Patent Publication Number: US-2021169447-A1

Title: Identifying Anatomical Structures

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation of U.S. application Ser. No. 15/063,152, filed on Mar. 7, 2016 entitled IDENTIFYING ANATOMICAL STRUCTURES, which claims priority to U.S. Provisional Patent Application Ser. No. 62/129,866, filed Mar. 8, 2015 and entitled Device and Method for Identifying Anatomical Structures and to U.S. Provisional Patent Application Ser. No. 62/129,862, filed Mar. 8, 2015 and entitled Nerve Mapping System. U.S. application Ser. No. 15/063,152 is a continuation-in-part of International Application PCT/US15/50404, with an international filing date of Sep. 16, 2015 entitled IDENTIFYING ANATOMICAL STRUCTURES, which claims priority to U.S. Provisional Patent Application Ser. No. 62/051,670, filed Sep. 17, 2014 and entitled “DEVICE AND METHOD FOR IDENTIFYING ANATOMICAL STRUCTURES”. The contents of the applications listed above are hereby incorporated by reference in their entirety for all purposes. This application also incorporates by reference in their entireties for all purposes the following related applications: U.S. Provisional Application Ser. No. 61/847,517, filed Jul. 17, 2013, entitled Direct Visualization Dissector and Retractor System for Minimally Invasive Procedures, U.S. Provisional Application Ser. No. 61/867,534, filed Aug. 19, 2013, entitled Ultrasonic Visualization, Dissection, and Retraction System for Minimally Invasive Procedures, U.S. Provisional Application Ser. No. 61/868,508, filed Aug. 21, 2013, entitled OCT Visualization, Dissection, and Retraction System for Minimally Invasive Procedures, U.S. Provisional Application Ser. No. 61/899,179, filed Nov. 2, 2013, entitled Nerve Detection System, U.S. Provisional Application Ser. No. 61/921,491, filed Dec. 29, 2013, entitled System and Method for Identifying Anatomical Structures Ultrasonically, U.S. Provisional Application Ser. No. 61/929,083, filed Jan. 19, 2014, entitled System and Method for Identifying Anatomical Structures Ultrasonically, U.S. Provisional Application Ser. No. 61/977,594, filed Apr. 9, 2014, entitled System and Method for Identifying Anatomical Structures Ultrasonically Employing Two or More Transducers, and U.S. Non-Provisional application Ser. No. 14/329,940, filed Jul. 12, 2014, entitled Device and Method for Identifying Anatomical Structures. 
    
    
     BACKGROUND 
     Surgical techniques utilizing minimally invasive surgery (“MIS”) are being rapidly adapted to replace current traditional “open” surgical procedures. “Open” procedures typically require larger skin incisions that may cause significant collateral damage to uninvolved anatomic structures. For example, intervening soft tissue (e.g., tendons, ligaments, facet capsules, muscles, and so on) may be cut and even potentially excised to allow for direct surgical visualization of the operated-upon area or anatomical structure. 
     In contrast, minimally invasive techniques, which may also be referred to as “percutaneous” techniques, involve significantly smaller incisions and are less traumatic to the patient&#39;s anatomy. Soft tissues may be preserved with minimal collateral damage to the uninvolved anatomy. Typical benefits of MIS may include decreased blood loss, decreased postoperative pain, smaller scar formation, decreased cost, and a faster rehabilitation for the patient than in “open” or conventional surgical techniques. 
     Minimally invasive surgery techniques are currently being adapted to a variety of surgical procedures. For example, minimally invasive techniques in the form of laparoscopic procedures, such as a laparoscopic colectomy for carcinoma of the colon, have been developed. More recently, surgeons have utilized MIS in spinal surgery applications. 
     BRIEF SUMMARY 
     Present MIS techniques are unable to accurately and consistently detect and avoid key anatomical features, such as neural elements, potentially resulting in profound neurological sequelae and deleterious impacts to other systems. For example, even a minimally invasive surgical instrument, if impacting or contacting with nervous system elements (e.g., nerves, spinal cord) may result in loss of sensation, sensory overload, pain, or other unwanted or harmful effects. Detection and identification of anatomical features may assist in combating these problems and other problems that may become apparent upon reading of this disclosure. 
     Accordingly, in one aspect of the present disclosure, a device may be provided for minimally invasive surgery and may include a body comprising a proximal portion, a distal portion, and a main portion formed between the proximal portion and distal portion. At least one ultrasound transducer may be arranged at the distal portion of the body and may be configured to scan a region extending away from the main portion of the body. The device may include a signal processing unit having at least one processor and memory storing instructions that cause the at least one processor to receive a signal from the at least one ultrasound transducer and identify an anatomical structure based on the signal. 
     In some embodiments, the device may include a hollow channel and an annular shaped tip to allow the passage of surgical tools in the channel for performing procedures while collecting data for use in mapping anatomical tissues. In these embodiments, ultrasonic transducers may be arranged on the distal end of the device, on the annular shaped tip. 
     In another aspect, a device may be provided for minimally invasive surgery. The device may include a proximal portion, a distal portion, a main body formed between the proximal and distal portions of the device having a longitudinal axis and at least one ultrasound transducer disposed within the distal portion of the device and configured to scan a region adjacent to a distal end of the distal portion of the device. 
     In another aspect, a method may be provided and may include receiving data from at least one ultrasound transducer arranged at a distal portion of a body and configured to scan a region extending away from a main portion of the body. The method may also include processing the data to identify an anatomical structure located within the region, and outputting an indication associated with the anatomical structure. 
     In another aspect, a method for identifying a target anatomy may be provided with a device having a distal portion and at least one ultrasound transducer at least partially disposed within a main body of the device. The method may include scanning an anatomy of a patient anatomy for the target anatomy, determining a voltage trace of the patient&#39;s anatomy, comparing the voltage trace of the patient&#39;s anatomy to a predetermined voltage trace of the target anatomy, and sending a notification if the voltage trace of the patient&#39;s anatomy matches the predetermined voltage trace of the target anatomy. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a side view of one embodiment of a device. 
         FIG. 2  is a side view of another embodiment of the device of  FIG. 1 . 
         FIG. 3  is a functional diagram of the ultrasound imaging system that may be used in one embodiment of the present disclosure. 
         FIG. 4  is a diagram of an ultrasound transducer that may be used in one embodiment of the present disclosure. 
         FIG. 5  is another functional diagram of one embodiment of the ultrasound imaging system that may be used in an embodiment of the present disclosure. 
         FIG. 6  is one embodiment of the device having more than one ultrasound transducer disposed therein. 
         FIG. 7  is another embodiment of the device having one ultrasound transducer disposed therein. 
         FIG. 8  depicts the scanning width of a transducer. 
         FIG. 9  depicts the scanning width of a transducer in one configuration. 
         FIG. 10  is another embodiment of the present disclosure where one of the transducers is positioned at an angle with respect to the other transducer. 
         FIG. 11  depicts the scanning width of the embodiment of  FIG. 10 . 
         FIG. 12  is yet another embodiment of the present disclosure where two transducers are angled towards the longitudinal axis of the device. 
         FIG. 13  depicts scan images of a target anatomy taken by one embodiment of the present disclosure. 
         FIG. 14  is a scan and A-line image scan of the target anatomy captured by one embodiment of the present disclosure. 
         FIG. 15  depicts the configuration of one embodiment of the present disclosure. 
         FIG. 16  depicts images of the target anatomy captured by one embodiment of the present disclosure. 
         FIG. 17  depicts additional images of the target anatomy captured by one embodiment of the present disclosure. 
         FIG. 18  is a scan of the target anatomy captured by one embodiment of the present disclosure. 
         FIG. 19  depicts one embodiment of a retractor system that can be used with embodiments of the present disclosure. 
         FIG. 20  depicts one embodiment of the dilator system that can be used with embodiments of the present disclosure. 
         FIG. 21  is one embodiment of the present disclosure that is incorporated into a glove. 
         FIG. 22  is a partial side view of the embodiment disclosed in  FIG. 21 . 
         FIG. 23  is a front cross-sectional view of one embodiment of the glove embodiment disclosed in  FIG. 21 . 
         FIG. 24  is a front cross-sectional view of another embodiment of the glove embodiment disclosed in  FIG. 21 . 
         FIG. 25  is a front cross-sectional view of yet another embodiment of the glove embodiment disclosed in  FIG. 21 . 
         FIG. 26  is diagram of another embodiment of the present disclosure that utilizes Optical Coherence Tomography. 
         FIG. 27  is one embodiment the probe used with the embodiment disclosed in  FIG. 26 . 
         FIG. 28  depicts two embodiments of the probe used with the embodiment disclosed in  FIG. 26 . 
         FIG. 29  is a side view of one embodiment of the present disclosure having direct visualization capability. 
         FIG. 30  is a cross-sectional view of the embodiment disclosed in  FIG. 29 . 
         FIG. 31  is another embodiment of the present disclosure having direct visualization capability. 
         FIG. 32  is a partial cross-sectional view of the embodiment disclosed in  FIG. 31 . 
         FIG. 33  is a partial front cross-sectional view of the embodiment disclosed in  29 . 
         FIG. 34  is another embodiment of the present disclosure disclosed in  FIG. 29 . 
         FIG. 35  is a side cross sectional view of another embodiment of the present disclosure disclosed in  FIG. 31 . 
         FIG. 36  is yet another embodiment of the conduit disclosed in  FIG. 29 . 
         FIG. 37  is yet another embodiment of the conduit disclosed in  FIG. 29 . 
         FIG. 38  depicts one embodiment of the present disclosure in use with a retractor system. 
         FIG. 39  depicts one embodiment of the retractor system of the preset invention. 
         FIG. 40  depicts another embodiment of the retractor system of the preset invention. 
         FIG. 41  depicts an illustrative graph of Scan line energy as a nerve discriminant. 
         FIG. 42  depicts an illustrative user interface design window containing a designed bandpass filter and specifications. 
         FIG. 43  depicts an illustrative application of a bandpass filter on the received RF signals, thereby suppressing low frequency noise near the transducer surface. 
         FIG. 44  depicts examples of SVM classification schemes for separable and non-separable data. 
         FIGS. 45A  &amp; B depict a plot matrix showing two-dimensional (2D) relationships between the feature variables. 
         FIG. 46  depicts an illustrative receiver operating characteristic (ROC) curve defining performance of the trained SVM. 
         FIG. 47  illustrates a computing device in accordance with one or more aspects described herein. 
         FIG. 48  shows the device viewed from the distal end as in an embodiment of the present disclosure. 
         FIG. 49  shows the device viewed from the side as in an embodiment of the present disclosure. 
         FIG. 50  shows the distal face of the device as in an embodiment of the present disclosure. 
         FIG. 51  depicts placement of the device on the surface of the psoas muscle as in an embodiment of the present disclosure. 
         FIG. 52  is another depiction of the placement of the device on the surface of the psoas muscle as in an embodiment of the present disclosure. 
         FIG. 53  depicts a probe inserted into the device on the surface of the psoas muscle as in an embodiment of the present disclosure. 
         FIG. 54  depicts a nerve map in a viewing window in accordance with aspects of the present disclosure. 
         FIG. 55  depicts a visual representation of Kambin&#39;s triangle. 
         FIG. 56  depicts the device in a position targeting Kambin&#39;s triangle, as described herein. 
         FIG. 57  depicts a surgical incision targeting access to a location on the spine. 
         FIG. 58  depicts a surgical approach targeting a portion of the spine. 
     
    
    
     DETAILED DESCRIPTION 
     To help understand the present disclosure, the following definitions are provided with reference to terms used in this application. 
     Throughout this specification and in the appended claims, when discussing the application of aspects of the present disclosure with respect to the body&#39;s tissue, spine or other neural elements, the term “proximal” with respect to such a device is intended to refer to a location that is, or a portion of the device that is, closer to the operator. The term “distal” is intended to refer to a location that is, or a portion of the device, further away from the operator. 
     The embodiments below are described with reference to the drawings in which like elements are referred to by like numerals. The relationship and functioning of the various elements are better understood by the following detailed description. The embodiments as described below are by way of example only and the present disclosure is not limited to the embodiments illustrated in the drawings. 
     According to one or more aspects of the present disclosure, a device capable of detecting target anatomical structures may be provided. The device may utilize ultrasound and/or Optical Coherence Tomography (OCT) technology as the device is being advanced through a patient&#39;s anatomy. The device may have a distal portion having a tip, where the tip can be used to dissect a patient&#39;s anatomy without puncturing or tearing the patient&#39;s anatomy and while simultaneously allowing the device to inspect the anatomy as it is being dissected by the tip. While the device discussed herein is discussed in the context of a device that can be held by an operator, it is contemplated that the device and/or parts of the device may be used during automated procedures such as those being performed by robotic and other similar systems. 
     In one embodiment, shown in  FIG. 1 , the device  10  has a proximal portion  12  and a distal portion  14  with a main body  16  disposed between the proximal and distal portions  12 ,  14 . The main body  16  has a proximal end  18  and a distal end  20  and is defined by a longitudinal axis L. The proximal end  18  may have a handle (not shown) or gripping portion (not shown) attached thereto. The length of the main body  16  may vary, but can include a length of 50 to 300 mm; however, in some embodiments the length may fall outside of this range. Similarly, the outer diameter of the main body  16  may vary and can include an outer diameter of between 3 mm and 20 mm. The main body  16  can be made out of any preferable surgical grade material, including but not limited to, a medical grade polymer including PEEK (polyether ether ketone), stainless steel, carbon fiber, and titanium. The main body  16 , and one or more of the components of the device  10  generally, may contain radio-opaque markers to allow an operator to detect the location of the device  10  with respect to the anatomy of a patient via radiographic imaging. 
     As shown in  FIG. 1 , the distal portion  14  of the device  10  includes a tip  22 . The tip  22  may be hemispherical in shape, as illustrated in  FIG. 1 , but it is contemplated that the tip  22  may also be of a different shape. For example, and without limitation, the tip  22  may have a semi-spherical, conical, pyramidal, spear or aspherical shape. The tip  22  may be configured to dissect a patient&#39;s anatomy, such as a muscle, without tearing or disrupting the patient&#39;s anatomy as it passes through the tissue. As a result, the outer diameter of the tip  22  may have a diameter ranging anywhere between 1 mm and 50 mm and preferably between 2 mm and 9 mm. It is appreciated that the outer diameter of the tip  22  may fall outside of this range as well. It is further appreciated that the tip  22  is optional such that particular embodiments of the device  10  may not include the tip  22 . 
     As illustrated in the embodiment shown in  FIG. 1 , the main body  16  of the device  10  may be substantially straight. However, it is contemplated that the main body  16  may have different shapes, including having a curved shape with a non-zero radius of curvature. An example of such an embodiment is illustrated in  FIG. 2 , which may be used for MIS requiring access through the presacral space of a patient. The main body  16  may also take on an “L”, “C”, “U” shape or a shape there between. 
     The device  10  may include ultrasonic capability. A purpose of this device may be to serve as an instrument that features a specifically patterned array of high frequency ultrasound transducers and a monitoring system that collects spectral properties of specific tissue in the body. For example, the system may be able to detect the spectral properties of muscle, fat, nerve and bone. As the anatomy is stimulated by the ultrasound transducer(s), it will emit a specific spectral property that can be detected by the monitoring system. The system may examine scan line images and seek specific parameters of amplitude, shape, and other spectral content in order to differentiate the signals coming from the nerve and signals coming from surrounding tissues. For example, nerve tissue may be hypoechoic as compared with the surrounding tissue. However, there are internal structures that provide features in the signal that identify the nerve from single scan lines or RF properties. The system will inform the operator that the device is adjacent to or proximate to the specific type of anatomy that is detected by the system. The device can allow a surgeon to identify and avoid certain portions of a patient&#39;s anatomy (e.g. nerve) when performing a minimally invasive procedure. 
     The device  10  may be equipped with ultrasound imager  24  to detect a patient&#39;s anatomy as shown in  FIGS. 3-5 . The ultrasound imager  24  may include a transducer  26  that is configured to emit sound waves and may be disposed at the distal end  20  of the device  10 . As shown in  FIG. 4 , the transducer  26  may include a single element focused transducer, and may have a frequency operation range that includes an operating range of approximately 10-40 MHz. In some aspects, the operating range may be higher or lower than this range of frequencies. Additionally or alternatively, transducer  26  may include a micro machined array, such as a capacitive micromachined ultrasonic transducer (CMUT), having multiple channels. The desirable frequency may vary depending on the application and target anatomy. For example, in one embodiment a frequency or range of frequencies may be selected for detecting nerve from surrounding tissues and adjacent anatomy on b-mode (2D) ultrasound images based on image texture and echogenicity. Reliably distinguishing between nerve and muscle tissue in real time may require quantitative approaches, and may require automated or manual calibration of the system to estimate tissue-specific properties. In some aspects, a meta-analysis comparing ultrasound to nerve-stimulation may result in superior outcomes for ultrasound guidance. 
     As shown in  FIGS. 3 and 5 , the transducer  26  may be in communication with a RF-pulser/receiver  28 , which may be in communication with an analog to digital converter  30 , which may be in communication with a digital signal processor  32  and an output  34  such as a monitor. 
     In one embodiment, the transducer  26  converts an electric signal or pulse generated from the RF-pulser/receiver  28  into a sound wave and then converts a reflected sound wave back into an electrical signal. The ultrasound transducer  26  launches sound pulses, which may be short, high-frequency non-damaging sound pulses, into the tissue, and then may wait to hear the reflection from the tissue. Since the speed of sound in tissues is high (˜1500 m/s), this process may take a few milliseconds to image a few millimeters of tissue. As referenced above, the RF-pulser/receiver  28  may generate an electrical impulse that may be sent (e.g., via a cable) to the transducer  26  to generate a sound wave, and may also receive a signal from the transducer  26  generated by the reflected sound waves that the transducer  26  receives. The analog to digital converter  30  converts the analog radiofrequency signal received from the transducer  26  into a digital form that a computer may analyze. The digital signal processor  32  processes the digitized signal received from the digital converter  30 . Signal filtering and processing operations may be programmed into the hardware, firmware, and/or software of various components of the system (e.g., the digital signal processor  32 ) to detect the reflected signal properties of the tissue and distinguish between nerve and muscle tissues in real-time. Once a nerve tissue signature is detected, a hardware, firmware, and/or software system may communicate with the output  34 . The output  34  may include a visual monitor that may be programmed to display the anatomy or signals indicative of the anatomy (e.g., via actual images or programmable color configurations (red/yellow/green)) and/or a sound-generating device which may be controlled to emit an audible indicator (e.g. alarm or a “beep”). For example, the sound-generating device, such as a speaker, may emit a “beep” when the device  10  encounters/detects the presence of target anatomy (e.g. nerve) within a predetermined range (e.g. 1 mm to 10 cm). 
     It is appreciated that one or more of these components may be in wireless communication with one another, may be combined into one or components, and other additional components may be in communication between each of these components or one or more identified components and may not be included in a particular embodiment. 
     In one embodiment, the outer diameter of the transducer  26  may be approximately 3 mm, but may range anywhere between approximately 1 mm and 10 mm. Further, the transducer  26  is configured to be disposed in a variety of locations with respect to the device  10 . For example, as shown in  FIG. 6 , the transducer  26  may be disposed at the distal end  20  of the main body  16  or at the tip  22  portion of the distal end  20 . The transducer  26  may also be removable such that it can be removably disposed within a conduit  36  formed within the device  10  and removed once a working space is identified and accessible. In some aspects, the working space may be the space created by insertion and/or manipulation of the device  10  within the patient&#39;s anatomy. 
     Multiple transducers  26  may be provided as part of the device  10 . In some aspects, two or more transducers  26  may be side positioned (e.g. on either side of the main body  16 ) so as to provide for multi-directional scanning of the patient&#39;s anatomy to detect a nerve. The side positioned transducers may be configured to scan the anatomy around in a circumferential direction around the main body  16 , and may detect the nerve (or other target anatomy) that was not detected by a transducer positioned at the distal end  20  of the main body  16 . The multi-directional scanning enables the system to generate a scan image of the patient&#39;s anatomy in multiple directions as the device  10  is advanced through the patient&#39;s anatomy. 
     Returning to  FIG. 6 , the device  10  may include at least one ultrasound transducer  26  (such as a high frequency ultrasound transducer) that is used to stimulate a patient&#39;s anatomy, such as muscle, fat, nerve, and bone, and so on. A series of transducers  26  (e.g., a transducer, two or more transducers) may be disposed along the length of the device  10  to allow for a wider pattern of ultrasonic stimulation of the surrounding anatomy. In this embodiment, there may one transducer  26  on the distal end of the device  10  that emits an ultrasonic frequency in a direction that is substantially parallel to the longitudinal axis of the device  10 . There may be another transducer  27 , adjacent to the first transducer  26 , that emits ultrasonic frequency along a path that is substantially perpendicular to the longitudinal axis of the device  10 . It can be appreciated that the transducers  26  and  27  can be orientated in any direction that is required for the particular application. 
       FIG. 7  depicts one embodiment where a 5 MHz transducer  26  is located on the distal end  21  of the device. In such an embodiment, the diameter of the transducer  26  may be 3 mm and the transducer may be forward facing. In such an embodiment, the scanning range is approximately 14 mm. In some aspects, an area of the scanning region (hatched section in  FIG. 8 ) by a transducer  26  may not exceed the outer diameter of the transducer. This may be because the scanning width is circumscribed by the outer diameter of the transducer  26  and the peripheral limitations of the transducer  26  such that the transducer  26  cannot identify or scan a region that lies beyond of the diameter of transducer  26 . 
     Accordingly, in some aspects such as those disclosed herein where the transducer  26  is housed within a device  10 , the transducer  26  may be unable to scan the region that is directly front of (distal to) the outer portions of the device that houses the transducer  26 . This region  44  is depicted in  FIG. 9 . One result of this is that the target anatomy may go undetected if it is positioned beyond the scanning region of the transducer  26 . 
     In some aspects, for example to detect target anatomy that lies just beyond the scanning region of the transducer  26  (i.e. outside of the scanning diameter), the device  10  may include two or more transducers positioned at an angle relative to one another. For example, as shown in  FIGS. 10 and 11 , the first transducer  40  may be positioned at an angle with respect to the outer edge of the main body  16 . The angle may be measured from the face of distal end  21  of the device  10 , or may be measured from the horizontal axis that intersects the longitudinal axis of the device  10 . The angle α in this embodiment is 7° but it is appreciated that it can vary from 0° to 180° depending on the particular embodiment. Further, in this embodiment, the angle may be formed between the edge of the transducer  26  and the adjacent outer edge of the main body  16 . 
     Transducer  40  may be angled with respect to any portion of the main body  16 . For example, the first transducer  40  may be angled by pivoting the first transducer  40  about the portion positioned along, or closest to, the longitudinal axis of the main body  16  as shown in  FIG. 12 . Specifically, as shown in  FIG. 12 , the transducers  40 ,  42  may be angled towards the longitudinal axis of the main body  16  such that the angle of tilt, al aa, are measured as the angle of the transducer from the longitudinal axis of the main body  20 . 
     In the embodiment shown in  FIG. 10 , the first transducer  40  may be positioned at an angle (e.g., 7° from the edge of the main body  16 ) allowing the first transducer  40  to scan a region extending beyond the outer edge of the main body  16 . Angling the first transducer  40  may allow the device  10  to scan and detect any target anatomy residing outside of the scanning region of a transducer that is not angled with respect to the main body  16  of the device. A region that may be scanned by the first angled transducer  40  in this particular embodiment is shown in  FIG. 10 . 
     The two transducer elements may fit on the tip of a device  10 . This may allow, for example, the device  10  to detect backscattered signals. In some aspects, the device  10 , and/or the two transducer elements may be configured to detect the presence of nerves or other neural elements existing distally up to 1 cm from the probe tip  22  (e.g., the nerves or neural elements may be in the pathway of the device). In some aspects, a device may be provided with transducers having different stimulating frequencies (e.g., a first transducer  40  may stimulate with a frequency of 5 MHz, and a second transducer may stimulate with a frequency of 10 MHz). Beam patterns or fields emitting from the sources may be modeled using an ultrasound simulation program assuming an element diameter of 3 mm and a focal number of 3 (f/3). 
     In some aspects, two transducer elements  40 ,  42  may be positioned at the tip of the probe. The tilted element  40  faces outward with an angle of tilt, such as 7°. The tilted element may have one end at the edge of the probe. The un-tilted element  42  may be centered from the edge of the distal portion of the device  10 . This configuration may allow the device  10  to be rotated as it is snaked through the tissue so that the cross sectional surface area of the probe may be at least 1 cm above the probe surface. 
     The diameter of the transducers  40 ,  42  may vary and can range from 1 mm to 20 mm. For example, in the embodiment shown in  FIG. 10 , the first transducer and second transducers  40 ,  42  each have a diameter of approximately 3 mm. It is not necessary for the transducers to have the same diameter of one another and they may be staggered as shown in the top view of  FIG. 10 . 
     The main body  16  can be rotated so as to allow the first transducer  40  to scan the entire outer region to detect whether any target anatomy is present that is just beyond the scanning area of a forward facing transducer. By rotating the main body  16  about its longitudinal axis, the first transducer  40  can scan the outer region that does not fall within the scanning region of a transducer that is not angled with respect to the main body  16  of the device. 
     The number of angled transducers may vary and they may be positioned at various angles with respect to the distal end of the main body  16 . For example, as shown in  FIG. 12 , the first and second transducers  40 ,  42  are positioned toward one another so that their scanning areas cross to provide a scan of the area distal to the distal portion  20  of the device  10  and a region beyond the area directly in front of to the outer diameter of the transducers  40 ,  42  as shown in  FIG. 9 . Also, the transducers  40 ,  42  may be positioned at an angle on more than one axis with respect to the distal end of the main body  16 . 
     The device  10  can be configured to determine the b-mode scans of the patient&#39;s anatomy and associated data, including, for example, the voltage trace from a scan line in the b-mode image. The voltage trace for certain anatomical parts (e.g., a nerve) may have a unique voltage trace that may be used to detect like anatomical parts within the patient&#39;s anatomy. One way to detect like anatomical parts may be by comparing the voltage trace from a scan line of a b-mode image to the known voltage trace from the scan line of the target anatomy. Specifically, the b-mode scans (and associated data, such as a-scan lines, voltage traces, and the like) may be captured by the device  10 . The scans and/or data may be compared to the pre-determined b-mode scans (and associated data) of known anatomical features (e.g., nerve) to determine whether the region captured by the b-mode scan from the device  10  contain the target anatomy. 
     The device  10  may be used in conjunction with a neuromonitoring system capable of detecting certain portions of a patient&#39;s anatomy, including neural elements that include a nerve, nerve bundle, or nerve root. For the purposes of this discussion, the device  10  and neuromonitoring system will be discussed with respect to detecting a patient&#39;s spinal nerve but it is contemplated that the device  10  and neuromonitoring system can be used to detect other nerves (peripheral and central) as well as the spinal cord. One type of neuromonitoring system that can be used in conjunction with the device  10  is disclosed in U.S. Pat. No. 7,920,922, the entirety of which is incorporated by reference herein. 
     Experimentation 
     The discussion below is directed to the experiment used to determine the target ultrasonic frequency that can be used to detect nerve using the device  10  and whether the b-mode scan images captured by the device  10 , which is inserted into the patient&#39;s anatomy, is comparable to results captured by traditional non-invasive ultrasound devices. Both target objectives were accomplished using the following process. 
       FIG. 13  illustrates exemplary data indicative of a scan of a sciatic nerve of a rabbit with a clinical ultrasound array system. The scan was performed before and after euthanizing the rabbit to be sure that the nerve could be seen in both cases.  FIG. 13  depicts b-mode images (nerve cross-sectional view) for alive (left, image  1300 ) and dead (right, image  1350 ). The nerve may be seen in each case (area pointed to by white arrow on image  1300  and image  1350 ). 
     The nerve was scanned using a high frequency (40 MHz) probe with the bottom of the nerve still attached to the muscle and the nerve centered in the probe&#39;s depth of field.  FIG. 14  illustrates a b-mode image  1400  of this scan. The image  1400  shows (from top to bottom): water, nerve, and muscle. The nerve separates from the muscle towards the right side of the image, and you can see a gap between the nerve and the muscle.  FIG. 14  also illustrates a plot  1450  depicting the voltage trace from a scan line in the center of the b-mode image, indicated by the vertical line. 
     The hind limb sciatic nerve was scanned with a 20 MHz single-element probe though the leg muscle. The muscle was kept intact, and the skin removed to provide a window to see into the muscle. The image  1500  shown in  FIG. 15  illustrates the setup. 
     A clinical scan was performed before scanning with the 20 MHz probe. Images  1600  and  1650  from the clinical scan of the nerve are shown in  FIG. 16 , and images  1710  and  1720  from the scan performed by the 20 MHz probe are shown in  FIG. 17 . A comparison between the clinical imaging system and the 20 MHz probe system suggests that both techniques produce similar images. For example, the cross-section and length-wise (with respect to the long direction of the nerve) scan planes both show the nerve in the background muscle for both the clinical system and the 20 MHz system. 
     The 20 MHz results are important for at least two reasons: First, the results show that the contrast inside the muscle exists at 20 MHz as demonstrated in the left image  1710  in  FIG. 17 . Second, the depth of penetration for the 20 MHz signal was sufficient to be seen at more than 1 cm of depth. This may be the distance away from the surgical probe required for detecting the nerve. Therefore, this suggests that if the signals can be used to detect the nerve, the signal strength and penetration should not be an issue at the chosen ultrasound frequencies. 
       FIG. 18  depicts an image  1800  of a single scan line through the nerve. There are characteristic signatures from the nerves that can be used to detect the nerve from a single scan line. 
     In another experiment, a dual element transducer  40 ,  42 , having a configuration similar to the embodiment disclosed in  FIG. 10  was utilized. This embodiment was used for testing of sciatic nerves of  22  rabbit legs post-mortem. A total of 142 sets of radio frequency (RF) data were collected. Each slice of data was recorded over a 30 mm lateral distance capturing an axial region of approximately 5-20 mm from the transducer surface. Imaging performance was evaluated when conducting a sector scan of −35° to 35° at a depth of up to 1.5 cm and a center frequency of up to 15 MHz. The ultrasonic transducer used for scanning was dual-element, 10 MHz transducer, where each element was 3 mm in diameter with an f-number of 3. Images were acquired using a Pulser/Receiver, the settings of which are shown in the table below. 
     
       
         
           
               
             
               
                 TABLE 1 
               
               
                   
               
               
                 Pulser/Receiver settings 
               
               
                   
               
             
            
               
                   
               
            
           
           
               
               
               
               
            
               
                   
                 Pulse Repetition Frequency 
                 200 
                 MHz 
               
               
                   
                 Energy 
                 12.5 
                 uJ 
               
               
                   
                 Damping 
                 25 
                 Ohms 
               
               
                   
                 High Pass Filter 
                 1 
                 MHz 
               
               
                   
                 Low Pass Filter 
                 20 
                 MHz 
               
               
                   
                 Input Attenuation 
                 0 
                 dB 
               
               
                   
                 Output Attenuation 
                 0 
                 dB 
               
               
                   
                 Gain 
                 20 
                 dB 
               
               
                   
                   
               
            
           
         
       
     
     As discussed above, the device was used to capture an ultrasonic B-mode image, where the sciatic nerve may be identified as an isolated, hyperechoic region, usually elliptical or circular in nature as seen below. As such, one of the first attempts to classify the images was based on the thresholding on the energy of the received scan line. From the data displayed in  FIG. 41 , for example, it may be seen that the scan line energy does allow for the detection of the presence of the sciatic nerve. Using energy alone, however, as a classification criterion may not be adequate to distinguish between the diffuse, weak signature of the nerve with the sharp, strong signature of an isolated strong scatterer (e.g., data point  4100  in  FIG. 41 ). 
     Low frequency ringing may also be present in the received RF scan lines, particularly near the surface of the transducer. Spectral analysis of the ringing may indicate a high noise component, such as a noise component between 500 kHz and 2 MHz. To combat this noise, the received RF may be passed through a finite impulse response (FIR) bandpass filter, such as software, hardware, and/or firmware configured using the design specifications described in Table 2 and illustrated in example user interface  4200  of  FIG. 42 . Furthermore, an illustrative output  4300  of the bandpass filter is shown in  FIG. 43 . 
     
       
         
           
               
             
               
                 TABLE 2 
               
             
            
               
                   
               
               
                 Bandpass filter design specifications 
               
            
           
           
               
               
               
            
               
                   
                 Type 
                 Optimal Equiripple 
               
               
                   
                   
               
               
                   
                 Order 
                 296 (minimum order) 
               
            
           
           
               
               
               
               
            
               
                   
                 Sample Frequency 
                 250 
                 MHz 
               
               
                   
                 Fstop1 
                 5 
                 MHz 
               
               
                   
                 Fpass1 
                 7 
                 MHz 
               
               
                   
                 Fpass2 
                 15 
                 MHz 
               
               
                   
                 Fstop2 
                 17 
                 MHz 
               
               
                   
                 Astop1 
                 60 
                 dB 
               
               
                   
                 Apass (ripple) 
                 0.3 
                 dB 
               
               
                   
                 Astop2 
                 60 
                 dB 
               
               
                   
                   
               
            
           
         
       
     
     Since classification of the nerve using only the scan line energy may not yield satisfactory results, it is appreciated that a multivariate classification approach can be explored. One commonly used multivariate classification algorithm is a support vector machine (SVM). A SVM may be a supervised learning algorithm that attempts to find an optimally separating hyperplane between two labeled sets of data. Each observation within the data sets consists of a number of features, which may be in some aspects descriptive variables that may be used to help classify the data. 
     For example, with reference to SVM classification schemes  4410  and  4420  in  FIG. 44 , consider the two-dimensional classification problem below. The i th  observation in the training set is associated with a feature vector x (i) =(x 1   (i) , x 2   (i) ) and a data label y (i) ∈{−1,1} which describes the observation&#39;s class. Any hyperplane over the feature space may be defined as {x:f(x)=β T x+=β 0 =0}, where β is a vector. The general goal of the SVM is to solve the optimization problem 
     
       
         
           
             
               min 
               
                 β 
                 , 
                 
                   β 
                   0 
                 
               
             
              
             
                
               β 
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             subject to the constraint y (i) (β T  x (i) +β 0 )≥1 
           
         
       
    
     for all i in the training set. By solving this optimization problem, the SVM may locate the hyperplane which maximizes the margin between separable data. Once the values for β and β 0  are found, new events may then be classified based on which side of the hyperplane they lie, or equivalently: 
         ŷ ( x )=sign(β T   x+β   0 )
 
     This simple form of SVM works for separable data, like the case in  FIG. 44  on the left (e.g., scheme  4410 ). However, in many cases the data may not be separable, such as the case on the right (e.g., scheme  4420 ). In this case, the SVM must change the optimization problem to include slack variables, ξ i , into the optimization problem. The new optimization problem is then given by 
     
       
         
           
             
               
                 min 
                 
                   β 
                   , 
                   
                     β 
                     0 
                   
                   , 
                   
                     ξ 
                     i 
                   
                 
               
                
               
                   
               
                
               
                 
                   1 
                   2 
                 
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                      
                     β 
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                   2 
                 
               
             
             + 
             
               C 
                
               
                 
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                   i 
                 
                  
                 
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                   i 
                 
               
             
           
         
       
       
         
           
             such 
              
             
                 
             
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             that 
           
         
       
       
         
           
             
               
                 y 
                 
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     By adding these slack variables, the constraint is now much less restrictive, since the slack variables allow for particular data points to be misclassified. The amount of misclassification may be controlled by the reweighting factor C known as the box constraint. In some aspects, the box constraint may be a parameter specified by the operator. When the box constraint is high, the optimization algorithm may force the slack variables to be small, thus resulting in a more restrictive classification algorithm. 
     Some classification problems do not automatically lend themselves to simple linear decision boundaries. In these cases, a feature set may be transformed into a different domain before attempting linear separation. For example, the instances of x may be replaced with the transformed version h(x). Typically these feature transformations are specified by their kernels. The kernel of the transformation is defined as the inner product between transformed feature vectors, or symbolically, 
         K ( x   (i)   ,x   (j) )=   h ( x   (i)   ,h ( x   (j) )   
     A commonly used kernel may be the radial basis function or Gaussian kernel, which may have the form 
     
       
         
           
             
               K 
                
               
                 ( 
                 
                   
                     x 
                     
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     In practice, Gaussian kernels are generally known to perform well in nonlinear classification. However, Gaussian kernels also add another degree of freedom to optimize over: the width parameter σ. This is yet another parameter which may have to be tuned by the operator depending on the target anatomy. 
     For each scan line, a set of features may be generated based on the statistical information of the received RF data and envelopes. In order to help mitigate corruption due to isolated strong scatterers, statistics based on the log of the envelope may also be computed. The identity and uniqueness of the classifier to the problem is the combination of the feature set used to build the classifier. A complete list of features is given below. It is appreciated that for a particular embodiment, any combination of these features may be used for the SVM to identify the target anatomy: (1) skewness of the received RF, (2) mean of the envelope, (3) variance of the envelope, (4) skewness of the envelope, (5) kurtosis of the envelope, (6) mean of the log of the envelope, (7) variance of the log of the envelope, (8) skewness of the log of the envelope, (9) kurtosis of the log of the envelope. 
       FIG. 45  illustrates a plot matrix  4500  demonstrating that the above-recited features do not appear to completely discriminate scan lines containing the nerve from scan lines that do not. Most of the data does not appear to follow a simple linear decision boundary, so a Gaussian kernel with σ=1 was used to help preserve nonlinear tendencies. The box constraint parameter was also set to 1 during training. 
     To evaluate the performance of the SVM, an evaluation metric may be computed by a specially-programmed computing device. In some aspects, the receiver operating characteristic may be used as an evaluation metric. For example, as a classification algorithm, the ROC curve plots the true positive rate vs. false positive rate, thus displaying the different trade-offs between operating at various threshold levels.  FIG. 46  illustrates the results  4600  of the ROC plot, indicating that the classification algorithm appears to have good performance based on the training data distributions. 
     The testing demonstrated that a Gaussian-based SVM can be a powerful tool in determining the presence of the sciatic nerve in a single scan line. The majority of the power of any multivariate algorithm lies within the features used to describe the data. Utilizing just a single scan line, the system may be able to achieve a true positive rate of over 80% and a false negative rate of less than 10%. 
     Additional techniques contemplated include post-processing schemes, such as time gain compensation, to accentuate deeper features in the tissue, or using filters such as median filters to remove some of the strong peaks from the energy signals. 
     The detection of the nerve (or any other anatomical feature) may be automated. Once the anatomical feature is detected, an audio or visual signal such as “beeping” sound or a flashing light signal (or similar signal) may be given to a physician to indicate that they, or the device, are within a certain distance from the nerve. 
     Automatic detection of nerve may be based on single scan lines, and may compare the b-mode scan lines captured by the probe with the known scan lines of the target anatomy. In some aspects, the detection system may notify the operator that the captured scan lines are identical to, or are within a certain predetermined value of, the known scan lines of the target anatomy (e.g., the known scan lines of the target anatomy may represent a unique signature). The detection system may also be calibrated to determine the proximity of the tip of the probe to the target anatomy and notify the operator when the tip of the probe is within a set distance (e.g. 1 mm). Furthermore, the system may be configured to notify the operator of the spatial location of the target anatomy and/or inversely the spatial location of non-target anatomy. 
     Further Details Regarding Aspects of the Present Disclosure 
     In some aspects, the device  10  may be equipped with an image capture system  200  as shown in  FIGS. 29 and 30  used to detect certain portions or aspects of the anatomy (e.g., nerve or vessels). The image capture system  200  may also be used independently of, or in conjunction with, the ultrasound imager  24 , as described above in the device  10  embodiments, and/or may be used as a stand-alone or a complimentary detection technique to the ultrasound imager  24 . In some aspects, the tip  22  in this embodiment may be a lens  23  that has an outer surface  202  and an inner surface  204 . It is appreciated that the outer surface  202  of the lens  23  need not be the same shape of the inner surface  204  and may differ depending on the desired optical performance. The lens  23  may or may not provide a magnification of an image, I, beyond the lens  23 . In this embodiment, the lens  23  provides no magnification. The lens  23  in this embodiment is clear, but can also be tinted or provided with a color filter as will be discussed below and may have anti-fog, anti-condensation, and/or anti-reflection coatings or properties. 
     As further seen in  FIG. 30 , the distal portion  14  of the device  10  further includes the image capture system  200  having an image capture device  201 . The image capture device  201  may include an image capture sensor  206  that is disposed adjacent to the distal end  20  of the main body  16 . The image capture device  201  can be connected to a flexible sheath  203  that may carry a fiber optic cable  205  that connects the image capture device  201  to a housing  207  that houses the image processing components. It is also contemplated that the image capture device  201  can be wirelessly coupled to the image processing components. 
     An image capture output device may be included that is in communication with an image control system that can adjust the properties of the image quality. It can also be appreciated that the image capture device  201  may wirelessly transmit images and video to the image control system without any hard wired components. The term “image capture device” may include devices configured to record or capture either still or video images, such as video cameras, digital cameras, CCD sensors, and the like. One example of an image capture device that may be used with the device may be a 1/18″ CMOS camera with OMNIVISION sensor OV  6930 . However, those skilled in the art will easily contemplate the settings &amp; components such as the “image capture device,” illumination device, and the like in accordance with the present disclosure as described herein. 
     In one aspect, the image sensor  206  of the image capture device  201  may be disposed within the distal portion  14  of the main body  10 . The image sensor  206  or the capture device  201  may be at the most distal end  20  of the main body  16  such that it forms a distal surface  210  of the image sensor  206  (or capture device  201 ) or is flush with the distal end  20  of the main body  16 . In some aspects, “image sensor” may be synonymous with “image capture device.” In some aspects, the image sensor  206  may be set back proximally from the distal end  20  of the main body  16 , depending on the application. For example, the image sensor  206  may be recessed from the distal end  20  of the main body  16 . Alternatively, the image sensor  206  or the image capture device  28  may extend from the distal end  20  of the main body  16  towards the inner surface  204  of the tip  22 . 
     The image capture device  201  may define an optical axis O. As shown in  FIG. 30 , the optical axis O is the axis collinear with the longitudinal axis L defined by the main body  16  as discussed above. However, the optical axis O may also be or offset from the longitudinal axis L. The image capture device  201  will have a field of view a, varying between 5 and 180° depending on the specific application. 
     The image capture device  201  may be configured to capture an image I that exists just beyond the outer surface  202  of the tip  22 . Specifically, as better shown in  FIGS. 31 and 32 , the tip  22  may be configured to dissect the anatomy of a patient, designated here as element  212 . As seen here, the tip  22  while dissecting the anatomy may create a working space  214  by way of its shape. This may enable the image capture device  201  to view the anatomy during the dissection process instead of having the anatomy directly abut the image capture device  201  which may distort the image quality. 
     In this embodiment, the working space  214  may be defined as the space between the distal surface  210  of the image capture device  201  and the outer surface  202  of the tip  22 . The working space  214  may permit the image capture device  201  to view a portion of the anatomy that is within its viewing angle α. Without the working space  214 , the anatomy might abut and thereby obstruct the image capture device  201  thereby preventing an illumination device  216  from illuminating the anatomy and the image capture device  201  from capturing an image. The working space  214  in some aspects may be primarily filled with air, but it can be appreciated that the working space may be filled with other materials, such as a liquid or other gases. In the alternative, the working space  214  may be created by a tip that is solid such that the inner surface  204  of the tip  22  is adjacent to the distal end  20  of the main body. It can be appreciated that the working space  214  may create a distance between the outer surface  202  of the tip  22  and the image capture device  201  of 2 mm to 10 mm or greater    
     The distal portion  14  of the main body  16  may also include the illumination device  216 , as shown in  FIG. 33 , which is a cross sectional view of  FIG. 30 . The illumination device  216  may include a set of light emitting diodes  218  (“LED”). It can be appreciated that the number of LEDs  218  and the location of each LED  218  with respect to the image capture device  201  may vary. For the example, there may only be one LED  218  for a particular application. Conversely, there may be as many as four or more LEDs  218 . In some aspects, the LEDs  218  are spaced equidistant from one other, but it is not a requirement and the LEDs  218  may not be equally spaced. Other illumination devices  216  may include a light source such as near-infrared LED, mid-infrared LED, other LEDs of various wavelengths ranging from UV to infrared, or any similar light source known in the art. The illumination device  216  may also take the form of a light source emitting from an annular ring around the image capture device  201  or a plurality of light fibers angularly spaced around the image capture device  201     
     The illumination device  216  in the device  10  may be disposed within the distal end  20  of the main body  16 . However, the illumination device  216  may be external to distal end  20  or tip  22  or be embedded in the tip  22  such that the illumination device  216  does not create reflection on the inner surface  204  of the tip  22 , as a reflection may impair the field of visibility of the image capture device  201 . For example, and without limitation, the illumination device  216  may be disposed on either side of the longitudinal axis L of the main body  16  as shown in  FIG. 34  and distal from the distal end  20  of the main body  16     
     Regardless of the type of illumination device  216 , the intensity of the illumination device  216  may be adjusted to as to change the level of illumination of the anatomy of a patient. Moreover, if the illumination device  216  includes more than one illumination sources, certain of the illumination sources may be turned off while others remain on, and that the intensity of each source may be independently adjusted. 
     The illumination device  216  may also include color filters to as to highlight certain features of the patient&#39;s anatomy such as a nerve or vessel, through a filter. In some aspects where the illumination device  216  consists of one or more LEDs  218 , different color LEDs, such as red blue, yellow, green or others, may be used to enhance or highlight certain features of a patient&#39;s anatomy. One alternative to placing the filters with the illumination device  216  may be to include the filters with image capture device  201 . The filters may include color filters, including red, orange, yellow, green, magenta, blue, violet, and the like. The filters may also include band pass-filters, such as UV, IR, or UV-IR filters to better view the desired anatomy. Alternatively, or in conjunction with the above, the illumination   device  216  may rely on ultraviolet to detect certain features of the patient&#39;s anatomy, such as a nerve. In this embodiment, the illumination device  216  may include a light source irradiating the desired portion of a patient&#39;s anatomy with illumination light including excitation light of a wavelength band in an ultraviolet or visible region. It is also contemplated that the illumination device  216  may have both illumination means for emitting illumination light in the visible and ultraviolet regions simultaneously and where the image capture device having an appropriate spectral response can capture images in both regions    
     The illumination device  216  may have an illumination axis IA as disclosed in  FIG. 35 . The illumination axis IA may or may not be collinear with the optical axis O or the longitudinal axis L of the device. The illumination device  216  and location of the illumination axis IA may result in a reflection captured by the image capture device  201  that may distort the image of the patient&#39;s anatomy. The reflection may be caused by the rays generated by the illumination device  216  reflecting from an outer surface  202  or inner surface  204  of the tip  22  or the lens  23 . To minimize and/or eliminate the reflection caused by the illumination device  216 , the illumination axis IA may be displaced relative to the optical axis O of the image capture device  201 . In the aspect as shown in  FIG. 35 , the optical tip is shown as a solid lens with the elliptical outside surface  202 . One property of elliptical surfaces is that if a light source is placed at one focus, all light rays on the surface of the ellipse are reflected to the second focus. Each of two light sources  216 , in the form of LED or optical fiber, may be placed at the focal point of elliptical surface  202 . The illumination rays  220  reflected from elliptical surface may concentrate at foci of this surface while the rays  222  reflected from the tissue abutting the surface  202  may be directed toward the capture device  201 . This arrangement eliminates the direct optical reflection of illumination beams into the image capture device  201  or sensor  206  while maintaining its on-axis position. The offset between the optical axis O and the illumination axis IA may vary in range including between 1 to 2.5 mm. 
     Another embodiment of the device that includes an offset between the optical axis O and illumination axis IA is shown in  FIG. 31 . As shown in this embodiment, the tip optical axis SO of the tip  22  is offset from the optical axis O of the image capture device  201  to reduce or minimize the amount of reflection captured by the image capture device  201 . In this embodiment, the illumination may be provided by an annular ring of optical fiber around the lens of the image capture device  201 . The illumination beams reflected from the inner surface  204  will focus on the tip  22  center of curvature. Because the tip optical axis is offset in relation to the optical axis of the image capture device  201  its center of curvature is outside of the objective field of view and therefore reflected beams do not degrade the image quality. 
     As shown in  FIGS. 36-37 , the device  10  may also include a conduit  224  disposed at least partially within the main body  16  and the tip  22 . In the aspect shown in  FIG. 36 , the conduit  224  may be off-set from the longitudinal axis L of the main body  16 . However, in some aspects, the conduit  224  may be collinear with the longitudinal axis L of the main body  16 . The conduit  224  may extend from the proximal end  18  of the main body  16 , or may be formed along only a portion of the main body  16  and extend all the way through the distal portion  14  of the device, including the tip  22 . The conduit  224  may be used in the ultrasound or visualization embodiments of this device. The conduct  224  may also be placed in the along the longitudinal axis of the main body  16 , which may require the transducer  26  to be offset to accommodate the conduit  224 . 
     Stated differently, the location of the conduit  224  may vary and may be application dependent. For example, and without limitation, the conduit may be placed closer to the longitudinal axis L than shown in the embodiment disclosed in  FIG. 36 . In the alternative, the conduit may be placed on the exterior of main body  16  of the device to as to form a raised portion that extends along a direction that is substantially parallel to the longitudinal axis L of the main body  16 . In this embodiment, the conduit  224  would reside in the raised portion as shown in  FIG. 37 , which is a cross-sectional view of the distal end  20  of the main body  16  of this embodiment. 
     In addition, it is contemplated that there may be more than one conduit  224  for a particular device  10  thereby allowing an operator to simultaneously place multiple instruments into the patient&#39;s anatomy. The diameter of the conduit is application dependent by can vary and may be between 0.3 mm to 5.5 mm. 
     A conduit  224  as shown in  FIGS. 36-37 , may be configured to receive a number of instruments, including a guide wire to guide the device  10  through the anatomy of a patient, a k-wire to anchor the device  10  to a surgical site such as the disk space between two vertebra, an illumination device, such as an optical fiber, to provide additional illumination to a particular region of the patient&#39;s anatomy, an ultrasound probe to image or detect particular regions of a patient&#39;s anatomy, such as the one described above, a fiber optic cord that emits visible or infrared light to image or detect particular regions of a patient&#39;s anatomy, a nerve stimulator for neuromonitoring, and the like. 
     In some embodiments, as shown in  FIGS. 48 and 49 , the device  10  may be provided with a channel  4810  (hollow region) extending throughout the length of the main body  16  and the tip  22 .  FIG. 48  shows the device  10 , viewed from the distal end, to illustrate the tip  22  in these embodiments. As shown in  FIG. 48 , the tip  22  may form an annulus or ring. The inner space provided by the channel  4810  may provide a working channel inside the device  10  through which a surgeon may perform clinical procedures while allowing the device  10  to remain in place. This may allow for the collection and display of data for real-time feedback form the site of the surgery during the surgical procedure. In aspects of these embodiments, the main body  16  and the tip  22  may provide a channel  4810 , with a diameter in a range from 24 mm to 40 mm. The wall of the main body  16  and/or tip  22  may be 10 mm in width. Various other diameters and widths are contemplated herein; the values discussed above are examples to aid in understanding of the disclosure. For example, in some embodiments, the diameter of device  10  may be selected to allow a particular surgical implement to be fitted through the channel of device  10  so that imaging may continue as the implement is advanced into tissue. In various aspects, the channel  4810  may be off-set from the longitudinal axis of the main body  16 . However, in some aspects, the channel  4810  may be collinear with the longitudinal axis of the main body  16 . The channel  4810  may extend from the proximal end  18  of the main body  16  all the way through the distal portion  14  of the device  10 , including the tip  22 . 
     In these embodiments, multiple transducers  26 , such as transducer  4810  of  FIG. 48 , may be arranged on the distal end  20  of the device  10 , on the ring-shaped tip  22 . As discussed above, the transducers  26  may emit an ultrasonic frequency in a direction that is substantially parallel to the longitudinal axis of the device  10 . It is also contemplated that various transducers may emit an ultrasonic frequency in a direction that is not parallel to the longitudinal axis of the device  10 . It can be appreciated that the transducers  4820  may be orientated in any direction that is required for the particular application. The ultrasonic frequency may be between 1 and 10 MHz, depending on the application. The ultrasound imager  24  may collect information, such as acoustic property results, from the transducers and, using the classification algorithm, screen for target tissue, such as nerve tissue. Nerve tissue may be highlighted on a display. In some embodiments, a 2-D mapping or a 3-D visualization (e.g. volumetric image) of nerve tissue may be generated and displayed. 
     In some embodiments, as shown in  FIG. 49 , the device  10  may have a length of 120 mm to 150 mm, forming the shape of a tube  4910 . It is contemplated that the device  10  may have a variety of other lengths, depending on the application. Probe  4920  is an example of a surgical tool that may be passed through the channel  4930  for various surgical procedures. 
       FIG. 50  shows the distal face of the tube, in order to illustrate various embodiments. The transducers are contemplated to have various shapes, such as a square, a rectangle, such as the rectangular transducers  5010 , and circular, such as the circular transducers  5010 . In some embodiments, more than one row of transducers may be arranged on the distal face, as illustrated in image  5030 . Various quantities of transducers may be used, depending on the application. In some embodiments, 100 to 250 or more transducers may be position on the distal end of the tube. Transducer frequency may be in the range of 5 MHz to 20 MHz to cover the appropriate depth required for the application (for example, 0.1-5 cm in depth). Other transducer frequencies may be used in various embodiments. 
     The above embodiments may be further understood by referring to  FIGS. 51-54 .  FIG. 51  shows the views  5110  and  5120  of device  10  having the channel as described above. Image  5130  shows the device  10  placed on the surface of the psoas muscle. The placement of the device  10  on the surface of the psoas muscle may be a first step prior to entering the psoas muscle in order to allow the surgeon to visualize the location of nerves within the psoas muscle using the methods as described herein. The transducers may emit ultrasound signals around the distal end of the device  10  and the image processor/software may form an image with a depth of 5-7 cm, creating a 3-D “volumetric” image of the area in the psoas muscle overlying the vertebral body and disc space. Based on use of the classification algorithm, sensory and motor nerves, and their routing, may be highlighted on the display. 
       FIG. 52  shows the device  10  and a surgical probe  5210 . Image  5220  shows the device  10  placed into position on the surface of the psoas muscle. Image  5230  depicts the probe  5210  before it is placed into the channel of device  10 , which is in position on the psoas muscle.  FIG. 53  depicts the device  10 , placed against the psoas muscle  5140  and with the probe  5210  inserted (retracted) into the channel of device  10 . At this point, the device  10  is in position for performing the operations as described herein to map the nerve tissues in the psoas muscle.  FIG. 54  depicts the device  10 , placed against the psoas muscle  5140  and with the probe  5210  inserted into the channel of device  10  and into the psoas muscle. Image  5400  shows an example anatomical image with a viewing window  5410  as may be generated by use of the classification algorithm. The viewing window  5410  may depict a map of the nerve tissues in the psoas muscle proximate to the device  10 . 
     Various aspects of the present disclosure are contemplated for being used in connection with minimally invasive surgery (MIS). The device  10  may be used for a variety of MIS procedures, including but not limited to, a lateral retroperitoneal interbody fusion (LLIF) (e.g., XLIF, DLIF), Axial Lumbar Interbody Fusion (AxiaLif), Transforaminal Lumbar Interbody Fusion (TLIF), Posterior Lumbar Interbody Fusion (PLIF), Anterior Lumbar Interbody Fusion, Trans-thoracic lumbar interbody fusion, Retropleural Thoracic Fusion, Interbody Fusion utilizing Kambin&#39;s Triangle, and Cervical/Thoracic/Lumbar Laminectomies, Foraminotomies and Diskectomies. The device  10  may be used to confirm that the area is clear of other anatomical parts, such as blood vessels, abdominal/pelvic viscera, nerve roots, and spinal cord. As shown in  FIG. 19 , once at the surgical site  46 , the device  10  may be used to illuminate the surgical site  46 , to allow a surgeon to introduce instruments (e.g. K-wire) to the surgical site via a conduit formed within the main body  16  of the device  10  or allow a retractor system or dilator system to create direct visualization and a working portal of the surgical site without the device  10 . 
     As described above, there can be a number of applications for which this device  10  may be used, which require the similar steps to access the surgical site. The method of use described below is in connection with performing an LLIF, but it can be appreciated that the device  10  can be used in a similar fashion for performing other MIS procedures as mentioned above. 
     In operation, the ultrasound imager  24  is used to detect the patient&#39;s anatomy as described herein. A surgeon may rely on the image or audio queues generated by the ultrasound imager  24  to detect the presence (or absence) of a nerve thereby allowing the surgery to reposition (or continue advancing) the device  10  through the patient&#39;s anatomy towards the surgical site  46 . The ultrasound imager  24  may also be used to confirm the image captured by an image capture device (not shown) is accurate by confirming the presence or absence of a targeted anatomical feature (e.g. nerve). The image capture device may consist of a camera or the like disposed within the distal portion  14  of the device  10  so as to capture an image of the region distal to the device  10 . 
     The image capture system  200  may also be used in a similar fashion to visually detect the patient&#39;s anatomy. The image capture system  200  may be used to confirm what is detected by the ultrasound imager  24 , or may be used independently to detect certain portions of the patient&#39;s anatomy. 
     The classifier/algorithm is integral in accurate nerve detection. In an alternative embodiment of the present invention, the classifier algorithm may be employed as follows: 
     An ultrasound probe acquires ultrasound backscatter data via a sector scan or similar ultrasound acquisition mode. 
     A 2D B-mode image may be constructed from the acquired data. A 2D B-mode image may be constructed using known methods and techniques. In one embodiment, a 2-dimensional image may be built up by firing a beam vertically, waiting for the return echoes, maintaining the information and then firing a new line from a neighboring transducer along a tambourine line in a sequence of B-mode lines. In a linear array of ultrasound crystals, the electronic phased array may shoot parallel beams in sequence, creating a field that is as wide as the probe length (footprint). A curvilinear array may have a curved surface, creating a field in the depth that is wider than the footprint of the probe, making it possible to create a smaller footprint for easier access through small windows. This may result in a wider field in depth, but at the cost of reduced lateral resolution as the scan lines diverge. 
     The image may be thresholded such that image intensity values above the threshold may be given a value of ‘1’ and image intensity values less than the threshold may be given a value of ‘0’. This may result in a binary map of intensity values. 
     The binary image may then be filtered with a smoothing filter which may consist of a simple median filter or similar smoothing filter. It is contemplated that a variety of digital filters may be employed to process the binary image. 
     The numbers of pixels for contiguous regions in the binary image may be counted. 
     Contiguous regions in the binary image that have a pixel count above a minimum threshold and below a maximum threshold may be selected. This may correspond to areas of contiguous regions in the binary image. The thresholds may be selected so that a nerve in the image will be detected and selected with a high degree of accuracy. 
     If the selected contiguous regions are less than a specified distance from the probe (2 cm, for example), the contiguous region may be selected as a possible nerve. It should be understood that the measured distance may be within a range of distances, and that the specific distance of 2 cm is provided by way of example. 
     A shape factor may next be implemented by fitting an ellipse to outline the selected contiguous regions in the 2D binary image. The area of the contiguous region may be compared to the area of the ellipse outlining the contiguous region. If the ratio of the areas is below a certain threshold, the contiguous region may be classified as not a nerve. A variety of outlining techniques, aside from the fitting of an ellipse, may be used to compare the contiguous region. 
     If the contiguous region is classified as a nerve, the original image data corresponding to the contiguous region may next be processed for texture features. Specifically, for the selected contiguous region, the SNR, kurtosis and skewness may be calculated from the B-mode image data (it is understood that alternative data parameters may be measured at this time as well). Threshold values for each of these parameters may be established in order to detect the nerves in the image. If the combination of the SNR, skewness and kurtosis are below a threshold, the contiguous region will be classified as not a nerve. It is contemplated that additional data parameters may be measured from the original image data for nerve detection. 
     In an alternative embodiment, robust detection using double threshold and connected component tracking by hysteresis may be employed. Specifically, instead of using only one, it may be preferred to use two threshold values: a high threshold value and a low threshold value. For each pixel in the B-mode image, if its value is larger than the high threshold value, then it may be marked as a strong nerve pixel. If the pixel value is smaller than the high threshold value and larger than the low threshold value, then it may be marked as weak nerve pixel. If the pixel value is smaller than the low threshold value, then it may be discarded. The connected component algorithm may be applied to look at each weak nerve pixel, and if it is connected to a strong nerve pixel then the weak nerve pixel may be preserved. 
     In some embodiments, the shape of the identified connected components (blobs) of detected nerve pixels may then be analyzed. If the size and shape of a blob is significantly different from the profile of a nerve area (elongated or elliptical of width about 5 mm) then it may also discarded. The detected nerve region in a B-mode image should have, at most, a maximum dimension of 1 or 2 cm. It is understood that data may fall in ranges which may yield the detection of a nerve, and that specific numbers are only provided by way of example. 
     The distance from the detected nerve region to the ultrasound probe may be estimated and used in the display. 
     In an alternative embodiment of the present invention, it is contemplated that sophisticated training and detection algorithms for nerve region like support vector machine (SVM) or random forest may be utilized for improved nerve detection. In machine learning, support vector machines (also support vector networks) may be supervised learning models with associated learning algorithms that analyze data and recognize patterns, used for classification and regression analysis. Given a set of training examples, each marked as belonging to one of two categories, an SVM training algorithm may build a model that assigns new examples into one category or the other, making it a non-probabilistic binary linear classifier. An SVM model is a representation of the examples as points in space, mapped so that the examples of the separate categories are divided by a clear gap that is as wide as possible. New examples may then be mapped into that same space and predicted to belong to a category based on which side of the gap they fall on. In addition to performing linear classification, SVMs can efficiently perform a non-linear classification using what is called the kernel trick, implicitly mapping their inputs into high-dimensional feature spaces. Random forests are an ensemble learning method for classification, regression and other tasks, that operate by constructing a multitude of decision trees at training time and outputting the class that is the mode of the classes (classification) or mean prediction (regression) of the individual trees. Random forests correct for decision trees&#39; habit of overfitting to their training set. Decision trees are a popular method for various machine learning tasks. Tree learning comes closest to meeting the requirements for serving as an off-the-shelf procedure for data mining because it is invariant under scaling and various other transformations of feature values, is robust to inclusion of irrelevant features, and produces inspectable models. However, they are seldom accurate. In particular, trees that are grown very deep tend to learn highly irregular patterns: they over fit their training sets, because they have low bias, but very high variance. Random forests are a way of averaging multiple deep decision trees, trained on different parts of the same training set, with the goal of reducing the variance. This comes at the expense of a small increase in the bias and some loss of interpretability, but generally greatly boosts the performance of the final model. 
     Once the muscles are split and the surgical site  46  is reached, the surgeon can place a k-wire through the conduit to confirm that the surgical site  46  is reached and anchor the device  10  with respect to the surgical site  46 . A retractor tool  48  may be put into place to give the surgeon a direct surgical working conduit to the surgical site  46 . Alternatively, a series of dilators may be sequentially placed over the main body  16  to create the working space. Once this direct access to the spine is achieved, the surgeon is able to perform a standard discectomy (removing the intervertebral disc), corpectomy (removing the vertebral bone) or fusion (uniting two bones together) with surgical tools. 
     An embodiment of the retractor system  48  may include a first blade  49  and a second blade  51 , both of which may be semi-circular in shape that form an opening that fits snugly around the outer diameter the main body  16 . It is appreciated that the cross-sectional shape of the blades can mimic the shape of the main body  16  (e.g., triangular, oval, square, rectangular, etc.). Once at the surgical site, the retractor blades  49 ,  51  may be configured to separate relative to one another so as to expand the dissection and to enable the device  10  to be removed and allow for direct visualization of the surgical site  46  as shown in  FIG. 19 . It is contemplated that the distal ends  53  of the first  49  and second  51  blades are adjacent to the distal portion  14  of the main body  16 . Any known type retractor system may be used with the device  10 . 
     In one embodiment, a retractor system  226 , like the one disclosed in  FIG. 38 , may be disposed over the device  10  and configured to expand to create a working space within the anatomy of the patient once a surgical site, or other location where a surgical procedure is to take place, is reached. This embodiment of the retractor system  226  includes a first blade  228  and a second blade  230 , both of which are semi-circular in shape that form an opening that fits snugly around the outer diameter the main body  16 . Once at the surgical site, the retractor blades  228 ,  230  are configured to separate relative to one another to expand the dissection so as to enable the device  10  to be removed and allow for direct visualization of the surgical site  68  as shown in  FIG. 38 . The distal ends  232  of the first  228  and second  230  blades may be adjacent to the distal portion  14  of the main body  16 . Any type known retractor system may be used with the device  10 . It can be appreciated that stimulation electrodes, visualization cameras and illumination devices (optical, ultrasound, infrared and ultraviolet) may also be placed along or within the retractor blades  228 ,  230  so as to allow for nerve detection as discussed above    
     As shown in  FIG. 39 , a cross-sectional view of the   retractor  226  disposed around the device  10 , the main body  16  of the device  10  may have a raised channel or channels  234  disposed along its length in a direction along the its longitudinal axis that is configured to slidingly receive a complimentary groove  236  formed by the first and second blades  228 ,  230  of the retractor system  226 . In some aspects, the raised channel  234  and/or groove  236  may have a square, rectangle, semi-spherical or a similar cross-sectional shape. Further, the number and location of the channel  234  and groove  236  may vary. For example, but without limitation, the may only be one channel/groove running along the main body  16 . 
     Alternatively, there may be more than two channels/grooves that are equidistantly placed about the outer surface of the main body  16 . The channel and groove may also be transposed, such that the grove  236  is on the main body  16  and the raised channel  234  is formed along the blades  228 ,  230 , as shown in  FIG. 40 , such that the groove  236  prevents the blades  228 ,  230  from expanding when the retractor  226  is disposed over the device  10 . The channel  234  and groove  236  may extend along only a portion of the main body  16  of the device  10  and the blades  228 ,  230 . 
     The retractor system  226  may consistent of multiple sets of blades  228 ,  230  with varying thickness and diameter. For example, and without limitation, the blades  228 ,  230  may vary in size so as to have an overall outer diameter ranging from 2 mm to 80 mm when in the closed (e.g., collapsed) configuration. Further, the blades  228 ,  230  may be configured such that they create a 2 mm to 220 mm opening within the patient&#39;s body when in the expanded configuration. The device  10  and retractor system  226  may be configured such that a first set of blades  228 ,  230  having a larger retracted diameter may be used to create a first opening within the patient&#39;s body and then a second set smaller diameter blades having a retracted diameter that is different than the first set of blades  228 ,  230  may be slidingly disposed over the main body  16  and within the first opening and retracted to open a second opening within the patient&#39;s body at a location distal to the first opening. The openings created by the first and second set of blades may have different opening diameters. The retractor system  226  may allow the operator to create multiple openings having different retracted diameters at different anatomic levels within the patient. A light source (not shown) may be disposed at the distal ends, or along the length, of the blades  228 ,  230  to illuminate the opening within the patient&#39;s body and illuminate the region of the patient&#39;s anatomy within and distal to the opening created by the blades  228 ,  230  In addition, a conduit (not shown) may also be formed within the blades so as to receive one or more of: a medical instrument, such as a k-wire to anchor the blades  228 ,  230  to a surgical site such as the disk space between two vertebra; an illumination device, such as an optical fiber, to provide additional illumination to a particular region of the patient&#39;s anatomy; an electrical conduit to provide neural stimulation; a ultrasound probe to image or detect particular regions of a patient&#39;s anatomy; a image capture device; a fiber optic cord that emits visible or infrared light to image or detect particular regions of a patient&#39;s anatomy; and the like. The blades  228 ,  230  may be made out of any preferable surgical grade material, including but not limited to, medical grade polymer including PEEK (polyether ether ketone), and may be transparent (e.g. made out of clear plastic) or translucent. 
     In another embodiment, the retractor system  226  may be integrated with the device  10  such that it forms part of the main body  16  and can be deployed once at the surgical side. The retractor system  226  in this embodiment may expand radially away from the longitudinal axis of the main body  16  to expand the path created by the main body  16 . The main body  16  may then be withdrawn from the surgical site so as to create a working portal within the retractor system  226 . 
     A series of dilating cannulas (e.g. dilators  100 ), as shown in  FIG. 20 , may also be slidingly placed around the main body  16  of the device  10  so as to expand the diameter of the dissection made by the distal portion  14  of the device  10 . The technique of employing a series of dilating cannulas to create a working space for direct visualization used in other medical procedures to create a working space may also be used in conjunction with the device  10 . 
     After disc material is removed, the surgeon may be able to insert an implant/spacer through the same incision from the side. This spacer (cage) may help hold the vertebrae in the proper position to make sure that the disc height (space between adjacent vertebral bodies) is correct and to make sure the spine is properly aligned. This spacer, together with a bone graft, may be designed to set up an optimal environment to allow the spine to fuse at that particular segment. The surgeon may use fluoroscopy to make sure that the spacer is in the right position. The surgeon may then remove the refractor and suture any incisions. 
     Spinal surgeons oftentimes access the intervertebral disc space and vertebral body via a transpsoas approach. The transpsoas muscle however has a network of nerves (lumber plexus) within the muscle and their exact location can be unpredictable The surgeon must therefore get to the disc while avoiding these nerves so as not to cause nerve damage or paralysis when performing surgery The present disclosure allows the surgeon to visualize where nerves lie before penetrating the psoas muscle. The device  10  and the classification algorithms may be used to create a quantitative image and/or map (2D or 3D) of the nerve tissue while the device  10  is placed above the psoas, providing a surgeon a path that avoids nerves and gets to the disc space. In some embodiments, a mapping of target tissue proximate to the surgical site may be provided by the ultrasound imager  24 . When the tip  22  is disposed adjacent to the psoas muscle, the surgeon may slide a first set of blades of the retractor system over the device and expand the retractor system  48  to create a first working space (also referred to as a superficial dock). This working space may allow the surgeon to visually inspect the psoas muscle and the surrounding region either via naked (eye) inspection or with the optical camera/dissector (e.g., one or more components of device  10 ). Next, the surgeon may continue the procedure by using the device, which is now disposed within the first working space to dissect through the psoas muscle as described herein. Once the tip  22  has reached the surgical site, which is the disc space here, a second set of retractor blades which are smaller than the first set of blades may be slid over the device  10  and expanded to create a second working space that is smaller in diameter than the first working space. The surgeon may then continue with the procedure in the manner discussed herein. One benefit of establishing the first working space may be that it allows the surgeon to remove the device  10  from the surgical site once the procedure is completed at the first surgical site and reposition and reinsert the distal tip  22  of the device  10  within the first working space that is formed above the psoas muscle at a second location to allow the surgeon to penetrate the psoas muscle to reach a second surgical site to conduct and complete another procedure or a multi-level procedure in which psoas dissection is currently dangerous because of the interposed neurovascular structures (L3-4 and L4-5 disc space or a lumbar corpectomy—removal of two discs and the intervening bone). It is appreciated that the tip  22  is optional and the distal end  21  of the device  10  maybe the portion of the device that is advanced towards the surgical site. 
     In some embodiments employing the device  10  having the channel  4930 , when the tip  22  is disposed adjacent to the psoas muscle, the surgeon may position surgical tools/implants through the channel  4930  to access the surgical site while allowing the transducer(s) to collect data for real-time display. By allowing the surgeon to perform surgery while the device  10  is in place, the transducer can record and collect data throughout the surgery. The device  10  may also serve as a retractor of tissue, thereby pushing surrounding tissue to the side and assisting with creating the working portal for the surgeon. Once the tip  22  has reached the surgical site, the surgeon may continue the use of tools through the channel  4930  or may employ a second set of tools, such as retractor blades, over the device  10 . The surgeon may then continue with the procedure in the manner discussed herein. 
     The device  10  may also be used for performing an axial lumbar interbody fusion (AxiaLIF). At surgery, the patient may be positioned prone with maintenance of lordosis and the legs spread. A catheter may be inserted into the rectum will allow air to be injected during the procedure for visualization of the rectum. After the surgeon makes a small incision (15-18 mm) lateral to the tip of the coccyx, the distal tip  22  of the device  10  may be inserted through the incision and is passed into the pre-sacral space. The surgeon may use the distal portion  14  of the device  10  to sweep and scan the pre-sacral space to confirm that the space is clear of any offending anatomy (e.g. colon, rectum). The device  10  may be gently passed along the anterior cortex of the sacrum and in the midline to an entry point usually close to the S1-2 junction. Once the trajectory is chosen, a sharp beveled pin may then be driven into the L5-S1 interspace, either through the conduit  36  or after the retractor system  48  is deployed. The retractor system,  48  or a series of dilators may be used to create approximately a 10 mm opening into the sacrum through which a 10 mm channel is drilled into the L5-S1 disc. The device  10  may then be withdrawn from the pre-sacral space and the surgeon may then perform the remaining steps of the AxiaLIF procedure. 
     The device  10  may also be used to allow direct access to Kambin&#39;s triangle (ExtraForaminal Lumbar Interbody Fusion). For this procedure, patients may be placed in a prone position, typically onto a Jackson Table using a radiolucent frame that allows for restoration of lumbar lordosis. Fluoroscopic imaging may be utilized to identify the epiphyseal plate of the upper and lower vertebral body by controlling the cranial-caudal angle of the image intensifier. Additionally, the fluoroscopic image may be rotated by 20-35 degrees toward the region, so that the superior articular process may be seen at the middle of the intervertebral disc. At this location, the tip  22  of the device  10  may be inserted percutaneously targeting the area commonly referred to as Kambin&#39;s triangle. Kambin&#39;s triangle is defined as the area over the dorsolateral disc. The hypotenuse is the exiting nerve root, the base (width) is the superior border of the caudal vertebra and the height is the dura/traversing nerve root.  FIG. 55  depicts a visual representation of Kambin&#39;s triangle  5500 .  FIG. 56  shows the device  10  in a position targeting Kambin&#39;s triangle, as described above. 
     The device  10  may also be used to ultrasonically identify various anatomical features such as the exiting root, radicular artery, thecal sac and the disc space. A k-wire can then be place into the disc space via the conduit  36  under ultrasonic detection via the device  10  allowing for docking of the dissector/retractor system  48 . Subsequent dilation can then be performed allowing for access in the intervertebral foramen while directly visualizing neurovascular structures using the device and avoiding these structures when identified by the surgeon. 
     The device  10  may also be used in treatment of extraforaminal disc herniations, such as in procedures involving extraforaminal intervertebral fusion. A far lateral discectomy is a commonly performed procedure for the treatment of extraforaminal disc herniations. It is routinely done through a paramedian incision using the Wiltse plane. However, the exiting nerve root (i.e. the L04 nerve root at the L45 level, see  FIG. 48 ) is at risk of damage with this approach, as it is normally draped over the disc. In order to decrease the risk of nerve injury, some surgeons currently use intraoperative nerve monitoring; however, intraoperative nerve monitoring relies on advanced anesthetic that may not allow for relaxation of the patient. Recently, surgeons have considered use of interbody cage in intervertebral fusion approaches through the far lateral extraforaminal approach. While there are advantages to a muscle and bone sparing approach to intervertebral fusion, the passage of an interbody cage device into the disc space increases the risk to the exiting nerve as well as the nerves that have exited from proximal levels and are running under the intertransverse membrane. In order to safely perform an extraforaminal intervertebral fusion, we disclose herein use of the device  10  for performing detection of the neurologic structures that run under the intertransverse membrane as well as the exiting nerve root as it is leaving its foramen. Once the nerve is detected, the device  10  can be safely docked on the far lateral portion of the disc, just anterior to the pars interarticularis. Dilators may then be advanced over the main body  16  of the device  10  and then a tubular retractor may be docked on the disc, just anterior to the pars interarticularis and in between the transverse processes of the two involved vertebrae. Once the retractor is safely docked, the surgeon may proceed with preparation of the disc space and endplates and safely insert the intervertebral cage for fusion. 
       FIG. 57  depicts a skin incision made approximate 5-6 cm lateral to the midline, according to the methods disclosed herein. The incision may be centered lateral to the facet-pedicle junction.  FIG. 58  shows the natural cleavage plane, between the multifidus part of the sacrospinalis and the longissimus part, as may be used for spinal approach in some embodiments. This plane allows direct access to the pars, transverse processes and facet joints with minimal soft tissue dissection and retraction. This approach is less vascular than the mid-line approach, and therefore may result in less bleeding. 
     In another embodiment, shown in  FIG. 21 , an ultrasound imager  24  may be used in conjunction with a glove  110 . In this embodiment, the operator may rely on tactile feedback provided by touch while still enabling ultrasonic imagining/scanning of a patient&#39;s anatomy. More specifically, the glove system (or device) may allow for tactile feedback that facilitates the dissection and separation of tissue namely neurological, vascular and peritoneal structures. In general, tactile feedback allows for dissection of tissue in normal surgical procedures without the unique perspective of direct visualization that may not be permissible in some minimally invasive/percutaneous techniques. 
     The ultrasound imager  24  may include a transducer  26  that is configured to emit sound waves may be disposed at the distal end of the glove  110 . In one embodiment, the transducer  26  is located along a distal portion  114  of the index finger  112  of the glove  110 . As better shown in  FIG. 22 , a   tip  22  forms part of, or is connected to, the distal portion  114  of the index finger  112  such that the outer surface  24  of the tip  22  does not extend beyond the very most distal part of the index finger  112 . Of course, it is appreciated that the tip  22  may extend beyond the distal portion depending on the embodiment. 
     Connected to the transducer  26  may be a flexible conduit  116  that may carry a cable that connects the transducer  26  to a housing that contains the remaining portion of the ultrasound imager  24 . The flexible conduit  116  may run along the length of the index finger  112  and a top portion  118  of the glove  110 . However, it can be appreciated that the conduit  116  can run along any length or surface of the glove  110  and is application dependent. The flexible conduit  116  may also provide a channel to carry a k-wire or other instrument that can be slidingly disposed within the flexible conduit  116  (as will be further discussed below). The flexible conduit  116  may run through and may be in communication with a unit  109  such that a portion of the flexible conduct  116  provides an opening  120 , as shown in  FIG. 23 , in the unit  109  at the distal portion  114  of the index finger  112 . 
     The unit  109  may have a bottom portion  122 , as shown in  FIG. 23 . The bottom portion  122  may have a concave curvature so as to provide a complimentary fit once an operator&#39;s hand is placed within the glove  110 . In addition, a proximal portion of the unit  109  may have a taper so as to cause minimal disruption to a patient&#39;s anatomy as the unit  109  is articulated during a procedure. Further, the unit  109  may have an overall semi-circular or cylindrical shape or the like so as to minimize any inadvertent disruption to the patient&#39;s anatomy during a procedure and to maintain a small overall profile as shown in  FIGS. 24 and 25 . For example, the height of the unit  109  may be less than the overall width to as to achieve a low profile. Alternatively, the outer portion of the unit  109  may not extend beyond and become collinear with the width of the index finger  112  to maintain a low profile. The external outer diameter of the unit  109  may range from 0.5 to 20 mm and outside of this range depending on the desired application. The length of the unit  109  can range from 0.5 to 10 mm but also may fall outside of this range depending on the application. It is appreciated that more than one transducer  26  may be positioned along the distal portion of a finger such that they provide side facing scans to generate a multi-directional (e.g. 180°-300°) scan of the patient&#39;s anatomy. 
     Transducers  26  may be side positioned (e.g. on either side of the index finger  112 ) so as to provide for multi-directional scanning of the patient&#39;s anatomy to detect the nerve or target anatomy. The side positioned transducers may be configured to scan the anatomy around in a circumferential direction around the index finger  112  to detect the nerve (or other target anatomy) not detected by the transducer positioned at the distal end of the main body  16 . The multi-directional scanning may enable the system to generate a scan image of the patient&#39;s anatomy in multiple directions as the index finger  112  of the glove  110  is advanced through the patient&#39;s anatomy. As discussed above, the system that is in communication with the transducers may then detect the nerve even that is not captured by the forward scanning transducer. 
     The image capture system  200 , as discussed in relation to  FIGS. 29 and 30 , may be used with the glove embodiment where the image capture device  201 , its tip  22 , sensor  206 , and illumination device  216  may be placed on a distal portion  114  of the index finger  112  of the glove  110 . The image capture system  200  may also be used independently of, or in conjunction with, the ultrasound imager  24  as described above in the glove embodiments. 
     The glove embodiment can be used in connection with minimally invasive surgery (MIS). The glove  110  may be used for a variety of MIS procedures, including but not limited to, Lateral Retroperitoneal Interbody Fusion (LLIF (e.g., eXtreme Lateral Lumbar Interbody Fusion (XLIF), Direct Lateral Interbody Fusion (DLIF)), Axial Lumbar Interbody Fusion (AxiaLif), Transforaminal Lumbar Interbody Fusion (TLIF), Posterior Lumbar Interbody Fusion (PLIF), Anterior Lumbar Interbody Fusion, Trans-thoracic lumbar interbody fusion, Retropleural Thoracic Fusion, Interbody Fusion utilizing Kambin&#39;s Triangle, and Cervical/Thoracic/Lumbar Laminectomies, Foraminotomies and Diskectomies. The glove  110  may be used to confirm that the area is clear of other anatomical parts, such as blood vessels, abdominal/pelvic viscera, nerve roots, and spinal cord.    
     As described above, there can be a number of applications for which this glove  110  may be used, which may require similar steps to access the surgical site. The surgeon may rely on the image or audio queues generated by the ultrasound imager  24  to detect the presence (or absence) of a nerve thereby allowing the surgery to reposition (or continue advancing) the glove  110  through the patient&#39;s anatomy towards the surgical site  48 . 
     Once the muscles are split and the surgical site  48  is reached, the surgeon can place a k-wire through the conduit to confirm that the surgical site  48  is reached and anchor the glove  110  with respect to the surgical site  48 . A retractor tool is put into place to give the surgeon a direct surgical working conduit to the surgical site  48 . Alternatively, a series of dilators may be sequentially placed over the k-wire to create the working space. Once this direct access to the spine is achieved, the surgeon is able to perform a standard discectomy (removing the intervertebral disc), corpectomy (removing the vertebral bone) or fusion (uniting two bones together) with surgical tools. 
     In the case of a discectomy, after the disc material is removed, the surgeon may be able to insert an implant/spacer through the same incision from the side. This spacer (cage) will help hold the vertebrae in the proper position to make sure that the disc height (space between adjacent vertebral bodies) is correct and to make sure the spine is properly aligned. This spacer, together with a bone graft, may be designed to set up an optimal environment to allow the spine to fuse at that particular segment. The surgeon may use fluoroscopy to make sure that the spacer is in the right position. The surgeon may then remove the refractor and suture the incisions. 
     The glove system may also be used for performing an axial lumbar interbody fusion (AxiaLIF). At surgery, the patient may be positioned prone with maintenance of lordosis and the legs spread. A catheter may be inserted into the rectum will allow air to be injected during the procedure for visualization of the rectum. After the surgeon makes a small incision (15-18 mm) lateral to the tip of the coccyx, the distal portion of the index finger  112  and distal tip  22  is inserted through the incision and is passed into the pre-sacral space. The surgeon may use the index finger  112  to sweep and inspect the pre-sacral space to confirm that the space is clear of any offending anatomy (e.g. colon, rectum) visually and by way of ultrasonic imaging. The index finger  112  may be advanced along the anterior cortex of the sacrum and in the midline to an entry point usually close to the S1-2 junction. Once the trajectory is chosen, a sharp beveled pin may then be driven into the L5-S1 interspace, either through a conduit or after the retractor system is deployed. The retractor system or a series of dilators may be used to create approximately a 10 mm opening into the sacrum through which a 10 mm channel is drilled into the L5-S1 disc. The index finger  112  may then be withdrawn from the pre-sacral space and the surgeon may then perform the remaining steps of the AxiaLIF procedure. 
     The glove system may also be used to allow direct access to Kambin&#39;s triangle (Extraforminal interbody fusion). For this procedure, patients may be placed in the prone position typically onto a Jackson Table using a radiolucent frame that allows for restoration of lumbar lordosis. Fluoroscopic imaging may be utilized to identify the epiphyseal plate of the upper and lower vertebral body by controlling the cranial-caudal angle of the image intensifier. Additionally, the fluoroscopic image may be rotated by 20-35 degrees toward the region, so that the superior articular process can be seen at the middle of the intervertebral disc. At this location, the index finger  112  can be inserted percutaneously targeting the area commonly referred to as Kambin&#39;s triangle. As discussed above, Kambin&#39;s triangle is defined as the area over the dorsolateral disc. The hypotenuse is the exiting nerve root, the base (width) is the superior border of the caudal vertebra and the height is the dura/traversing nerve root.    
     The glove system may be used to identify various anatomical features such as the exiting root, radicular artery, thecal sac and the disc space. A k-wire can then be place into the disc space via the conduit under ultrasonic visualization allowing for docking of the dissector/retractor system. Subsequent dilation can then be performed allowing for access in the intervertebral foramen while directly visualizing neurovascular structures using the device and avoiding these structures when identified by the surgeon. 
     The device  10  may also include infrared technology, which includes an infrared emitting light source and an infrared image capture device. The device  10  may include one or more infrared radiation detecting elements mounted at the distal portion  14  of the device  10 . The infrared array may be sensitive at e.g. wavelengths from 2 to 14 micrometers. One embodiment of the infrared aspect of the present disclosure uses a two-dimensional array of microbolometer sensor elements packaged in an integrated vacuum package and co-located with readout electronics on the distal tip of the device  10 . It is appreciated that the infrared aspect of this disclosure may be used in conjunction with, or separate from, the other embodiments discussed herein. One such infrared system that could be used with the present disclosure is disclosed in U.S. Pat.   No. 6,652,452, the entirety of which is incorporated herein by reference. 
     The device  10  may also utilize Optical Coherence Tomography (hereinafter “OCT”) technology as a stand-alone detection system or in conjunction with the other embodiments disclosed herein. OCT is an optical signal acquisition and processing method that generates images using near infrared light. By way of background, OCT performs high-resolution, cross-sectional tomographic imaging of the internal microstructure in materials and biologic systems by measuring backscattered or back-reflected light. OCT images are typically two- or three-dimensional data sets that represent the optical back-scattering in a cross-sectional plane through the tissue. Image resolutions of approximately 1 to 15 micrometers may be achieved, one to two orders of magnitude higher than conventional ultrasound. Imaging can be performed in situ and in real time. 
     OCT forms depth resolved images by interferometrically detecting the light backscattered from different scatterers within the sample. In a typical OCT system  50 , as shown in  FIG. 26 , the light from the laser  52  is split by a fiber optic coupler/beam splitter  54  into two arms i.e. the reference arm  56  and the sample arm  58 . The light coupled into the reference arm  56  is reflected back from a fixed mirror  60 , while in the sample arm  58  the light is projected through an OCT probe  62 , which will be discussed in greater detail below.    
     The OCT probe  62  may be focused onto the sample of interest (e.g. tissue or the anatomy of the patient) through a focusing lens (e.g. a GRIN lens). OCT is a point by point imaging technique where the sample is illuminated by focusing the light from the laser  52  onto a small point (spot size determined by the focusing lens) on the sample. Light in the sample arm  58  travels within the tissue and is backscattered by different scatterers within the tissue and combines with the light from the reference arm  56 . If the optical path lengths of the reference  56  and sample  58  arms are matched, an interferogram may be formed which may be measured by a photo detector or a spectrometer. The frequency content of the interferogram may contain information about the depth and strength of the scatterers that the beam had encountered in the sample. The resulting interferogram may be processed to form one-dimensional depth information generally known as an A-scan (a single A-scan would be a single column in the image). The optical beam may then be scanned over the sample to generate two- or three-dimensional images. The beam may be scanned using galvanometers in bench-top OCT systems or using MEMS scanners in hand-held OCT devices. This data is sent to, and processed by, the computer  95  or other processor. 
     As further disclosed in  FIG. 27 , the OCT probe  62  may include a GRINS lens  64 , the diameter of which in this embodiment is 1 mm, but which can vary depending on the intended application. A single mode optical fiber  66  is included in this embodiment that transfers the light rays between the OCT   probe  62  and the remaining portion of the OCT system (e.g. the fiber optic coupler  54  or a detector  68 ). The single mode optical fiber  66  may have a thickness of approximately 900 micrometers and a length of approximately 1.5 m. These specifications, of course, are examples only and can vary depending on the application. Attached to the distal end of the GRINS lens  64  may be a prism  70  for deflecting the light depending on the location and orientation of the target. It can be appreciated that the prism  70  may not be necessary in situations where the surface of the target is directly in front of or substantially perpendicular to the longitudinal axis of the light ray (or beam). In this embodiment, the length of the prism is approximately 700 micrometers, but it is appreciated that the length can vary and is application dependent    
     Two different embodiments of the OCT probe  62  are illustrated in  FIG. 28 . The first embodiment is the forward image probe  72 , which does not include a prism, such that the light ray (or beam) extends outward towards the front of the probe  72  to reach the target (e.g. tissue). In the second embodiment, image probe  74  contains a prism  70 , which allows this embodiment to image targets that are disposed below or at an angle to the tip of the probe  74 . The OCT technology may also be incorporated in to the glove  110  in a manner as discussed above with respect to the ultrasound embodiment. 
     Some of the parameters that may be manipulated to optimize OCT imaging include (a) the A-scan rate (the number of A-scans the system can acquire in a second), (b) the axial and transverse resolution, and (c) the imaging depth. The A-line scan rate may determine how fast an OCT system can operate. For a swept source OCT system, the imaging rate may depend on the wavelength sweeping rate of the laser, while, for a spectral domain OCT system, it is generally limited by the speed of the line scan camera used in the spectrometer. The tradeoff is that at a higher A-scan rate, the exposure time has to be reduced which can decrease the SNR of the acquired data. The axial resolution (resolution across the depth) is determined by the bandwidth and wavelength of the laser source. In general, the higher the bandwidth the better is the axial resolution. The resolution along the transverse dimensions is determined by the numerical aperture of the lens in the sample arm  58 . The higher the numerical aperture, higher the transverse resolution, however, the tradeoff is a reduced depth-of-field. Moreover, with an increase in the center wavelength of the source both the axial and transverse resolutions degrade. Finally, the imaging depth is usually limited by how deeply the light can penetrate through the tissue or sample of interest. Higher wavelengths offer greater imaging depth. These and other parameters may be optimized to detect certain features of a patient&#39;s anatomy, such as nerve root. 
     The OCT probe  62  may be positioned at the distal portion  14  of the device  10 . Alternatively, the OCT probe  62  may be positioned at the distal end of a k-wire like structure and disposed through the conduit  36 . In either embodiment, the OCT probe  62  may be configured to image a portion of the patient&#39;s anatomy that is adjacent to (or in front of) the distal portion  14  of the device  10 . The surgeon may insert the OCT probe  62  to image the patient&#39;s anatomy as needed to reach the surgical site. The OCT system  50  may be configured to visually and/or audibly indicate detection of select pre-selected portions of a patient&#39;s anatomy (e.g. nerve root). As mentioned above, it can be appreciated that the OCT system can be used independently or in combination with other detection technologies described herein. 
     It is also contemplated that the device  10  can be used in conjunction with a neuromonitoring system to detect certain portions of a patient&#39;s anatomy, including neural elements that include a nerve, nerve bundle, or nerve root. For the purposes of this discussion, the device  10  and neuromonitoring system will be discussed with respect to detecting a patient&#39;s spinal nerve but it is contemplated that the device  10  and neuromonitoring system may be used to detect other nerves (peripheral and central) as well as the spinal cord. One type of neuromonitoring system that may be used in conjunction with the device  10  is disclosed in U.S. Pat. No. 7,920,922, the entirety of which is incorporated by reference herein. 
     In one embodiment, stimulation electrodes may be placed at the distal end of the device  10 , such as forming part of the tip  22 , or placed at a distal end of an instrument, such as a K-wire, disposed through the conduit  36 , to stimulate any nerves in the region adjacent to the distal portion  14  of the device  10 . EMG (electromyography) electrodes can be placed on the skin to detect any nerve depolarization in the manner descried in U.S. Pat. No. 7,920,922. One manner in which the proximity, location, direction, physiology of the nerve is determined is also disclosed in U.S. Pat. No. 7,920,922. It is appreciated that other techniques of detecting nerves using stimulation are known in the art and any of those techniques may be used in conjunction, or integrated, with the device  10  in the manner described above. 
     The ultrasound imager  24  may be used in conjunction or independent of an image capture device to visualize the patient&#39;s anatomy as described herein. Steps and methods describe herein using the ultrasound imager  24  to detect certain features of a patient&#39;s anatomy may be supplemented through use of an image capture device. Specifically, the surgeon may rely on the image or audio queues generated by the ultrasound imager  24  to detect the presence (or absence) of a nerve thereby allowing the surgery to reposition (or continue advancing) the device  10  through the patient&#39;s anatomy towards the surgical site  48 . The ultrasound imager  24  may also be used to confirm the image captured by the image capture device is accurate by confirming the presence or absence of a targeted anatomical feature (e.g. nerve).   
     Likewise, in operation, the OCT system  50  may be used in conjunction or independent of an image capture device and/or the ultrasound imager  24  to scan and identify the patient&#39;s anatomy as described herein and to access the surgical site. Steps and methods used to access the surgical site and avoid target anatomy (e.g. nerve) employing the ultrasound imager  24  may also be performed using the OCT system  50 . Furthermore, steps described herein using ultrasound imager  24  may be supplemented through use of the OCT system  50 . For example, the surgeon may rely on the image or audio cues generated by the OCT system  50  to detect the presence (or absence) of a nerve thereby allowing the surgery to reposition (or continue advancing) the device  10  through the patient&#39;s anatomy towards the surgical site  48 . The OCT system  50  may also be used to confirm the image captured by an image capture device is accurate by confirming the presence or absence of a targeted anatomical feature (e.g. nerve). 
     The device  10  may be used in a variety of other medical areas outside of spinal surgery. These include: gynecologic transvaginal imaging for cervical cancer and endometrial cancer, prostate examination/prostate cancer, intra-abdominal surgery to delineate depth of penetration of a tumor within peritoneal contents (stomach, small intestine, large intestine, kidney, liver, and spleen). The device  10  may be utilized with known robotic systems, such as the Da Vinci Robotic or similar systems. 
       FIG. 47  depicts an illustrative operating environment in which various aspects of the present disclosure may be implemented in accordance with one or more example embodiments. Referring to  FIG. 47 , computing system environment  4700  may be used according to one or more illustrative embodiments. Computing system environment  4700  is only one example of a suitable computing environment and is not intended to suggest any limitation as to the scope of use or functionality contained in the disclosure. Computing system environment  4700  should not be interpreted as having any dependency or requirement relating to any one or combination of components shown in illustrative computing system environment  4700 . 
     Computing system environment  4700  may include computing device  4701  having processor  4703  for controlling overall operation of computing device  4701  and its associated components, including random-access memory (RAM)  4705 , read-only memory (ROM)  4707 , communications module  4709 , and memory  4715 . Computing device  4701  may include a variety of computer readable media. Computer readable media may be any available media that may be accessed by computing device  4701 , may be non-transitory, and may include volatile and nonvolatile, removable and non-removable media implemented in any method or technology for storage of information such as computer-readable instructions, object code, data structures, program modules, or other data. Examples of computer readable media may include random access memory (RAM), read only memory (ROM), electronically erasable programmable read only memory (EEPROM), flash memory or other memory technology, compact disk read-only memory (CD-ROM), digital versatile disks (DVD) or other optical disk storage, magnetic cassettes, magnetic tape, magnetic disk storage or other magnetic storage devices, or any other medium that can be used to store the desired information and that can be accessed by computing device  4701 . 
     Although not required, various aspects described herein may be embodied as a method, a data processing system, or as a computer-readable medium storing computer-executable instructions. For example, a computer-readable medium storing instructions to cause a processor to perform steps of a method in accordance with aspects of the disclosed embodiments is contemplated. For example, aspects of the method steps disclosed herein may be executed on a processor on computing device  4701 . Such a processor may execute computer-executable instructions stored on a computer-readable medium. 
     Software may be stored within memory  4715  and/or storage to provide instructions to processor  4703  for enabling computing device  4701  to perform various functions. For example, memory  4715  may store software used by computing device  4701 , such as operating system  4717 , application programs  4719 , and associated database  4721 . Also, some or all of the computer executable instructions for computing device  4701  may be embodied in hardware or firmware. Although not shown, RAM  4705  may include one or more applications representing the application data stored in RAM  4705  while computing device  4701  is on and corresponding software applications (e.g., software tasks) are running on computing device  4701 . 
     Communications module  4709  may include a microphone, keypad, touch screen, and/or stylus through which a user of computing device  4701  may provide input, and may also include one or more of a speaker for providing audio output and a video display device for providing textual, audiovisual and/or graphical output. Computing system environment  4700  may also include optical scanners (not shown). Illustrative usages include scanning and converting paper documents, e.g., correspondence, receipts, and the like, to digital files. 
     Computing device  4701  may operate in a networked environment supporting connections to one or more remote computing devices, such as computing devices  4741 ,  4751 , and  4761 . Computing devices  4741 ,  4751 , and  4761  may be personal computing devices or servers that include any or all of the elements described above relative to computing device  4701 . Computing device  4761  may be a mobile device (e.g., smart phone) communicating over wireless carrier channel  4771 . 
     The network connections depicted in  FIG. 47  may include local area network (LAN)  4725  and wide area network (WAN)  4729 , as well as other networks. When used in a LAN networking environment, computing device  4701  may be connected to LAN  4725  through a network interface or adapter in communications module  4709 . When used in a WAN networking environment, computing device  4701  may include a modem in communications module  4709  or other means for establishing communications over WAN  4729 , such as Internet  4731  or other type of computer network. The network connections shown are illustrative and other means of establishing a communications link between the computing devices may be used. Various well-known protocols such as transmission control protocol/Internet protocol (TCP/IP), Ethernet, file transfer protocol (FTP), hypertext transfer protocol (HTTP) and the like may be used, and the system can be operated in a client-server configuration to permit a user to retrieve web pages from a web-based server. Any of various conventional web browsers can be used to display and manipulate data on web pages. 
     The disclosure is operational with numerous other general purpose or special purpose computing system environments or configurations. Examples of well-known computing systems, environments, and/or configurations that may be suitable for use with the disclosed embodiments include, but are not limited to, personal computers (PCs), server computers, hand-held or laptop devices, smart phones, multiprocessor systems, microprocessor-based systems, set top boxes, programmable consumer electronics, network PCs, minicomputers, mainframe computers, distributed computing environments that include any of the above systems or devices, and the like. 
     While aspects of the present disclosure have been described in terms of preferred examples, and it will be understood that the disclosure is not limited thereto since modifications may be made to those skilled in the art, particularly in light of the foregoing teachings.