 5,667,472 (Finn et al.), “Surgical instrument and method for use with a viewing system”, issued Sep. 16, 1997. In that design the illumination is provided by a tube lateral to the instrument inside the disc space which might endanger the nerve root by over-retraction, and would provide poorer illumination by not focusing on the center of field of vision. 
         [0005]    In the present patent application we describe an enhanced design of action-ended endoscopes without encumbrance of wired attachments, and also including a self-contained mounted viewing screen. In totality this design enhances surgical efficiency with respect to operating room time, ergonomics, and financial investment. 
         [0006]    To our knowledge, this is the first action-ended endoscope which can function with the complete absence of wires by utilizing a novel induction coil converter converting low voltage power to transient high-powered sparks to initiate gas breakdown of xenon and other molecules, outputting high illumination thereby achieving luminescence equal to wired xenon systems. Another entirely novel aspect of this endoscope is an embodiment which can differentially direct light output in multiple radial and linear directions with digitally controlled reflectors. It can also be easily adapted with lasers to use as a routine laser surgical tool in addition to illumination, forceps grapping, and video display. Furthermore images can be wirelessly transmitted to a mounted self-contained system viewing screen. In addition, it has the capacity to wirelessly transmit images to routine stationary screens, customized work stations, as well as to palm pilots and mobile phones. A further novel application is the ability to manually or electronically control the end manipulator forceps so that it can work as a straight, up or down biter pituitary rongeur combining three types of instruments into one. These modifications with all the above mentioned functions contained within a single action ended-device are entirely unique to endoscopic design to date. 
         [0007]    The present invention minimizes operating room clutter associated with routine endoscopic/laser equipment, has a self contained imaging screen, as well as optional therapeutic laser capacities. These functions allow operations to be performed in any sized operating room or military field, thus significantly reducing capital investment, and enhancing surgical and ergonomic efficiency. It also allows surgeries to be performed in places where there might not be any available electrical outlets or electricity or other power sources. 
         [0008]    Additional inventions presented here are uniquely related to the design of our lumbar artificial disc design described in co-pending patent application Ser. No. 11/487,415, filed Jul. 17, 2006. These inventions include an instrument which allows easy placement and removal of our lumbar disc ball between upper and lower disc plates, and a disc plate extractor which can extract the device if necessary. There are further modifications of the disc plates including rescue plates with longer spikes, and/or increased plate diameters, akin to rescue screws used for spinal fusion. If a plate falls out under harsh conditions because the spikes are too short, the plate can be rescued with longer/wider spikes or increased width and or ball diameter. 
         [0009]    The history of endoscopy, and neuroendoscopy in particular is thoroughly reviewed in “Intracranial endoscopic Neurosurgery”, Editor, David F. Jimenez, The American Association of Neurological Surgeons, 1998. 
         [0010]    Recent devices to further enhance endoscopic functions include a device which rotates images using an image sensor to act like a gyroscope or a pair of accelerometers, U.S. Pat. No. 7,037,258,B2, (Chatenever et al.) “Image orientation for endoscopic video displays”, issued May 2, 2006. A remote surgical support system has been described wherein the state of the surgical instrument and the patient data can be checked in remote control rooms, U.S. Pat. No. 6,955,671 B2, (Uchikubo), “Remote Surgery support system”, issued Oct. 18, 2005. Neither of these devices are wireless, or are incorporated into distal action instruments. Neither, do they incorporate any of the advanced technology and wireless transmission of images, or enable differential directional illumination as does our invention. 
         [0011]    Another wireless video system entails an in-vivo camera system which is swallowed by the patient, captures and then transmits images of the gastrointestinal tract thereby functioning as an autonomous video endoscope. (See U.S. Pat. No. 6,904,308 B2 (Frisch et al.), “Array system and method for locating an in vivo signal source”, issued Jun. 7, 2005). The patient must wear an antenna array with two antennas. The signals received by the two antennas derive an estimated coordinate set from the signal strength measurements. This innovative device functions specifically as an imaging/camera device. The patient must wear an electrode array to capture the signals over his/her abdomen. It is not designed, nor intended to be a combined surgical tool which performs surgical tool functions e.g. tissue grabbing, suction, cutting etc, which significantly distinguishes it from our invention. 
         [0012]    Two more recent patents incorporating wireless technology include U.S. Pat. No. 7,097,615, (Banik et al.), “Robotic endoscope with wireless interface Aug. 29, 2006), and U.S. Pat. No. 7,030,904 B2, (Adair et al.), “Reduced area imaging device incorporated within wireless endoscopic devices” Apr. 18, 2006. Neither of these patents incorporates action-ended instruments or have a self-contained screen imaging system. Furthermore they are purely used for illumination/video, and they do not exploit our innovative technology of an induction coil thermoelectric converter to enhance wireless xenon light. They do not use controlled directional deflectors to modulate light intensity and direction. They do not have laser surgical tool capacities. They are not capable of wireless transmission to palm pilots, or cell phones. 
         [0013]    The inventions described herein have great import not only to anterior and posterior spinal endoscopy, but can be modified and used for diagnostic and therapeutic uses in every endoscopic related field including brain, otolaryngological, pulmonary, gastrointestinal, and urological endoscopy, as well as arthroscopic joint surgery including shoulders, hips, knees, ankles, to name but a few. The multifunctional capacities compressed into a single wireless instrument enabling tissue illumination, tissue manipulation, and therapeutic laser directed treatment with a wireless, self-contained mounted viewing screen would also have profound advantages in the fields of military, emergency, ambulatory, and aerospace medicine in areas and situations where sources of electricity are not guaranteed. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0014]      FIG. 1  illustrates a perspective view of the totally wireless electronically embedded action ended (TWEEAE) endoscope. 
           [0015]      FIG. 2A  illustrates an enlarged view of the on board electronics panel located on the medial manipulator lever of the TWEEAE endoscope. 
           [0016]      FIG. 2B  illustrates the on board electronics panel with optical output dimmer. 
           [0017]      FIG. 3A  illustrates a cross-sectional view of the Laser and visible light source with cooling apparatus and battery compartment of the TWEEAE endoscope. 
           [0018]      FIG. 3B  illustrates the spark (inductor) voltage generator. 
           [0019]      FIG. 4  illustrates the spreading pattern for visible and laser light in the more distal body of the TWEEAE endoscope. 
           [0020]      FIG. 5A  illustrates a cross-sectional view of the fixtures at optical output of the TWEEAE endoscope. 
           [0021]      FIG. 5B  illustrates a cross-sectional view of guide fibers exiting at action end of the TWEEAE endoscope exhibiting geometric arrangement of beams output. 
           [0022]      FIG. 6A  illustrates the TWEEAE endoscope on-board view of video or ultrasound capture at action-end. 
           [0023]      FIG. 6B  illustrates examples of various positions assumable by system monitor and data display. 
           [0024]      FIG. 7A  illustrates the computer architecture of the TWEEAE endoscope electronics. 
           [0025]      FIG. 7B  illustrates an array of contemporary devices which can be made capable of receiving video transmissions via digital radiofrequency data packets. 
           [0026]      FIG. 7C  illustrates the air interface. 
           [0027]      FIG. 8A  illustrates a cross-sectional orthonormal view of adjustable, jaw of biter at action end of TWEEAE endoscope (inner fiber light guide absent). 
           [0028]      FIG. 8B  illustrates a perspective view of superior jaw position selector of the TWEEAE endoscope. 
           [0029]      FIG. 8C  illustrates a cut-away cross sectional view of the action end of the TWEEAE endoscope (inner fiber guide light present). 
           [0030]      FIG. 8D  illustrates a full perspective view of the TWEEAE endoscope end-manipulator with arbitrary angle superior jaw mechanism. 
           [0031]      FIG. 8E  illustrates the full perspective view of the TWEEAE end-effector with demonstration of laser wave front directed through midsection. 
           [0032]      FIG. 9  illustrates a standard lumbar disc plate (A) and rescue plates with larger spikes (B) or thicker plates (C). 
           [0033]      FIG. 10  illustrates a disc plate extractor. 
           [0034]      FIG. 11A  illustrates an overall view of a disc ball implanter/extractor. 
           [0035]      FIG. 11B  illustrates a cross sectional enlargement of the disc ball extractor handle. 
           [0036]      FIG. 11C  illustrates an enlargement of the disc ball extractor grappler. 
           [0037]      FIG. 11D  illustrates an enlarged view of the grappler in opened position. 
           [0038]      FIG. 11E  illustrates the grappler in closed position. 
           [0039]      FIG. 11F  illustrates the grappler in closed position with disc ball. 
       
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The Medical Device 
       [0040]      FIG. 1  illustrates a prospective view of the TWEEAE endoscope having digital inserts  111 . This figure demonstrates the medial and distal manipulators  101 ,  102  which control the opening and closing of the pituitary forceps end manipulator  103 . Also illustrated is an on board electronics panel  104  located on the lever  105  of the medial manipulator  101 . The electronics panel  104  preferably includes system removable memory  114 . Located on the proximal portion of the endoscopic body  112  is the laser and visible light source with cooling apparatus  106  and battery, light, laser compartment  107 . Located distal to this component  107  is the mounted system viewing screen  110 . The TWEEAE endoscope  100  preferably includes an adjustable manipulator angle of attack  113 . We will now describe the electrical and mechanical functioning of the TWEEAE  100 . 
         [0041]      FIG. 2A  illustrates an enlargement of the on board electronics panel  114 . In order to power up the instrument to initiate usage, the power On-Off button  201 , the first button on the right, is depressed once. To turn off or power down, this button  201  is depressed once again. 
         [0042]    In order to initiate or terminate wireless transmission of secure video and or data, the second button  202  which is immediately adjacent to the power on/off button  201 , with a closed padlock icon is depressed. This information can be transmitted to the mounted system viewing screen  110 , to remote unconnected devices such as a mobile phone, palm pilot, personal digital assistant (PDA), or hospital monitors and PCs. This transmission can either be broadcast, and password accessed, in any of the above receivers, or it can be communicated ad-hoc node to node with a remote device. 
         [0043]    To transmit non-secure data i.e. open data, the third button  203  with an open padlock icon is depressed. To initiate or terminate saving of video or data into re-removable/re-readable memory drives e.g. micro secure digital the fourth button  204  with a floppy disc icon is depressed. The buttons  201 - 204  are housed in electronics panel  104 . Slots  205  are for removable, rereadable memory drive  114 , such as micro-secure digital. 
         [0044]    Distal to the four control buttons  201 - 204  are three slots  205  for inserting and removing micro-secure memory cartridges  114 . Slots  205 A, B and C are identical slots with the capacity for data storage of contemporary maximum micro-sd capacity. Having three slots  205  multiplies this capacity threefold. 
         [0045]      FIG. 2B  illustrates the on board electronics panel  104  with optical output dimmer  207 . Turning the optical output dimming knob  207  will dim or brighten the optical output. 
         [0046]      FIG. 3A  is an enlargement of the laser and visible light source with cooling apparatus  106  and battery compartment  107 . Once the power button  201  is depressed this closes a switch between the battery, and both the induction coil within the Magneto and the embedded electronics, on the electronics control panel  104 .  FIG. 3B  illustrates the induction coil  311  (spark voltage generator indicated in  FIG. 3A ) which generates a high voltage pulse that is used to initiate the ionization of gas molecules inside the gas (xenon) bulb  301  which generates high luminosity white light that is transmitted the fiber optic wave guide. Illustrated in  FIG. 3B  are the coil  311  and electrodes  312 . There may also be a helically wound coolant tube  308 , a helical arrangement of thermoelectric conversion units and high efficiency photovoltaic cells  305 , a hybrid hydrogen chemical potential cell  306  and an area containing spark (inductor) voltage generator and miniaturized magneto circuitry  307 . The fiber optic wave guide  302  may include a core  303  and cladding  304 . Alternatively, the gas (xenon) bulb can be a solid state light source. This light then is transmitted through the fiber optic wave guide  302  enclosed in the endoscopic body  112 , and is ultimately emanated distally at the end manipulator as optical output. 
         [0047]    Alternative embodiments may include a solid state light source i.e. a diode light source as well as a laser source e.g. VCSEL (vertical cavity surface emitting laser), or a quantum cascade laser, a terahertz source, or a yttrium energy source. These embodiments can be used for therapeutic surgical laser treatment of tissues, (not merely illumination) as well as for tissue scanning. 
         [0048]    To constantly energize the power battery source  FIG. 3  illustrates a helical arrangement of thermoelectric conversion units and high efficiency photovoltaic cells  305  which recaptures heat and light (photonic) energy, respectively which is fed back to a recharge mechanism (not shown). Adjacent to the aforementioned cells  305  is a helically wound coolant tube  308  with liquid flow propelled by a combination of the battery and an electro osmotic unit (not illustrated). A hydrogen cell is ideally suited for this design as it requires constant flow of protons. This cell can be combined with a standard chemical cell for increased power capacity and reliability. This is denoted as a hybrid hydrogen chemical potential cell (Battery)  306 . 
         [0049]      FIGS. 4 , and  5 A and  5 B illustrate the spreading and beam guiding patterns for visible and laser light at the more distal end of the endoscope  100  close to the end manipulator  103 .  FIG. 4  illustrates the light or laser beam hereafter referred to as the “wave front”  404  entering the beam splitting section  405  which is composed of a three dimensional array of mirrors used to split and redirect the wave front. Illustrated is a beam splitting mirror  401  and a beam directed coated back mirror  402  which directs the wave front to one of twenty-five interior or exterior optical fibers  403   a ,  403   b . The interior fibers  403   a  preferentially transmit a laser light or radiation, but are also capable of transmitting visible light. The exterior fibers  403   b  preferentially transmit visible light but are capable of transmitting laser light or radiation. Whether or not the laser source or visible light source is transmitted can be programmed or controlled with additional electronics (not illustrated). 
         [0050]      FIG. 5A  illustrates the path of light distal to that illustrated in  FIG. 4 . We see the exterior fibers  403   b  which transmit visible light in this depiction. Each of these exterior cables  403   b  terminates within individual elliptical semi-enclosed directive reflectors  501 . These reflectors  501  which can be positioned electronically have the ability to form a beam of visible light unto an arbitrary direction. 
         [0051]    The Risley prisms or semi-coated mirrors  502  can be used as shown at the terminals of the interior fibers  403   a  to direct a coherent beam of laser light or radiation. Also illustrated are prism or mirror axial inserts  503  that can be electronically rotated to obtain the desired beam direction. 
         [0052]      FIG. 5B  is an en-face cross sectional image of the guide fibers  403   a ,  403   b  exiting at action end of endoscope exhibiting geometric arrangement of beams output. Illustrated are exterior fibers  403   b  (exaggerated cross sectional thickness) transmitting visible light (preferred) or laser light radiation with their respective surrounding electronically controlled elliptical semi-enclosed directive reflectors. Illustrated centrally are interior fibers  403   a  transmitting laser light or radiation (preferred) or visible light. 
         [0053]      FIGS. 6A and 6  B illustrate the endoscope on-board view of video or ultrasound capture at the action end of the endoscope. Illustrated is the monitor  601  and video processing housing  602  which can be rotated and hinged about the connecting ring  604  that can also allow automatic (gyroscopically based repositioning) or manual repositioning. The monitor  601  and video processing housing  602  consists of both monitor  601  and display which can be LCD and an alphanumeric or waveform data display  603 . The processing components can include application specific or standard integrated circuits with programmable video and image processing algorithms and protocols such as image enhancement through filtering or through multiple image combinations. Data is transmitted from either CCD (charge coupled device) or CMOS (complimentary metal oxide silicon) cameras that are fed straight to this unit (not shown) as well as to the electronic control panel  104 . 
         [0054]      FIG. 6B  illustrates examples of various positioning assumable by the system monitor  601  and data display  603 . 
         [0055]      FIG. 7A  represents the computer architecture of the TWEEAE electronics.  FIG. 7B  represents a listing of possible devices that will be made ready to receive the endoscopes transmissions.  FIG. 7C  illustrates a cloud and lightening icon which represents an air interface  701  of RF (radiofrequency) communication between the TWEEAE endoscope  100  and those devices listed in  7 B. 
         [0056]    In  FIG. 7A  the central processing unit  720  initially reacts to the user interface  721  while also interacting with the power, video and illumination micro-controllers  722 - 724 . The power micro-controller  722  is programmed to facilitate re-charging and charge control of the battery power system. The illumination micro-controller  724  is utilized to control light intensity, mirror positioning, lasing frequencies, and reports power requirements to the CPU  720 . The video microcontroller  723  interfaces with the signal processing integrated circuits as well as the transmitter and flash memory. The illumination microcontroller  723  additionally connects to the bulb which connects to the fiber optic guide wire  302 . 
         [0057]      FIG. 7B  lists an array of contemporary devices which can be made capable of receiving video transmissions via digital RF data packets. These devices include hand held units  702 , e.g. palm pilot  703 , mobile phone  704 , blue tooth enabled devices  705 , embedded devices  706 ; set top boxes  707  that connect to televisions  708  or computers  709 ; and custom devices  710  e.g. a hospital screen  711 , custom phone  712  and custom computers. 
         [0058]      FIGS. 8A-E  illustrate the adjustable jaw of biter at action end of endoscope. 
         [0059]      FIG. 8A  illustrates a cross-sectional orthonormal view demonstrating the mechanism of angling and positioning of the superior and inferior jaws  801 ,  802  to become a regular straight, up or down biter. The mechanism is initiated by rotation of pinion  803  for superior jaw position selector  804 . In turn the superior jaw position selector  804  rotates the action end of superior jaw  801  about the pivot axis  805  of jaws. There is also a superior jaw gear pivot  806  and an inferior jaw pivot  807 . The pinion  803  for pinion jaw position selector  804  is controlled either manually or electronically by a stepper motor (not shown). The action end of inferior jaw  802  is free in this embodiment to clamp matter against the action end of superior jaw  801 . In an alternative embodiment, not illustrated, an inferior jaw position selector can be incorporated to have the inferior jaw  802  fixed and the superior jaw  801  free. Not illustrated are the fiber light guides. 
         [0060]      FIG. 8B  illustrates the perspective view of superior jaw position selector  804 . Illustrated are the right pinion contact spurs  813  and left pinion contact spurs  810  which rotate the selector  804  due to the aforementioned action of the pinion  803 . The right and left contacts  811 ,  812  with the superior jaw gear pivots serve to adjust the superior jaw angle of attack and lock it in its place. The left to right disc bridge  812  connects the left and right sides of this selector  804  while allowing free space for uncompromised passage of light fibers. 
         [0061]      FIG. 8C  illustrates a cut-away cross sectional view of action end of endoscope  100 . This figure illustrates how the interior fibers  403   a  transmit laser light or radiation (preferred) or visible light through the mid-plane of the gear mesh. 
         [0062]      FIG. 8D  illustrates a full perspective view of end-effector manipulator with arbitrary angle superior jaw mechanism. This illustrates a transparent midsection  810  of jaws constructed from glass or polymer. In addition it illustrates three-dimensional views of the pinion  803  for superior jaw position selector  804 , the superior jaw position selector  804 , and the action ends of both the inferior and superior jaws  801 ,  802 . 
         [0063]      FIG. 8E  in addition illustrates the imaginary expected path of laser light or radiation (preferred) or visible light emanating from interior fibers  403   a  through end manipulator  103 . 
         [0064]      FIG. 9  illustrates the concept of rescue plates. If a standard lumbar disc plate  900 A falls out, it can be replaced with a plate  900 B with longer (or wider) spikes  901  or with a wider/thicker plate  900 C. 
         [0065]      FIG. 10  illustrates a lumbar disc plate extractor  1000 . If for some reason the lumbar artificial disc  1004  must be removed in order to perform a fusion or to change plate sizes, this plate extractor  1000  can be inserted between the plate  1004  and the vertebral body. Illustrated are the sharpened end point  1001 , the torque handle  1002  and the force transmitter  1003 . 
         [0066]      FIGS. 11A and 11B  illustrate a disc ball implanter/explantor  1100 . The instrument  1100  is composed of a tightening knob  1101  which rotates a pinion shaft key  1106  attached to a pinion shaft  1107  which then opens and closes, i.e. releases or grabs the disc ball  1108  with enclosing semi circles grapplers  1105 . A pinion shaft enclosure  1102  encloses pinion shaft  1107 . 
         [0067]      FIG. 11B  is an enlargement cross sectional view of the disc ball extractor handle  1103 . 
         [0068]      FIG. 11C  is an enlargement of the disc ball extractor grappler  1105 . This demonstrates the interface of the left enclosing semicircle  1111  and right enclosing semi-circle  1112  with the disc ball  1108 . Also demonstrated is the pinion  1114 , as well as the disc plate  1004  in the background. 
         [0069]      FIG. 11D  illustrates the grappler  1105  in an opened position. Centrally illustrated is the pinion  1114  inter-digitating with the left semi-circle spur rack  1112   a  and the right semi-circle spur rack  1111   a.    
         [0070]      FIG. 11E  illustrates the grappler  1105  in closed position. Note how the semicircles  1111 ,  1112  have moved away from each other by reversing inter-digitating directions along the pinion  1114 . 
         [0071]      FIG. 11F  illustrates the same image of  9 E with a ball  1108  inside, demonstrating how it is grasped. 
         [0072]    The inventions described herein further enhance the capacity to implant and explant posteriorly placed artificial discs. The unique totally wireless electronically embedded action ended endoscope herein described has the capacity to revolutionize and simplify the current practice of endoscopy in lumbar spinal surgery as well as all spheres of surgical and medical subspecialties utilizing endoscopy. It is also uniquely adapted for the military surgical field, and emergency, ambulatory and aerospace medical technology.