Patent Publication Number: US-2023148993-A1

Title: Ultrasound Probe with Integrated Data Collection Methodologies

Description:
PRIORITY 
     This application claims the benefit of priority to U.S. Provisional Application No. 63/280,047, filed Nov. 16, 2021, which is incorporated in its entirety into this application. 
    
    
     BACKGROUND 
     Ultrasound imaging is a widely accepted tool for guiding interventional instruments such as needles to targets such as blood vessels or organs in the human body. In order to successfully guide, for example, a needle to a blood vessel using ultrasound imaging, the needle is monitored in real-time both immediately before and after a percutaneous puncture in order to enable a clinician to determine the distance and the orientation of the needle to the blood vessel and ensure successful access thereto. However, through inadvertent movement of an ultrasound probe during the ultrasound imaging, the clinician can lose both the blood vessel and the needle, which can be difficult and time consuming to find again. In addition, it is often easier to monitor the distance and orientation of the needle immediately before the percutaneous puncture with a needle plane including the needle perpendicular to an image plane of the ultrasound probe. And it is often easier to monitor the distance and orientation of the needle immediately after the percutaneous puncture with the needle plane parallel to the image plane. As with inadvertently moving the ultrasound probe, the clinician can lose both the blood vessel and the needle when adjusting the image plane before and after the percutaneous puncture, which can be difficult and time consuming to find again. What is needed are ultrasound-imaging systems and methods thereof that can dynamically adjust the image plane to facilitate guiding interventional instruments to targets in at least the human body. 
     Doppler ultrasound is a noninvasive approach to estimating the blood flow through your blood vessels by bouncing high-frequency sound waves (ultrasound) off circulating red blood cells. A doppler ultrasound can estimate how fast blood flows by measuring the rate of change in its pitch (frequency). Doppler ultrasound may be performed as an alternative to more-invasive procedures, such as angiography, which involves injecting dye into the blood vessels so that they show up clearly on X-ray images. Doppler ultrasound may help diagnose many conditions, including blood clots, poorly functioning valves in your leg veins, which can cause blood or other fluids to pool in your legs (venous insufficiency), heart valve defects and congenital heart disease, a blocked artery (arterial occlusion), decreased blood circulation into your legs (peripheral artery disease), bulging arteries (aneurysms), and narrowing of an artery, such as in your neck (carotid artery stenosis). Doppler ultrasound may also detect a direction of blood flow within a blood vessel. 
     Disclosed herein are systems including ultrasound imaging probes having integrated therein one or more scanning components, which enable ultrasound scanning and ancillary scanning such as via a barcode scanner, a camera, and/or a radio-frequency identifier (RFID) scanner with a single ultrasound imaging probe. Additionally, disclosed herein are methods of use of such ultrasound imaging probes. 
     SUMMARY 
     Disclosed herein is an ultrasound-imaging system including, in some embodiments, an ultrasound probe including (i) an array of ultrasonic transducers, activated ultrasonic transducers of the array of ultrasonic transducers configured to emit generated ultrasound signals into a patient, receive reflected ultrasound signals from the patient, and convert the reflected ultrasound signals into corresponding electrical signals of the ultrasound signals for processing into an ultrasound image, and (ii) a secondary data collection module, a console configured to communicate with the ultrasound probe, the console including one or more processors and a non-transitory computer-readable medium having stored thereon logic, when executed by the one or more processors, causes operations including: receiving and processing the electrical signals to generate the ultrasound image, receiving secondary data from the secondary data collection module, wherein the secondary data is data other than the electrical signals corresponding to reflected ultrasound signals, and providing a notification to administrator that includes the secondary data. 
     In some embodiments, the secondary data collection module includes a barcode scanner and the secondary data includes barcode data. In further embodiments, the barcode data identifies one of a patient, a clinician, or a medical device, and wherein the notification includes information corresponding to the patient, the clinician, or the medical device. In other embodiments, the secondary data collection module includes a camera and the secondary data includes image data. In some embodiments, the image data includes a medical device, a packaging of the medical device, a patient identifier, a clinician identifier, or an insertion site of a patient. In yet other embodiments, the image data includes a video capturing insertion of a medical device into a patient. Further, the notification may be a display rendered on a display screen of the console, wherein the display includes the ultrasound image and information corresponding to the secondary data of at least one of (i) patient information, or (ii) medical device information. In some embodiments, the secondary data collection module includes a radio-frequency identifier (RFID) sensor and the secondary data includes RFID data. 
     Also disclosed herein is an ultrasound probe apparatus including an array of ultrasonic transducers, activated ultrasonic transducers of the array of ultrasonic transducers configured to emit generated ultrasound signals into a patient, receive reflected ultrasound signals from the patient, and convert the reflected ultrasound signals into corresponding electrical signals of the ultrasound signals for processing into an ultrasound image and a secondary data collection module configured to collect secondary data that is different than the electrical signals corresponding to reflected ultrasound signals. 
     Additionally, disclosed herein is a method of utilizing an ultrasound-imaging system including a non-transitory computer-readable medium having executable instructions that cause the ultrasound-imaging system to perform a set of operations for ultrasound imaging when the instructions are executed by a processor of a console of the ultrasound-imaging system, the method comprising activating ultrasonic transducers of an array of ultrasonic transducers of an ultrasound probe communicatively coupled to the console, whereby the ultrasonic transducers emit generated ultrasound signals into a patient, receive reflected ultrasound signals from the patient, and convert the reflected ultrasound signals into corresponding electrical signals of the ultrasound signals for processing into ultrasound images, activating a secondary data collection module of the ultrasound probe, the secondary data collection module configured to collect secondary data that is different than the electrical signals corresponding to reflected ultrasound signals, receiving and processing the electrical signals to generate the ultrasound image, receiving secondary data from the secondary data collection module, wherein the secondary data is data other than the electrical signals corresponding to reflected ultrasound signals, and providing a notification to administrator that includes the secondary data. 
     These and other features of the concepts provided herein will become more apparent to those of skill in the art in view of the accompanying drawings and following description, which describe particular embodiments of such concepts in greater detail. 
    
    
     
       DRAWINGS 
         FIG.  1    illustrates an ultrasound-imaging system and a patient in accordance with some embodiments. 
         FIG.  2    illustrates a block diagram of a console of the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments. 
         FIG.  3 A  illustrates a first embodiment of an ultrasound probe that may be included in the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments. 
         FIG.  3 B  illustrates a second embodiment of an ultrasound probe that may be included in the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments. 
         FIG.  3 C  illustrates a third embodiment of an ultrasound probe that may be included in the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments. 
         FIG.  3 D  illustrates a fourth embodiment of an ultrasound probe that may be included in the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments. 
         FIG.  3 E  illustrates a fifth embodiment of an ultrasound probe that may be included in the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments. 
         FIG.  3 F  illustrates a sixth embodiment of an ultrasound probe that may be included in the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments. 
         FIG.  4    illustrates the ultrasound-imaging system of  FIG.  1   , a clinician, medical device packaging, and a patient in accordance with some embodiments. 
         FIG.  5    illustrates an embodiment of a display an ultrasound image, patient information and medical device information rendered on the display screen of the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments. 
     
    
    
     DESCRIPTION 
     Before some particular embodiments are disclosed in greater detail, it should be understood that the particular embodiments disclosed herein do not limit the scope of the concepts provided herein. It should also be understood that a particular embodiment disclosed herein can have features that can be readily separated from the particular embodiment and optionally combined with or substituted for features of any of a number of other embodiments disclosed herein. 
     Regarding terms used herein, it should also be understood the terms are for the purpose of describing some particular embodiments, and the terms do not limit the scope of the concepts provided herein. Ordinal numbers (e.g., first, second, third, etc.) are generally used to distinguish or identify different features or steps in a group of features or steps, and do not supply a serial or numerical limitation. For example, “first,” “second,” and “third” features or steps need not necessarily appear in that order, and the particular embodiments including such features or steps need not necessarily be limited to the three features or steps. Labels such as “left,” “right,” “top,” “bottom,” “front,” “back,” and the like are used for convenience and are not intended to imply, for example, any particular fixed location, orientation, or direction. Instead, such labels are used to reflect, for example, relative location, orientation, or directions. Singular forms of “a,” “an,” and “the” include plural references unless the context clearly dictates otherwise. 
     With respect to “proximal,” a “proximal portion” or a “proximal-end portion” of, for example, a catheter disclosed herein includes a portion of the catheter intended to be near a clinician when the catheter is used on a patient. Likewise, a “proximal length” of, for example, the catheter includes a length of the catheter intended to be near the clinician when the catheter is used on the patient. A “proximal end” of, for example, the catheter includes an end of the catheter intended to be near the clinician when the catheter is used on the patient. The proximal portion, the proximal-end portion, or the proximal length of the catheter can include the proximal end of the catheter; however, the proximal portion, the proximal-end portion, or the proximal length of the catheter need not include the proximal end of the catheter. That is, unless context suggests otherwise, the proximal portion, the proximal-end portion, or the proximal length of the catheter is not a terminal portion or terminal length of the catheter. 
     With respect to “distal,” a “distal portion” or a “distal-end portion” of, for example, a catheter disclosed herein includes a portion of the catheter intended to be near or in a patient when the catheter is used on the patient. Likewise, a “distal length” of, for example, the catheter includes a length of the catheter intended to be near or in the patient when the catheter is used on the patient. A “distal end” of, for example, the catheter includes an end of the catheter intended to be near or in the patient when the catheter is used on the patient. The distal portion, the distal-end portion, or the distal length of the catheter can include the distal end of the catheter; however, the distal portion, the distal-end portion, or the distal length of the catheter need not include the distal end of the catheter. That is, unless context suggests otherwise, the distal portion, the distal-end portion, or the distal length of the catheter is not a terminal portion or terminal length of the catheter. 
     Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by those of ordinary skill in the art. 
     As set forth above, ultrasound-imaging systems and methods thereof are needed that can dynamically adjust the image plane to facilitate guiding interventional instruments to targets in at least the human body. Disclosed herein are dynamically adjusting ultrasound-imaging systems and methods thereof. 
     Referring now to  FIG.  1   , an illustration of an ultrasound-imaging system  100 , a needle  112 , and a patient P is shown in accordance with some embodiments.  FIG.  2    illustrates a block diagram of the ultrasound-imaging system  100  in accordance with some embodiments.  FIG.  3 A  illustrates an ultrasound probe  106  of the ultrasound-imaging system  100  imaging a blood vessel of the patient P prior to accessing the blood vessel in accordance with some embodiments. 
     As shown, the ultrasound-imaging system  100  includes a console  102 , the display screen  104 , and the ultrasound probe  106 . The ultrasound-imaging system  100  is useful for imaging a target such as a blood vessel or an organ within a body of the patient P prior to a percutaneous puncture with the needle  112  for inserting the needle  112  or another medical device into the target and accessing the target. Indeed, the ultrasound-imaging system  100  is shown in  FIG.  1    in a general relationship to the patient P during an ultrasound-based medical procedure to place a catheter  108  into the vasculature of the patient P through a skin insertion site S created by a percutaneous puncture with the needle  112 . It should be appreciated that the ultrasound-imaging system  100  can be useful in a variety of ultrasound-based medical procedures other than catheterization. For example, the percutaneous puncture with the needle  112  can be performed to biopsy tissue of an organ of the patient P. 
     The console  102  houses a variety of components of the ultrasound-imaging system  100 , and it is appreciated the console  102  can take any of a variety of forms. A processor  116  and memory  118  such as random-access memory (“RAM”) or non-volatile memory (e.g., electrically erasable programmable read-only memory (“EEPROM”)) is included in the console  102  for controlling functions of the ultrasound-imaging system  100 , as well as executing various logic operations or algorithms during operation of the ultrasound-imaging system  100  in accordance with executable logic  120  therefor stored in the memory  118  for execution by the processor  116 . For example, the console  102  is configured to instantiate by way of the logic  120  one or more processes for dynamically adjusting a distance of activated ultrasonic transducers  149  from a predefined target (e.g., blood vessel) or area, an orientation of the activated ultrasonic transducers  149  to the predefined target or area, or both the distance and the orientation of the activated ultrasonic transducers  149  with respect to the predefined target or area, as well as process electrical signals from the ultrasound probe  106  into ultrasound images. Dynamically adjusting the activated ultrasonic transducers  149  uses ultrasound-imaging data, magnetic-field data, shape-sensing data, or a combination thereof received by the console  102  for activating certain ultrasonic transducers of a 2-D array of the ultrasonic transducers  148  or moving those already activated in a linear array of the ultrasonic transducers  148 . A digital controller/analog interface  122  is also included with the console  102  and is in communication with both the processor  116  and other system components to govern interfacing between the ultrasound probe  106  and other system components set forth herein. 
     The ultrasound-imaging system  100  further includes ports  124  for connection with additional components such as optional components  126  including a printer, storage media, keyboard, etc. The ports  124  can be universal serial bus (“USB”) ports, though other types of ports can be used for this connection or any other connections shown or described herein. A power connection  128  is included with the console  102  to enable operable connection to an external power supply  130 . An internal power supply  132  (e.g., a battery) can also be employed either with or exclusive of the external power supply  130 . Power management circuitry  134  is included with the digital controller/analog interface  122  of the console  102  to regulate power use and distribution. 
     The display screen  104  is integrated into the console  102  to provide a GUI and display information for a clinician during such as one-or-more ultrasound images of the target or the patient P attained by the ultrasound probe  106 . In addition, the ultrasound-imaging system  100  enables the distance and orientation of a magnetized medical device such as the needle  112  to be superimposed in real-time atop an ultrasound image of the target, thus enabling a clinician to accurately guide the magnetized medical device to the intended target. Notwithstanding the foregoing, the display screen  104  can alternatively be separate from the console  102  and communicatively coupled thereto. A console button interface  136  and control buttons  110  (see  FIG.  1   ) included on the ultrasound probe  106  can be used to immediately call up a desired mode to the display screen  104  by the clinician for assistance in an ultrasound-based medical procedure. In some embodiments, the display screen  104  is an LCD device. 
     The ultrasound probe  106  is employed in connection with ultrasound-based visualization of a target such as a blood vessel (see  FIG.  3 A ) in preparation for inserting the needle  112  or another medical device into the target. Such visualization gives real-time ultrasound guidance and assists in reducing complications typically associated with such insertion, including inadvertent arterial puncture, hematoma, pneumothorax, etc. As described in more detail below, the ultrasound probe  106  is configured to provide to the console  102  electrical signals corresponding to both the ultrasound-imaging data, the magnetic-field data, the shape-sensing data, or a combination thereof for the real-time ultrasound guidance. 
     Optionally, a stand-alone optical interrogator  154  can be communicatively coupled to the console  102  by way of one of the ports  124 . Alternatively, the console  102  can include an integrated optical interrogator integrated into the console  102 . Such an optical interrogator is configured to emit input optical signals into a companion optical-fiber stylet  156  for shape sensing with the ultrasound-imaging system  100 , which optical-fiber stylet  156 , in turn, is configured to be inserted into a lumen of a medical device such as the needle  112  and convey the input optical signals from the optical interrogator  154  to a number of FBG sensors along a length of the optical-fiber stylet  156 . The optical interrogator  154  is also configured to receive reflected optical signals conveyed by the optical-fiber stylet  156  reflected from the number of FBG sensors, the reflected optical signals indicative of a shape of the optical-fiber stylet  156 . The optical interrogator  154  is also configured to convert the reflected optical signals into corresponding electrical signals for processing by the console  102  into distance and orientation information with respect to the target for dynamically adjusting a distance of the activated ultrasonic transducers  149 , an orientation of the activated ultrasonic transducers  149 , or both the distance and the orientation of the activated ultrasonic transducers  149  with respect to the target or the medical device when it is brought into proximity of the target. For example, the distance and orientation of the activated ultrasonic transducers  149  can be adjusted with respect to a blood vessel as the target. Indeed, an image plane can be established by the activated ultrasonic transducers  149  being perpendicular or parallel to the blood vessel in accordance with an orientation of the blood vessel. In another example, when a medical device such as the needle  112  is brought into proximity of the ultrasound probe  106 , an image plane can be established by the activated ultrasonic transducers  149  being perpendicular to a medical-device plane including the medical device as shown in  FIGS.  11 - 13  and  21 - 23    or parallel to the medical-device plane including the medical device for accessing the target with the medical device. The image plane can be perpendicular to the medical-device plane upon approach of the medical device and parallel to the medical-device plane upon insertion of the medical device (e.g., percutaneous puncture with the needle  112 ). The distance and orientation information can also be used for displaying an iconographic representation of the medical device on the display. 
       FIG.  2    shows that the ultrasound probe  106  further includes a button and memory controller  138  for governing button and ultrasound probe  106  operation. The button and memory controller  138  can include non-volatile memory (e.g., EEPROM). The button and memory controller  138  is in operable communication with a probe interface  140  of the console  102 , which includes an input/output (“I/O”) component  142  for interfacing with the ultrasonic transducers  148  and a button and memory I/O component  144  for interfacing with the button and memory controller  138 . 
     The ultrasound probe  106  can include a magnetic-sensor array  146  for detecting a magnetized medical device such as the needle  112  during ultrasound-based medical procedures. The magnetic-sensor array  146  includes a number of magnetic sensors  150  embedded within or included on a housing of the ultrasound probe  106 . The magnetic sensors  150  are configured to detect a magnetic field or a disturbance in a magnetic field as magnetic signals associated with the magnetized medical device when it is in proximity to the magnetic-sensor array  146 . The magnetic sensors  150  are also configured to convert the magnetic signals from the magnetized medical device (e.g., the needle  112 ) into electrical signals for the console  102  to process into distance and orientation information for the magnetized medical device with respect to the predefined target, as well as for display of an iconographic representation of the magnetized medical device on the display screen  104 . (See the magnetic field B of the needle  112  in  FIGS.  3 A- 3 C .) Thus, the magnetic-sensor array  146  enables the ultrasound-imaging system  100  to track the needle  112  or the like. 
     Though configured here as magnetic sensors, it is appreciated that the magnetic sensors  150  can be sensors of other types and configurations. Also, though they are described herein as included with the ultrasound probe  106 , the magnetic sensors  150  of the magnetic-sensor array  146  can be included in a component separate from the ultrasound probe  106  such as a sleeve into which the ultrasound probe  106  is inserted or even a separate handheld device. The magnetic sensors  150  can be disposed in an annular configuration about the probe head  114  of the ultrasound probe  106 , though it is appreciated that the magnetic sensors  150  can be arranged in other configurations, such as in an arched, planar, or semi-circular arrangement. 
     Each magnetic sensor of the magnetic sensors  150  includes three orthogonal sensor coils for enabling detection of a magnetic field in three spatial dimensions. Such 3-dimensional (“3-D”) magnetic sensors can be purchased, for example, from Honeywell Sensing and Control of Morristown, NJ. Further, the magnetic sensors  150  are configured as Hall-effect sensors, though other types of magnetic sensors could be employed. Further, instead of 3-D sensors, a plurality of  1 -dimensional (“1-D”) magnetic sensors can be included and arranged as desired to achieve 1-, 2-, or 3-D detection capability. 
     Five magnetic sensors  150  are included in the magnetic-sensor array  146  so as to enable detection of a magnetized medical device such as the needle  112  in three spatial dimensions (e.g., X, Y, Z coordinate space), as well as the pitch and yaw orientation of the magnetized medical device itself. Detection of the magnetized medical device in accordance with the foregoing when the magnetized medical device is brought into proximity of the ultrasound probe  106  allows for dynamically adjusting a distance of the activated ultrasonic transducers  149 , an orientation of the activated ultrasonic transducers  149 , or both the distance and the orientation of the activated ultrasonic transducers  149  with respect to the target or the magnetized medical device. For example, the distance and orientation of the activated ultrasonic transducers  149  can be adjusted with respect to a blood vessel as the target. Indeed, an image plane can be established by the activated ultrasonic transducers  149  being perpendicular or parallel to the blood vessel in accordance with an orientation of the blood vessel. In other embodiments, fewer than five or more than five magnetic sensors of the magnetic sensors  150  can be employed in the magnetic-sensor array  146 . More generally, it is appreciated that the number, size, type, and placement of the magnetic sensors  150  of the magnetic-sensor array  146  can vary from what is explicitly shown here. 
     As shown in  FIG.  2   , the ultrasound probe  106  can further include an inertial measurement unit (“IMU”)  158  or any one or more components thereof for inertial measurement selected from an accelerometer  160 , a gyroscope  162 , and a magnetometer  164  configured to provide positional-tracking data of the ultrasound probe  106  to the console  102  for stabilization of an image plane. The processor  116  is further configured to execute the logic  120  for processing the positional-tracking data for adjusting the distance of the activated ultrasonic transducers  149  from the target, the orientation of the activated ultrasonic transducers  149  to the target, or both the distance and the orientation of the activated ultrasonic transducers  149  with respect to the target to maintain the distance and the orientation of the activated ultrasonic transducers  149  with respect to the target when the ultrasound probe  106  is inadvertently moved with respect to the target. 
     It is appreciated that a medical device of a magnetizable material enables the medical device (e.g., the needle  112 ) to be magnetized by a magnetizer, if not already magnetized, and tracked by the ultrasound-imaging system  100  when the magnetized medical device is brought into proximity of the magnetic sensors  150  of the magnetic-sensor array  146  or inserted into the body of the patient P during an ultrasound-based medical procedure. Such magnetic-based tracking of the magnetized medical device assists the clinician in placing a distal tip thereof in a desired location, such as in a lumen of a blood vessel, by superimposing a simulated needle image representing the real-time distance and orientation of the needle  112  over an ultrasound image of the body of the patient P being accessed by the magnetized medical device. Such a medical device can be stainless steel such as SS  304  stainless steel; however, other suitable needle materials that are capable of being magnetized can be employed. So configured, the needle  112  or the like can produce a magnetic field or create a magnetic disturbance in a magnetic field detectable as magnetic signals by the magnetic-sensor array  146  of the ultrasound probe  106  so as to enable the distance and orientation of the magnetized medical device to be tracked by the ultrasound-imaging system  100  for dynamically adjusting the distance of the activated ultrasonic transducers  149 , an orientation of the activated ultrasonic transducers  149 , or both the distance and the orientation of the activated ultrasonic transducers  149  with respect to the magnetized medical device. 
     During operation of the ultrasound-imaging system  100 , the probe head  114  of the ultrasound probe  106  is placed against skin of the patient P. An ultrasound beam  152  is produced so as to ultrasonically image a portion of a target such as a blood vessel beneath a surface of the skin of the patient P. The ultrasonic image of the blood vessel can be depicted and stabilized on the display screen  104  of the ultrasound-imaging system  100 . 
     With reference now to  FIGS.  3 A- 3 F , multiple embodiments of the ultrasound probe  106  of  FIG.  1    are shown. It should be understood that the embodiments are provided to illustrate various components that may be included on the ultrasound probe  106  and further understood that any component (other than the array of transducers) is not necessary. Further, the embodiments may be combined such that a first optional component shown in one embodiment may be added to a second embodiment. 
     Referring to  FIG.  3 A , a first embodiment of an ultrasound probe that may be included in the ultrasound-imaging system of  FIG.  1    is shown in accordance with some embodiments. The ultrasound probe  106  includes a probe head  114  that houses a mounted linear array of the ultrasonic transducers  148  or a 2-D array of the ultrasonic transducers  148 , wherein the ultrasonic transducers  148  are piezoelectric transducers or capacitive micromachined ultrasonic transducers (“CMUTs”). When the ultrasound probe  106  is configured with the 2-D array of the ultrasonic transducers  148 , a subset of the ultrasonic transducers  148  is linearly activated as needed for ultrasound imaging in accordance with ultrasound-imaging data, magnetic-field data, shape-sensing data, or a combination thereof to maintain the target in an image plane or switch to a different image plane (e.g., from perpendicular to a medical-device plane to parallel to the medical-device plane) including the target. 
     The probe head  114  is configured for placement against skin of the patient P proximate a prospective needle-insertion site where the activated ultrasonic transducers  149  in the probe head  114  can generate and emit the generated ultrasound signals into the patient P in a number of pulses, receive reflected ultrasound signals or ultrasound echoes from the patient P by way of reflection of the generated ultrasonic pulses by the body of the patient P, and convert the reflected ultrasound signals into corresponding electrical signals for processing into ultrasound images by the console  102  to which the ultrasound probe  106  is communicatively coupled. In this way, a clinician can employ the ultrasound-imaging system  100  to determine a suitable insertion site and establish vascular access with the needle  112  or another medical device. 
     The ultrasound probe  106  may further include the control buttons  110  for controlling certain aspects of the ultrasound-imaging system  100  during an ultrasound-based medical procedure, thus eliminating the need for the clinician to reach out of a sterile field around the patient P to control the ultrasound-imaging system  100 . For example, a control button of the control buttons  110  can be configured to select or lock onto the target (e.g., a blood vessel, an organ, etc.) when pressed for visualization of the target in preparation for inserting the needle  112  or another medical device into the target. Such a control button can also be configured to deselect the target, which is useful whether the target was selected by the control button or another means such as by holding the ultrasound probe  106  stationary over the target to select the target, issuing a voice command to select the target, or the like. 
       FIG.  3 B  illustrates a second embodiment of an ultrasound probe that may be included in the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments. The ultrasound probe  106  of  FIG.  3 B  includes many of the components of the ultrasound probe  106  of  FIG.  3 A  and also includes the barcode scanner  300  integrated directly thereto. For instance, as shown, the barcode scanner  300  may be positioned at a distal end of the ultrasound probe  106  adjacent the probe head  114 . However, the barcode scanner  300  may be positioned in alternative locations on the ultrasound probe  106 , such as between the control buttons  110  and the magnetic sensors  150 . 
     The barcode scanner  300  may be configured to scan and capture data from a patient identifier (ID) band, a clinician ID card, a device ID tag or label, a medicine ID or label, etc. Thus, advantageously, the ultrasound probe  106  of  FIG.  3 B  enables a clinician to perform multiple tasks that may be required before or during a medical procedure with a single device. This simplifies the clinician&#39;s job by eliminating steps of selecting and deploying multiple devices, simplifies the clinician&#39;s training by eliminating an additional device to learn to operate, provides for a more sterile environment as fewer components are utilized (reducing possible points of introducing bacteria), etc. Further, the data collected by the ultrasound scanner  106  of  FIG.  3 B  may all be provided to a single console (e.g., console  102  of  FIG.  1   ) such that a single display screen may be generated and provided to the clinician that includes ultrasound imaging information as well as ancillary information such as information related to a scanned barcode (e.g., information of medicine/drugs provided to the patient, patient information, instructions for use of other medical devices deployed, etc.). For instance, see  FIG.  5    for an example of such a display screen. 
       FIG.  3 C  illustrates a third embodiment of an ultrasound probe that may be included in the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments. The ultrasound probe  106  of  FIG.  3 C  includes many of the components of the ultrasound probe  106  of  FIGS.  3 A- 3 B  and also includes the camera  302  integrated directly thereto. For instance, as shown, the camera  302  may be positioned at a distal end of the ultrasound probe  106  adjacent the probe head  114  and the barcode scanner  300 . However, the camera  302  may be positioned in alternative locations on the ultrasound probe  106 , such as between the control buttons  110  and the magnetic sensors  150 . In some embodiments, the camera  302  may be configured to perform similar functionality as the barcode scanner  300 . For instance, the images collected by the camera  302  may be provided to logic of the console  100 , where the logic may perform image recognition, text recognition or barcode analysis procedures thereon. Thus, it should be understood that in some embodiments, the barcode scanner  300  and the camera  302  need not both be provided. The advantages provided by the integration of the camera  302  into the ultrasound probe  106  are similar to those discussed above with respect to the barcode scanner  300  and  FIG.  3 B . 
       FIG.  3 D  illustrates a fourth embodiment of an ultrasound probe that may be included in the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments. The ultrasound probe  106  of  FIG.  3 D  includes many of the components of the ultrasound probe  106  of  FIGS.  3 A- 3 C  and also includes (i) an alternative position of the camera  302 , and (ii) the camera  302  positioned on an arm  304  that extends outwardly from the body of the ultrasound probe  106 . Additionally, the arm  304  may be optionally rotatable such that a groove  306  may be included in the body of ultrasound probe  106  to receive the arm  304  when rotated from an open position (shown) to a closed position. The positioning of the camera  302  on the arm  304  may enable live imaging, such as of an insertion site of the patient for a medical device (e.g., a needle). Additionally, the insertion process may be recorded by the camera  302  in the position shown in  FIG.  3 D  for viewing at a subsequent time (e.g., to assess the insertion procedure). The advantages provided by the integration of the camera  302  into the ultrasound probe  106  are similar to those discussed above with respect to the barcode scanner  300  and  FIG.  3 B . 
       FIG.  3 E  illustrates a fifth embodiment of an ultrasound probe that may be included in the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments. The ultrasound probe  106  of  FIG.  3 E  includes many of the components of the ultrasound probe  106  of  FIGS.  3 A- 3 E  and also includes (i) an alternative position of the camera  302 , and (ii) an RFID sensor  308  integrated into the body of the ultrasound probe  106 . The RFID sensor  308  may be configured to obtain radio-frequency signals from certain devices such as a clinician&#39;s ID card and/or medical device packaging. The advantages provided by the integration of the RFID sensor  308  into the ultrasound probe  106  are similar to those discussed above with respect to the embodiment of  FIG.  3 E . 
       FIG.  3 F  illustrates a sixth embodiment of an ultrasound probe that may be included in the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments.  FIG.  3 F  is similar to the embodiment of  FIG.  3 D  in that the camera  302  is positioned on an arm  310  extending outwardly from the ultrasound probe  106 . In  FIG.  3 F , the arm  310  extends from a position distal the position of the arm  304  in  FIG.  3 D . The advantages provided by the integration of the camera  302  into the ultrasound probe  106  are similar to those discussed above with respect to the barcode scanner  300  and  FIG.  3 B . 
       FIG.  4    illustrates the ultrasound-imaging system of  FIG.  1   , a clinician, medical device packaging, and a patient in accordance with some embodiments. The embodiment of  FIG.  4    provides an illustration of various possible use cases for embodiments of the ultrasound probe  106  discussed above. For instance, an embodiment of the ultrasound probe  106  including the barcode scanner  300  may be utilized to scan barcodes on a clinician ID card  400  and/or a patient ID bracelet  402 . Additionally, an embodiment of the ultrasound probe  106  including the camera  302  may be configured to image the insertion site S as the medical device  404  is inserted into the patient P. Additionally, the camera  302  may capture an image of the packaging  406  of a medical device (e.g., of the medical device  404 ) where the captured image is analyzed, e.g., through image recognition, optical character recognition, and/or barcode analysis procedures performed by logic of the console  102 . 
       FIG.  5    illustrates an embodiment of a display an ultrasound image, patient information and medical device information rendered on the display screen of the ultrasound-imaging system of  FIG.  1    in accordance with some embodiments.  FIG.  5    provides an illustration of the console  102  including the display screen  104 , where a display  502  is rendered thereon. The display is shown to include an ultrasound image  504  (and a target vessel  506 ) in a first portion of the display  502 , patient information  508  in a second portion of the display  502  (e.g., blood pressure and temperature, which may be obtained through deployment of other devices). Advantageously, the inclusion of an ancillary scanning component (e.g., barcode scanner and/or camera) that is configured to obtain data identifying the patient (e.g., scanning or imaging a patient ID bracelet) may allow for automated syncing of patient information  508  with the ultrasound image  504 . For example, logic of the console  102  may utilize the data identifying the patient obtained through use of the ultrasound probe  106  to retrieve patient information  508  and incorporate such into the display  502 . Similarly, insertion instructions  510  are included in a third portion of the display  502 , where the insertion instructions  510  may be obtained in a similar manner as the patient information  508  (e.g., scan/image a medical device or corresponding packaging, retrieve insertion instructions  510  from a database using the data obtained via the scan/image of the medical device or corresponding packaging where the scanning/imaging was performed using the ultrasound probe  106 ). 
     While some particular embodiments have been disclosed herein, and while the particular embodiments have been disclosed in some detail, it is not the intention for the particular embodiments to limit the scope of the concepts provided herein. Additional adaptations and/or modifications can appear to those of ordinary skill in the art, and, in broader aspects, these adaptations and/or modifications are encompassed as well. Accordingly, departures may be made from the particular embodiments disclosed herein without departing from the scope of the concepts provided herein.