INSERT IMAGING DEVICE FOR SURGICAL PROCEDURES
Insertable imaging devices, and methods of use thereof in minimally invasive medical procedures, are described. In some embodiments, insertable imaging devices are described that can be introduced and removed from an access port without disturbing or risking damage to internal tissue. In some embodiments, imaging devices are integrated into an access port, thereby allowing imaging of internal tissues within the vicinity of the access port, while, for example, enabling manipulation of surgical tools in the surgical field of interest. In other embodiments, imaging devices are integrated into an imaging sleeve that is insertable into an access port. Several example embodiments described herein provide imaging devices for performing imaging within an access port, where the imaging may be based one or more imaging modalities that may include, but are not limited to, magnetic resonance imaging, ultrasound, optical imaging such as hyperspectral imaging and optical coherence tomography, and electrically conductive measurements.
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This document is a continuation application claiming the benefit of, and priority to, the following documents: U.S. patent application Ser. No. 15/786,133, titled “INSERT IMAGING DEVICE FOR SURGICAL PROCEDURES,” and filed on Oct. 17, 2017; U.S. patent application Ser. No. 14/777,300 titled “INSERT IMAGING DEVICE FOR SURGICAL PROCEDURES,” and filed on Sep. 15, 2015; International PCT Patent Application No. PCT/CA2014/000254 titled “INSERT IMAGING DEVICE FOR SURGICAL PROCEDURES,” and filed on Mar. 14, 2014; U.S. Provisional Application Ser. No. 61/801,746, titled “INSERT IMAGING DEVICE,” and filed on Mar. 15, 2013; U.S. Provisional Application Ser. No. 61/818,255, titled “INSERT IMAGING DEVICE,” and filed on May 1, 2013; U.S. Provisional Application Ser. No. 61/801,143, titled “INSERTABLE MAGNETIC RESONANCE IMAGING COIL PROBE FOR MINIMALLY INVASIVE CORRIDOR-BASED PROCEDURES,” and filed on Mar. 15, 2013; U.S. Provisional Application Ser. No. 61/818,325, titled “INSERTABLE MAGNETIC RESONANCE IMAGING COIL PROBE FOR MINIMALLY INVASIVE CORRIDOR-BASED PROCEDURES,” and filed on May 1, 2013; U.S. Provisional Application No. 61/800,787, titled “POLARIZED LIGHT IMAGING DEVICE,” and filed on Mar. 15, 2013; U.S. Provisional Application Ser. No. 61/800,911, titled “HYPERSPECTRAL IMAGING DEVICE,” and filed on Mar. 15, 2013; U.S. Provisional Application Ser. No. 61/800,155, titled “PLANNING, NAVIGATION AND SIMULATION SYSTEMS AND METHODS FOR MINIMALLY INVASIVE THERAPY,” and filed on Mar. 15, 2013; U.S. Provisional Application Ser. No. 61/924,993, titled “PLANNING, NAVIGATION AND SIMULATION SYSTEMS AND METHODS FOR MINIMALLY INVASIVE THERAPY,” and filed Jan. 8, 2014, all of which are hereby incorporated herein by reference in their entirety.
FIELDThe present disclosure is generally related to image guided medical procedures.
BACKGROUNDIn the field of surgery, imaging and imaging guidance is becoming a more significant component of clinical care, from diagnosis of disease, monitoring of the disease, planning of the surgical approach, guidance during the procedure, and follow-up after the procedure is complete, or as part of a multi-faceted treatment approach.
Integration of imaging data in the surgical suite has become common-place for neurosurgery, where typically brain tumors are excised through an open craniotomy approach guided by imaging. The data that is used typically consists of CT scans with or without associated contrast (iodinated contrast), and MRI scans with or without associated contrast (gadolinium contrast). Systems provide a means to register the imaging data sets together, and registration methods to translate the three dimensional imaging space to the three dimensional space of the patient and tracking of instruments relative to the patient and the associate imaging data by way of an external hardware system such as a mechanical arm, or an RF or optical tracking device.
SUMMARYInsertable imaging devices, and methods of use thereof in minimally invasive medical procedures, are described. In some embodiments, insertable imaging devices are described that can be introduced and removed from an access port without disturbing or risking damage to internal tissue. In some embodiments, imaging devices are integrated into an access port, thereby allowing imaging of internal tissues within the vicinity of the access port, while, for example, enabling manipulation of surgical tools in the surgical field of interest. In other embodiments, imaging devices are integrated into an imaging sleeve that is insertable into an access port. Several example embodiments described herein provide imaging devices for performing imaging within an access port, where the imaging may be based one or more imaging modalities that may include, but are not limited to, magnetic resonance imaging, ultrasound, optical imaging such as hyperspectral imaging and optical coherence tomography, and electrically conductive measurements.
Embodiments will now be described, by way of example only, with reference to the several figures of the drawing(s), in which:
Various embodiments and aspects of the disclosure will be described with reference to details discussed below. The following description and drawings are illustrative of the disclosure and are not to be construed as limiting the disclosure. Numerous specific details are described to provide a thorough understanding of various embodiments of the present disclosure. However, in certain instances, well-known or conventional details are not described in order to provide a concise discussion of embodiments of the present disclosure.
As used herein, the terms, “comprises” and “comprising” are to be construed as being inclusive and open ended, and not exclusive. Specifically, when used in the specification and claims, the terms, “comprises” and “comprising” and variations thereof mean the specified features, steps or components are included. These terms are not to be interpreted to exclude the presence of other features, steps or components.
As used herein, the term “exemplary” means “serving as an example, instance, or illustration,” and should not be construed as preferred or advantageous over other configurations disclosed herein.
As used herein, the terms “about” and “approximately” are meant to cover variations that may exist in the upper and lower limits of the ranges of values, such as variations in properties, parameters, and dimensions. In one non-limiting example, the terms “about” and “approximately” mean plus or minus 10 percent or less.
Unless defined otherwise, all technical and scientific terms used herein are intended to have the same meaning as commonly understood to one of ordinary skill in the art. Unless otherwise indicated, such as through context, as used herein, the following terms are intended to have the following meanings:
As used herein, the phrase “access port” refers to a cannula, conduit, sheath, port, tube, or other structure that is insertable into a subject, in order to provide access to internal tissue, organs, or other biological substances. In some embodiments, an access port may directly expose internal tissue, for example, via an opening or aperture at a distal end thereof, and/or via an opening or aperture at an intermediate location along a length thereof. In other embodiments, an access port may provide indirect access, via one or more surfaces that are transparent, or partially transparent, to one or more forms of energy or radiation, such as, but not limited to, electromagnetic waves and acoustic waves.
As used herein the phrase “intraoperative” refers to an action, process, method, event or step that occurs or is carried out during at least a portion of a medical procedure. Intraoperative, as defined herein, is not limited to surgical procedures, and may refer to other types of medical procedures, such as diagnostic and therapeutic procedures.
Embodiments of the present disclosure provide imaging devices that are insertable into a subject or patient for imaging internal tissues, and methods of use thereof. Some embodiments of the present disclosure relate to minimally invasive medical procedures that are performed via an access port, whereby surgery, diagnostic imaging, therapy, or other medical procedures (e.g., minimally invasive medical procedures) are performed based on access to internal tissue through access port.
An example of an access port is an intracranial access port which may be employed in neurological procedures in order to provide access to internal tissue pathologies, such as tumors. One example of an intracranial access port is the BrainPath® surgical access port provided by NICO®, which may be inserted into the brain via an obturator with an atraumatic tip in the brain. Such an access port may be employed during a surgical procedure, by inserting the access port, via the obturator that is received within the access port, through the white matter fibers of the brain to access a surgical site.
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As noted above, some embodiments of the present disclosure provide insertable imaging devices that may be employed during such access-port-based procedures. The use of imaging devices within an access port, or the incorporation of imaging devices into an access port, provides additional interoperative images and data that may improve the accuracy, efficiency, and effectiveness of medical procedures. In some embodiments, methods and devices are described for performing imaging with an insertable imaging device that can be introduced and removed from an access port without disturbing or risking damage to internal tissue. In some embodiments, devices are integrated into an access port, thereby allowing imaging of internal tissues within the vicinity of the access port, while, for example, enabling manipulation of surgical tools in the surgical field of interest. Several example embodiments described herein provide imaging devices for performing imaging within an access port, where the imaging may be based one or more imaging modalities that may include, but are not limited to, magnetic resonance imaging, ultrasound, optical imaging such as hyperspectral imaging and optical coherence tomography, and electrically conductive measurements.
For example, in some embodiments, insertable imaging devices may simultaneously accommodate multiple imaging modalities. Insertable imaging devices according to the present disclosure can be also be integrated into currently available, e.g., conventional, imaging systems, such as MRI scanners, or may be interfaced with a dedicated imaging system. In other embodiments, insertable imaging devices may be configured to accommodate point measurement devices and modalities such as, but not limited to, a Raman touch probe and conductance or pressure measurement, e.g., involving measurements made at a single point or across an array of sensors.
Understood is that, while many of the embodiments described herein relate to access-port-based neurological procedures, the embodiments provided herein, unless otherwise stated, may be employed for a wide range of medical procedures, involving a wide range of anatomical regions of the body. For example, various embodiments may be employed for imaging during procedures such as endorectal and endovaginal procedures. Furthermore, while many of the embodiments of the present disclosure relate to access-port-based procedures, some embodiments, such as insertable imaging probes described herein, may be employed with or without an access port.
As described below, an insertable imaging device may, in some embodiments, include at least one imaging array employing at least one imaging modality. Examples of imaging modalities include magnetic resonance MR imaging, ultrasound, optical imaging (such as, but not limited to visible 2D-3D imaging, optical coherence tomography, hyper-spectral imaging, polarized light imaging, Raman Imaging, and fluorescence Imaging), electrophysiology, optical coherence tomography, X-ray (computerized tomography, spectral X-ray), photo-acoustic imaging, positron emission tomography, thermal imaging, electromechanical arrays (strain gauges, ionic conductors), and biosensor arrays. Also understood is that these modalities may be used in receive and/or transmission mode, and may be used in conjunction with an external transmission or receiving system, and image processing system. Some embodiments may include a means to transmit the signals to and from the detectors/transmitters and coordinate the image acquisition, and image alignment. Some embodiments may also include a means to integrate the acquired information with a previously acquired volumetric image data.
The present disclosure is organized as follows. Section 1 presents various embodiments of insertable imaging device that are generic to a wide range of imaging modalities, where the generic embodiments include insertable imaging probes, access ports with integrated imaging elements, and embodiments involving various combinations of insertable imaging probes and access ports with integrated imaging elements. Section 2 describes various embodiments of insertable imaging probes and access ports with integrated imaging elements that are configured for magnetic resonance imaging. Additional sections of the present disclosure describe additional imaging modalities, and embodiments involving multimodal imaging.
1. Insertable Imaging Devices 1.1 Insertable Imaging ProbeReferring to
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As described further below, the close fit between the insertable imaging probe and the access port reduces the amount of air between the imaging probe and the access port. This may be useful in improving image quality for selected imaging modalities. For example, the presence of air can lead to image distortion in magnetic resonance imaging due to differences in susceptibility between air, tissue, and the materials forming the access port and the insertable imaging probe. In another example, in which the insertable imaging probe employs an acoustic or optical imaging modality, the presence of an air gap may lead to losses in signal and/or signal artifacts due to multiple reflections. In such cases, the imaging probe may be coated with a material such as a liquid or gel in order to improve the matching of impedances between the insertable imaging probe and the access port.
In alternate implementations, insertable imaging probes may have different diameters suitable for several different types of access ports. For example, an insertable imaging probe may have a diameter suitable to be received within the NICO® Brainpath® access port, which is currently available in several lengths: 50 mm, 60 mm and 75 mm, where the inner diameter is 13.5 mm. Different lengths are used depending of depth of tumor/target. An imaging probe for use with such a port would have a diameter less than 13.5 mm. An imaging probe that needs to be moved directionally within the port would have a diameter significantly less than 13.5 mm. In one example implementation, an imaging probe that is intended to slide freely along the axis of the port could have a diameter between approximately 12 mm and 13.4 mm. In other example implementations, an insertable imaging probe may have a diameter suitable for other types of access ports, such as access ports suitable for abdominal or spinal surgical procedures.
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As above-described, several embodiments of the present disclosure provide insert imaging probes that comprise a cylindrical body portion that is configured for insertion into an access port having a cylindrical bore. In some applications, a portion of the insertable imaging probe may be contacted with tissue (or could potentially be contacted with tissue) during a medical procedure. For example, in some embodiments described herein, the distal portion of the insertable imaging probe may contact tissue when the probe is inserted into an access port or conduit having a distal opening (aperture). Accordingly, in some embodiments, at least part of the body portion of the insertable imaging probe may have an external surface formed from a material that is bio-compatible. Examples of suitable biocompatible materials include polyurethane, polycarbonate, or Teflon.
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In some example embodiments, a handle may be provided that is removably connectable to different body portions, where each body portion has a different coil orientation. For example, one body portion may include an endonasal coil with two orthogonal striplines, while another body potion may include a port coil using an orthogonal loop and a stripline. As long as the coil elements are tuned outside of the handle, the preamplifier could be located in the handle.
1.1.2 Markings on Insertable Imaging ProbeIn some embodiments, the insertable imaging probe may have delineated markings to assist in the positioning of the insertable imaging probe within the access port. For example, the body portion of the insert imaging probe may have graduated measurement markings to provide depth information when guiding the port into the access probe.
In other example implementations, the insertable imaging probe may include one or more directional markings identifying an orientation of the probe relative to a preferred orientation. For example, in embodiments in which the insertable imaging device includes one or more magnetic resonance imaging coils, the body or handle of the imaging probe may include a directional marker identifying a preferred orientation of the insertable imaging probe relative to the B0 magnetic field. Alternatively, in the example case of an insertable imaging probe that is configured for performing polarization sensitive imaging, the insertable imaging probe may have one or more directional markers identifying one or more polarization axes.
1.1.3 Single Element Insertable Imaging ProbesIn some embodiments, an insertable imaging probe (or an imaging introducer) may including a single imaging element, such as a single MR coil or a single ultrasound transducer. In such cases, 2D and/or 3D imaging may be realized by mechanically (robotically) rotating the insertable imaging probe during insertion or removal of the insert component, and subsequently reconstructing the volume image through the use of software reconstruction methodologies based on a tracked orientation and position of the insertable imaging probe. In some embodiments, two or more imaging elements may be employed, where each element is associated with a different imaging modality. Such embodiments are described in more detail below.
1.1.4 Insertable Imaging Probes with Multi-Element Imaging Arrays
In other embodiments, an insertable imaging probe (or an imaging introducer) may including a plurality of imaging elements, e.g., an array of imaging elements, such as an array of MR coils, and an array of ultrasound transducers. Such embodiments are described in more detail below.
1.2 Imaging Introducer for Access PortReferring to
1.3 Access Port with Integrated Imaging Elements
In the preceding embodiments, insertable imaging devices were described as insertable imaging probes that may be configured for use with an access port. However, in other embodiments, the access port itself may have imaging elements formed therein or thereon. For example, the access port may have integrated imaging elements, such as, but not limited to, magnetic resonance MR imaging, ultrasound, optical imaging devices (such as, but not limited to visible 2D imaging-3D imaging), optical devices and/or conduits for performing optical coherence tomography, hyper-spectral imaging, polarized light imaging, Raman Imaging, and fluorescence Imaging), electrophysiology, photo-acoustic imaging, thermal imaging, electromechanical arrays (strain gauges, ionic conductors), and biosensor arrays.
An external connection to the proximal end of the access port could be made with connectors such as pins and sockets, with push-on connectors (such as MCX, or SMB), or threaded coaxial connectors such as SMA, or any other multi-pin connector. If the connector is to be used in a magnetic resonance imaging system, the connector should be non-magnetic.
1.4 Insertable Sleeves with Integrated Imaging Elements
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In an alternative embodiment, in which an imaging element is incorporated into the sleeve near or at a distal region of the imaging sleeve, such that it is oriented for imaging a tissue region beyond the distal end of the imaging sleeve, e.g., by imaging in a longitudinal direction. In such an embodiment, the imaging element may obtain images through the bottom of the access port, or directly from the internal tissue, depending on the configuration of the distal end of the access port, e.g., depending on whether or not an aperture is present in the access port, or depending on the width of an aperture in the access port. The region imaged by the imaging sleeve in this alternative embodiment could be increased, for example, by rotating the imaging sleeve. Understood is that other embodiments may be provided by combining the aspects mentioned above, such that one or more image elements are provide for both longitudinally directed imaging and laterally directed, e.g., radially, imaging. Furthermore, an alternative embodiment in which an array of imaging elements are integrated into the imaging sleeve.
The imaging element or elements incorporated into the imaging sleeve may employ a wide range of imaging modalities, including, but not limited to, magnetic resonance MR imaging, ultrasound, optical imaging devices (such as, but not limited to visible 2D imaging-3D imaging), optical devices and/or conduits for performing optical coherence tomography, hyper-spectral imaging, polarized light imaging, Raman Imaging, and fluorescence Imaging), electrophysiology, photo-acoustic imaging, thermal imaging, electromechanical arrays (strain gauges, ionic conductors), and biosensor arrays.
In some embodiments, the imaging sleeve may have an aperture or opening at its distal portion, such that the operator or clinician may insert items such as tools or other imaging devices and access internal tissues exposed through the central bore. In other embodiments, the distal end of the imaging sleeve may be closed at its distal surface by a tissue fixing surface that is transparent or at least partially transparent to imaging radiation associated with at least one imaging modality.
One potential benefit of an imaging sleeve embodiment is the ability to intraoperatively remove an imaging sleeve of a first type or modality and replace it with an imaging sleeve of a second type or modality. This benefit is not present for the aforementioned embodiments involving an access port with integrated imaging elements, in which the choice of imaging elements is fixed.
1.5 Combinations of Insertable Imaging DevicesIn other embodiments, two or more insertable imaging devices may be used together, for example, in order to achieve multi-modal imaging of internal tissues. Understood is that a wide variety of combinations of insertable imaging devices exists that may be combined together to provide different imaging embodiments. The following examples are provided to illustrate some example implementations of such embodiments, and the scope of the present disclosure is not intended to be limited to these embodiments.
Some specific examples of combinations of insertable imaging devices are described and illustrated below.
1.5.1 Multiple Coaxial Imaging SleevesReferring to
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In a further embodiment, an access port with integrated imaging element(s) and one of an insertable imaging probe and an imaging introducer may be envisioned.
1.5.4 Imaging Access Port and Imaging Sleeve(s) and Insert Imaging Probe/Imaging IntroducerReferring to
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While the preceding section has introduced several embodiments of the present disclosure from a general perspective, the following sections present specific and non-limiting embodiments providing example implementations involving selected imaging modalities or combinations of imaging modalities. The following section presents example various implementations involving magnetic resonance insertable imaging devices.
2. Magnetic Resonance (MR) Insert Imaging DeviceThe present section describes various embodiments employing one or more magnetic resonance imaging radio-frequency (RF) coils, e.g., coil elements, for imaging within an access port, cannula, lumen, channel or other such structure, in order to achieve magnetic resonance imaging within an internal area of interest.
Some embodiments introduced herein provide insertable MR imaging devices that are alternatives to current surface or volume coils, where the insertable MR imaging devices can be inserted within a cavity to provide imaging of the tissues surrounding the devices and tissues beyond a distal end of the device (end-fire imaging) given its close proximity. The coil's ability to detect signals increases as the coil approaches the tissue being imaged. RF coils that are local to the tissue of interest have a higher signal-to-noise ratio (SNR) than those positioned further away, and thereby a higher quality image.
As described above, some embodiments described in the present section may complement a minimally-invasive neurological procedure (such as surgical procedures) whereby a procedure involving internal brain tissue is conducted via a narrow corridor formed via an access port. For example, an insertable magnetic resonance imaging device may be adapted to be received, e.g., slidably received, as described in Section 1 above, into the bore of an access port and exploit its close position to produce MR images, such as high resolution MR images of the surrounding (lateral) brain tissue and/or forward-looking (anterior, distal) tissues. Such images may be used during medical procedures, e.g., surgical procedures, potentially providing detail that would otherwise not be obtainable with current technologies (or would otherwise be obtainable with less resolution or signal to noise, using currently available technologies).
Several insertable MR coil probes are configured for vascular or prostate imaging, where the tissue of interest is located adjacent (laterally) to the insertable coil. Some embodiments of the present section of the disclosure provide insertable imaging devices that are suitable for imaging anterior tissues, or both lateral and anterior tissues. Such devices may be useful, for example, in neurosurgical and endo-nasal applications involving an inserted access port, where it is imperative to receive signals from the tissue residing at the distal portion of an access port.
2.1 Example MR SystemReferring to
The example system includes an insertable MR imaging device, which may be, for example, an insertable MR imaging probe, an insertable MR imaging introducer for inserting an access port, an access port with one or more integrated MR imaging coils, one or more MR imaging sleeves that are configured to be coaxially inserted into an access port, or various combinations of these insertable imaging devices, as illustrated in Section 1. Various example implementations of such insertable MR imaging devices, and various coil configurations, are described in detail below.
Magnetic resonance imaging can be performed either with separate transmit and receiver coils, or by using the same coil for transmit and receive. The transmit coil may be a head coil, body coil, or the probe itself. The reason one tends to use a separate transmit coil is to have uniform excitation of tissue. However, by using appropriate pulse sequences, it is possible to still obtain reasonable images from a non-uniform T/R coils.
Other elements included in the example MR system, shown the Figure include a gradient system consisting of coils, amplifiers, and direct alternating current (DAC) converters, an RF system which comprises a transmitting and receiving coil which may or may not be the same device, in addition to DAC/ADC, and amplifiers. Finally, a computer, controller, pulse generator and reconstruction engine are included.
The controller sends the pulse sequence at the correct time, and the reconstruction engine generates the image from the raw data. The controller and the reconstruction engine, while shown as separate components in
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In some embodiments, the insertable MR imaging device is an insertable imaging probe, as described in Section 1.1 above, where the imaging elements are one or more MR coils.
2.3.1 Probe HousingIn embodiments in which the MR imaging probe is configured to be used within a MRI scanner, employing the scanner to provide the primary B0 field, the probe housing constructed from an MRI-compatible material. Examples of MRI-compatible materials include polycarbonate, Teflon, Delrin and PEEK.
The dimensions of the insertable imaging probe may be selected such that the probe may fit within a pre-selected access port, as described in Section 1.1. However, understood is that the MR imaging probe intended to be limited to applications involving the use of an access port, and may additionally or alternatively be used outside of an access port in any in-situ or ex-situ applications where appropriate. For example, MR imaging probe embodiments according to the present disclosure may be employed for local imaging during an open craniotomy, endonasally, or when examining sample tissue. In some non-limiting example embodiments, the diameter of the MR imaging probe can range from a diameter from less than approximately 1 mm to 13 mm, and with a length of less than approximately 1 mm to 100 mm.
In some embodiments, at least one portion of the MR imaging probe may be disposable and/or sterilizable, as described in Section 1.1. For example, the disposable and/or sterilizable (e.g., autoclavable) portion of the insertable MR imaging probe may be connectable, via a locking mechanism, to a handle that is used to position the MR imaging probe as required. This handle, which may or may not be disposable, may also serve to store electrical components and/or to route cables back to the MRI system as a whole. Incorporating some or all of the magnetic resonance circuit elements within the handle of the probe enables a slim silhouette of the body portion of the MR imaging probe.
As described in Section 1.1.1, in some embodiments, the electrical and imaging components contained within the MR imaging probe may be divided into two groups: components that are housed within the handle, and components that are housed within the insertable and optionally disposable body portion of the insertable imaging probe. In some embodiments, at least some of the electrical components of the MR insertable imaging probe are housed within the handle, while other components, such as other electrical components and imaging elements or imaging assemblies, are housed within the disposable body portion. For example, at least some of the electrical components, such as at least some components of the tuning and matching circuit, or preamplifier circuit, may be housed within the handle portion, while other components, such as one or more electrical coils, may be housed within the body portion of the insertable imaging probe.
Some example configurations for the integration of electrical components into the handle of a MR imaging probe are as follows. In one example, only the wire portion of the coil resides in the probe body, while the remainder of the components reside in the handle. In another example, the coil wire and tuning capacitors reside within the probe body, while the matching components and preamplifier(s) reside in the handle. In another example, the coil wire, tuning capacitors, and matching circuits reside within the probe body, while the preamplifier(s) reside within the handle. Finally, in another example, all components may be housed within the probe body. In embodiments in which one or more components are integrated into the handle, for use with a disposable or interchangeable probe body portion having one or more integrated coils, the tolerances on the capacitors housed within the handle portion could be specified to be sufficiently low or tight.
Some MR imaging probe configurations according to embodiments provided herein serve to excite or receive a B1 field substantially perpendicular with the main BO field, as generated by the main magnet, to acquire a high or maximum signal potential. Possible is that the alignment of the port coil with the main magnetic field changes with operating conditions, for example, the angle of the operating corridor. For this reason, the MR imaging probe may be made available in varying coil geometries to accommodate operating conditions and magnetic field orientations. The various coil configurations described below provide several non-limiting example implementations of such different coil geometries.
In some embodiments, the handle portion of the MR imaging probe may be reusable, and may be configured to mate with a variety or disposable and/or sterilizable body portions having different coil types of geometries.
2.3.2 Markings on Coil Housing and/or Handle
As noted in Section 1.1.2, the body and/or handle portion of the insert imaging probe may have delineated markings, for example, with graduated measurement markings to provide depth information (perception) when guiding the port into the cavity.
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The coil configurations presented below are provided as example and non-limiting implementations of potential coil configurations. Some of the following embodiments provide coils that are configured to produce a forward-looking focused receiving or transmitting zone. In other words, some of the following embodiments provide coil configurations that are sensitive to regions anterior to the longitudinal probe body (regions beyond the distal end of the probe body), e.g., in an end-fired configuration beyond the distal region of the body of the imaging probe. Such embodiments may be included or incorporated within the various MR imaging probes described within this disclosure.
The coils themselves may be formed from a conductive material, for example copper, silver, silver coated copper wire, super conducting wire or tape, high temperature superconducting wire or tape, carbon nanotubes, or graphene, that may or may not be cooled (to lower metal resistivity and hence increase SNR) during image acquisition. Where needed, a dielectric substrate may be used. Suitable dielectric materials may be materials such as polyurethane, polycarbonate, Teflon, air, foam, FR4, liquid crystal polymer (LCP), low temperature cofired ceramics (LTCC), or high temperature cofired ceramics (HTCC), among others.
Understood is that the MR coil may be provided according to a number of different configurations and fabrication methods. For example, the coil may be formed from wire and wound. Alternatively, the coil could be thick film conductor, and screen printed. In other examples, the coil could be tape and adhered to a surface. In other examples, the coil metal may be sputtered or machined away from a block of metal, etched, or formed using EDM.
2.4.1 Folded StriplineReferring to
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In some example implementations, the width of the stripline can vary from less than approximately 1 mm to greater than 13 mm, while the length of the folded stripline can measure from less than 1 mm to greater than 100 mm. The value of the tuning capacitors Ct will change as the length is varied, because the length of the antenna corresponds to inductance, and the capacitors are required to resonate with the inductance. One skilled in the art will know to vary the capacitor value as the length is varied.
Understood is that many possible configurations of the stripline resonator based coil exist. The following sections illustrate some additional example implementations that involve coils based on multiple striplines.
2.4.2 Folded Quadrature StriplinesReferring to
To connect to tuning and matching circuitry, a ground connection would be attached to the center line. A matching circuit would be attached each of the circle-dot connections. The matching circuit could be a matching capacitor, or inductor, or phase shifting network, followed by a preamplifier. The end of the probe is at the other end of the capacitors.
Understood is that the number of striplines used herein may vary. These striplines are depicted as sharing a common ground plane within the center of the coil; however, in other embodiments, the striplines may have separate ground planes.
2.4.3 Distal Stripline ArraysReferring to
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The preceding embodiments described several example implementations of coil configurations that may be employed in an insertable MR imaging device, such as an insertable MR imaging probe. Understood is that coils according to these configurations, or according to variations thereof, may be provided in an array form.
2.5.1 Sparse and Dense ArraysIn some embodiments, an array may be formed by providing, on or within an insertable MR imaging device, a plurality of coils in a prescribed spatial arrangement. The array of coil elements which combine to form the port coil may be provided according to many different embodiments without departing from the scope of the present disclosure. Example embodiments feature an array of RF elements to enable parallel imaging where the sensitivity of each element is used to accelerate imaging times. These arrays may be used as receive-only, transmit-only, or in combination as a transceiving device. In transceiving mode, an electrical switch is included in order to toggle between the receiving and transmitting circuits. Examples involving parallel imaging include asymmetric g-factor, using phase encoding in one direction, driving gradients in opposite direction.
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In some embodiments, the array elements of a dense array may form a phased array. In a phased array, each coil has a spatially separate region of sensitivity.
Within the array, each element may be tuned to the Larmor frequency of the nuclei under investigation using non-magnetic capacitive components as required. These elements may have multiple tunings to enable collecting data from numerous nuclei. The desired tuning can be selected actively by way of an electronic switch that includes the appropriate tuning capacitors within the circuit. The Larmor frequency is proportional to the applied magnetic field strength, and as such, the imaging array can be configured to operate at varying field strengths, whether it be a low-field or high-field application. To maintain isolation between the channels corresponding to various coil elements, the coil elements are decoupled from each other, for example, either capacitively, geometrically, or inductively within the circuit. The plurality and placement of the capacitive and/or inductive elements are dictated by individual coil geometries. Where appropriate these components may be placed in the handle.
In one embodiment, the imaging device may include a dense array of MRI receiver coils, such as an array of stripline coils, as shown in
In addition to the aforementioned embodiments involving single and multiple coils of a given type, understood is that in other embodiments, a MR imaging probe may include multiple coil types, for example, to form a coil array.
For example, in some embodiments, two or more of loop coils, striplines, and butterfly coils can be combined within a MR imaging probe. In some embodiments, the coils that are combined may include one or more folded coils to generate an end-fire focused imaging area. The proceeding section presents several non-limiting examples of such combinations. Understood is that these examples are non-limiting and that other configurations may be obtained by alternative combinations of two or more coil types.
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In some embodiments, the insertable MR imaging probe may be employed for parallel imaging, which is a technique used in MR to reduce the acquisition time. This is accomplished by providing multiple receiving coils, each receiving signals from a slightly different spatial area. Parallel imaging may be performed in either the slice direction, the frequency-direction, or the phase encoding direction. Parallel imaging will be most effective when the body portion of the probe is oriented such that the phase encoding direction of the scanner is perpendicular to the axis of the striplines. However, due to the variances of neurosurgery, the direction of the port often cannot be known in advance, nor can it be fixed.
To still allow for maximum parallel imaging, a navigation system can be used to track the location of the port relative to the patient, and the scanner can then choose an oblique slice. Typically, in MR scanners, the scan planes are chosen in standard orthogonal planes, i.e. axial, sagittal, and coronal. However, it is possible to scan in any plane (referred to as an oblique plane) by choosing the gradients correctly. In order for the scanner to know the direction of the port, the port coil must be tracked, typically by optical means.
An MR image typically has two axes—the frequency axis, and the phase axis. Parallel imaging can be used (but not exclusively) to speed up the time of acquiring the phase axis. The frequency axis and the phase axis can correspond to a real axis, such as ‘x’, or ‘y’, or ‘z’, or any arbitrary-direction. If an array of coils was placed in a scanner such that each coil was arranged on a line that did not correspond to the scanner's definition of ‘x’, ‘y’, or ‘z’, it could be advantageous to define an oblique reference plane so that the axis of the coils does lie along this plane. This will allow maximum time improvement using parallel imaging. The combination of knowledge of the port's orientation obtained from an optical tracking system with the knowledge of the scanner's reference planes will allow a user to vary the scan parameters such that the oblique angles chosen by the scanner maximize the parallel imaging capacity.
2.5.4 Rotatable Forward-Looking Coil ElementIn another embodiment, the forward-looking imaging capability of an MR insertable imaging probe may be extended by providing a means or mechanism for rotating the tip of the coil.
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Noted is that the same functionality of scanning a broad range of angles through the end-fire area can be achieved with a rigid probe with one wrist and one elbow joint. The joints can be actuated using electromechanical actuators or mechanical actuators such as gears, cables and pulleys.
Although the present embodiments, with a rotating or swiveling distal portion of the probe, pertain to insertable MR imaging probes, understood is that they may be extended or adapted to insertable imaging probes employing other imaging modalities, such as optical and ultrasound imaging.
2.5.5 Insertable MR Imaging Probe with Expandable Forward-Looking Coil Elements
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2.6 Access Ports with Embedded Coils
The preceding embodiments of Section 2 have disclosed various example insertable MR imaging probes. In several of the forthcoming portions of Section 2, alternative embodiments are described in which one or more coils, e.g., coil elements, are formed on or within an access port, or a sleeve that is insertable into an access port, as initially described in Sections 1.3 and 1.4.
In one embodiment, one or more coil elements are formed on, or embedded within, an access port, thus providing a hollow imaging sleeve wherein instruments such as surgical tools can be inserted during a medical procedure. This provides an entry point for other imaging devices, MR guided therapies, or contrast agent administration. This may include biopsy tools, deep brain stimulation devices, thermal imaging equipment, or ultrasound devices among others.
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The embodiments below illustrate a non-limiting set of other example implementations of access ports with integrated imaging coils.
2.6.1 Examples of Access Ports with Integrated Coils
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In other embodiments, an imaging sleeve with one or more integrated MR coils may be provided, where the imaging sleeve is insertable into an access port, thereby providing a reconfigurable and optional means of port-based-imaging while still providing a central bore that provides access (direct or indirect) to internal tissues. This embodiment was introduced in Section 1.4.
In one embodiment, one or more coil elements are formed on, or embedded within, a sleeve that is slidably received within an access port, thus providing a hollow imaging sleeve wherein instruments such as surgical tools can be inserted during a medical procedure. All the geometries with hollow openings are applicable here.
2.8 Embodiments with Combinations of Multiple Insertable MR Imaging Devices
Finally, understood is that, as described in Section 1.5 (and in Sections 1.5.1-1.5.5), additional embodiments may be provided by combining two or more of the above insertable imaging devices.
For example, in one example implementation, an insertable imaging apparatus may include one insertable imaging device that includes an array of integrated lateral imaging elements, and another insertable imaging device that includes an array of imaging elements that are oriented for forward-looking (end-fire) imaging.
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Some imaging elements may be contained in the outer access sheath, however most of the body of the imaging device will contain the imaging receivers and probes. By placing the imaging devices in close proximately to the surgical volume, a very high signal to noise ratio can be obtained for all modalities.
Understood is that a wide range of combinations of insertable MR imaging devices (probes, access ports, and imaging sleeves) may be employed without departing from the intended scope of the present disclosure. Many such combinations are described in Sections 1.5.1-1.5.5.
2.9 Example of Tested MR Imaging Probe Using Stripline GeometryReferring to
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An alternative example implementation of the MR imaging probe as then fabricated, having coil geometry as depicted in
The loop was formed with 14 gauge silver-coated copper wire and was electrically isolated from the stripline by a foam dielectric substrate. The 50-mm long stripline was formed with adhesive copper tape wrapped around a foam substrate. Both the stripline and stripline ground plane had a width of 10 mm. Non-magnetic capacitors were used to tune and match both coil elements. This combination of a stripline and a loop provided a 360-degree view of the tissue surrounding the port with a focus on the end-fire direction.
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In some embodiments, coil arrays may be employed as smart coils, where the coils are dynamically (adaptively) controlled, such that only a portion of the coil elements of the array are activated or interrogated during scanning. Understood is that the present “smart coil” embodiment pertain to any insertable MR imaging device having an array of coils, including insertable MR imaging probes, access ports with integrated coil arrays, imaging sleeves with integrated coil arrays, or combinations thereof, as described above.
In one example implementation, this may be achieved by an MR system that is configured to sample signals the elements of the coil array and to determine when a pre-selected signal level threshold has been achieved for each coil. When the threshold has been achieved for given coil, the coil are employed (e.g., activated or interrogated) for scanning. This arrangement allows an insertable MR imaging device to contain coils that are not necessarily orthogonal to the main magnetic field of the scanner.
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These signal values are then employed to determine which coil elements will be activated and which ones will remain off (or, which ones will be employed for constructing an image, and which will not).
In one example implementation, a criterion for determining which coils to activate or interrogate employs a threshold value, wherein, coils receiving signal levels that are below a certain value will remain off (or will not be interrogated) during signal acquisition.
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In some example methods, the signals from all coils should be sampled again after initially having determined a subset of coils to use. For example, the sampling may occur at a fixed time interval. Alternatively, the sampling may be based on a detected change in the orientation of the insertable MR imaging device within the B0 field, such as, a changed detected by a tracking system, or a change detected by an inertial sensor associated with the insertable MR imaging device, such as an accelerometer.
In some embodiments, the coils could be selectively activated or interrogated according to a number of criteria. For example, criteria may be based on the signal of one coil compared to some other statistical measure associated with the other coils, such as the average signal magnitude, or criteria based on the measure of signal to noise ratio, as opposed to signal strength. In another example embodiment, the signals to include could also be based on the orientation of the probe, as detected by a tracking system. The tracking system could be optical, RF, or accelerometer based (not claiming the tracking system in this patent). There could be a sensor such as a Hall sensor that is sensitive to the orientation of the static magnetic field.
2.11 Insertable MR Imaging Devices with Embedded Heating Elements
In some embodiments, an insertable MR imaging device, having an array of MR coils integrated therein, may further contain an array of heating elements, where the heating elements may be interspersed with coil array elements in order to generate thermal gradients during the imaging process. The heating and imaging cycles can be alternated to avoid interference between MR imaging elements and heating elements.
2.12 MR Imaging Probe with Magnet
Although the preceding insertable MR imaging embodiments have pertained to devices that employ the main magnet of an MRI scanner to generate the B0 field, some alternative embodiments may include a magnet within the insertable MR imaging device for providing the B0 field. Such devices may therefore be used outside of a conventional MRI scanner, since they are capable of generating their own B0 field.
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The outside of the permanent magnet is typically coated in a non-conductive coating. Therefore, the gradient wiring may be wound directly against the permanent magnet itself. Alternately, a spacer could be placed between the permanent magnet and the gradient coils. The gradient coils are used to generate spatially varying magnetic fields in directions orthogonal to the static magnetic field. In this case, one set of gradient coils generates a field in phi (angle, around the probe), and the other generates a field in z (along the probe). Each set of gradient coils would require an independent gradient amplifier. The final gradient, r, radially away from the permanent magnet, is achieved through the natural drop-off in magnetic field strength of a permanent magnet. Noted is that the gradients do not need to be perfectly linear, as long as they are known. Provided the spatial patterns of the gradient coils are well plotted, a modern reconstruction engine can undo any warping that occurs.
In order to reconstruct an image using a permanent magnet, the field of the permanent magnet, as well as the fields generated by the gradient coils would need to be accurately known. This could be generated through measurement, or through simulation. The method to reconstruct the image is the same as is currently used on modern MRI scanners. As long as the permanent magnet field is precisely known, there would not be a need to shim the magnet.
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Another example embodiment may employ a plurality of very small coil elements and physically move the coil in θ and z-directions, and use the change in signal over time to serve as the gradients for these directions.
In a further embodiment, no physical gradients are used. Instead, the motion of a transmit/receive coil is used to artificially generate the situation of a magnetic field varying in space. By arranging a set of transmit/receive coils around a probe, the motion required to successfully approximate physical gradients would be rotating motion, as well as motion in the z-direction, along the axis of the probe. Signal acquisition would take place at the same time as the probe motion. This embodiment uses the same magnet configuration as
This spatial information can be captured with a navigation system and relayed to the MR system. Again, the non-uniform B0 field is used for the r gradient. The physical movement of the coil can be achieved by moving the arm that is otherwise used to rigidly hold the coil in place. Consistent movement of the arm can be realized through automation of the arm to achieve consistent and constant movement along specific directions. Alternatively, the movement of the coil may be achieved by retracting the coil into the handle in a consistent manner while the handle is held rigidly in place by an external mechanical arm.
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Noted is that each gradient will require a separate gradient amplifier. The outside of permanent magnet is typically coated in a non-conductive coating. Therefore, the gradient wiring may be wound directly against the permanent magnet itself. Alternately, a spacer could be placed between the permanent magnet and the gradient coils. The gradient coils are used to generate spatially varying magnetic fields in directions orthogonal to the static magnetic field. In this case, one set of gradient coils generates a field in φ (angle, around the probe), and the other generates a field in θ (other angle around the magnet). The final gradient, r, radially away from the permanent magnet, is achieved through the natural drop-off in magnetic field strength of a permanent magnet. Noted is that the gradients do not need to be perfectly linear, as long as they are known. Provided the spatial patterns of the gradient coils are well plotted, a modern reconstruction engine can undo any warping that occurs.
Another example implementation involves the use of a plurality of very small coil elements such that their imaging area can be used to determine spatial encoding in the θ and φ directions while continuing to extrapolate from the non-uniform B0 field for the r gradient.
In another embodiment, a plurality of very small coil elements may be used in conjunction with physically moving the coil in the θ and φ directions, and use the change in signal over time to serve as the gradients for these directions. Once again, the non-uniform B0 field is used for the r gradient.
The coil array surrounding the magnet may be selected from the elements described within to generate and receive orthogonal B1 fields. The configurations may be used either with or without externally applied gradients as noted. In the latter scenario, the combination of the magnetic field pattern, B0, and the sensitivity profile of each element in the array may be used be to decode the spatial information in combination with the coil's physical position in space. As such, the port coil's movements may be tracked to provide z and θ (or θ and φ for a spherical system) data and the radial information can be extrapolated from the non-uniform B0 field.
2.13 Housing Material/Cannula Having a Susceptibility MapMagnetic susceptibility is a measure of how a material reacts to a magnetic field and is given by the equation M=χH where M is the magnetization and H is magnetic field. Susceptibility χ is related to magnetic permeability by the equation χ=μr−1. Although there is only a small susceptibility difference between Air (0.36E-6) and Water (−9.05E-6), this is enough to distort MR images, particularly diffusion weighted imaging (DWI) and the related diffusion tensor imaging (DTI). This distortion is particularly seen at the front of the brain, where the air of the sinuses causes a susceptibility difference in this area.
Typically, susceptibility induced distortions are ignored in MR, as they do not impact a radiologist's ability to read the scan. However, in an intraoperative setting, geometric accuracy can be of the utmost importance. Indeed, if an insertable MR imaging device is inserted into an access port, as described above, even if the insertable MR imaging device is formed from a non-magnetic material, the ability to perform geometrically accurate diffusion scans will be compromised if the insertable MR imaging device does not have a close susceptibility match to the brain.
Therefore, in some embodiments, insertable MR imaging devices are formed, at least in part, from a material having a susceptibility that is similar to that of the tissues being imaged, e.g., the tissues that reside adjacent to the insertable MR imaging device when it is inserted. A susceptibility that is similar to that of tissues is a susceptibility that differs from that of the tissue being imaged by approximately (−9.05E-6) which is similar to the range for water.
Examples of materials with a close susceptibility map to water (soft tissue in the body), which could be employed to fabricate an insertable MR imaging device, include nylon, silicon nitride, Teflon®, polysulfone, magnesia, steatite, carbon fiber composites, Vespel® (acetal), zirconia, plexiglass, PEEK, wood and copper. In the class of carbon fiber composites, one other material is pyrolytic graphite foam (PG Foam, described in ‘Pyrolytic Graphite Foam: A Passive Magnetic Susceptibility Matching Material’ by Lee et al, Journal of Magnetic Resonance Imaging 32:684-691 (2010)). Suitable materials for forming the shell of an insertable MR probe include polycarbonate, Teflon, and PEEK, and a suitable material for forming the dielectric portion within the body of an insertable MR probe is Teflon.
In one embodiment in which an access port is employed with one or more insertable MR imaging devices, such as an insertable MR imaging probe or an insertable imaging sleeve, the access port and the insertable MR imaging devices are formed, at least in part, from a common material that is susceptibility matched to the tissue being imaged.
Furthermore, as described in Section 1.1, the access port and an insertable MR imaging probe may be configured such that a close fit is achieved between the outer wall of the insertable imaging probe and the access port, thereby reducing the amount of air between the imaging probe and the access port. This avoids MR image distortion caused by differences in susceptibility between air, tissue, and the materials forming the access port and the insertable imaging probe.
Noted is that while large conductor sizes can cause eddy current problems in scanners, the size of the port in the embodiments considered herein is expected to be sufficiently small to avoid eddy current problems.
3. UltrasoundThe present section describes various embodiments employing one or more ultrasound (acoustic) transducers (ultrasound elements) for imaging within an access port, in order to achieve ultrasonic imaging within an internal area of interest.
As described above, some embodiments described in the present section may complement a minimally-invasive neurological procedures (such as surgical procedures) whereby a procedure involving internal brain tissue is conducted via a narrow corridor formed via an access port. For example, an insertable ultrasonic imaging device may be adapted to be received, e.g., slidable received, as described in Section 1 above, into the bore of an access port and exploit its close position to produce ultrasound images, such as ultrasound images of the surrounding (lateral) brain tissue and/or forward-looking (anterior, distal) tissues. Such images may be used during medical procedures, e.g., surgical procedures, potentially providing detail that would otherwise not be obtainable with current technologies (or would otherwise be obtainable with less resolution or signal to noise, using currently available technologies).
The ultrasound transducers may be provided within an insertable imaging device according to a number of different configurations. For example, in one example implementation, a single ultrasonic transducer may be employed (including a single ultrasonic transducer with multiple electrical connections to act as a phased array). In another example embodiment, an array of ultrasonic transducers may be provided within an insertable imaging device, such as a radial array spanning a radial segment of the insertable ultrasonic imaging device, or as an array of transducers with an opening at the center to enable access to distal tissue through an internal bore.
The ultrasonic elements of an ultrasound array may be realized using technologies, such as piezoelectric transducers. Understood, however, is that other solid-state transducers may alternatively replace the piezoelectric transducers.
In some embodiments, an array of ultrasound transducers may be arranged as a phased array to generate beams that may be swept in predetermined fashion. This can be realized using a transducer driver circuit that implements necessary signal processing capability.
An array of ultrasonic transducers may be arranged sparsely so that the tissue region beyond the distal end of the insertable ultrasonic imaging device may be clearly visible for visual inspection or for simultaneous imaging through the use of an additional imaging device, such as an external videoscope. The array of transducers may be sparsely arranged without compromising the ability to acquire a complete ultrasonic volume image by appropriately overlapping the fields of adjacent transducers. Transducer configurations may be realized, for example as described in “Configuration Optimization for a 2D Sparse Transducer Array for 3D Ultrasound Imaging”, Proc IEEE Ultrasound Symposium, 2010 Oct. 11; 2010:1928-1931.
Insertable ultrasonic imaging devices according to the embodiments described here may be, for example, an insertable ultrasonic imaging probe, an insertable ultrasonic imaging introducer for inserting an access port, an access port with one or more integrated ultrasonic transducers, one or more ultrasonic imaging sleeves that are configured to be coaxially inserted into an access port, or various combinations of these insertable imaging devices, as illustrated in Section 1. Various example implementations of such insertable ultrasonic imaging devices, and various ultrasonic transducer configurations, are described in detail below.
The ultrasonic transducer configurations presented below are provided as example and non-limiting implementations of potential configurations. Some of the following embodiments provide configurations that produce a forward-looking focused receiving or transmitting zone. In other words, some of the following embodiments provide transducer configurations that are sensitive to regions anterior to the longitudinal probe body (regions beyond the distal end of the probe body), e.g., in an end-fired configuration beyond the distal region of the body of the imaging probe. Such embodiments may be included or incorporated within the various imaging probes described within this disclosure.
3.1.1 Insertable Ultrasonic Imaging ProbesReferring to
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Wiring from the electrical connection layer provides the electrical connection to the ultrasound control system not located in or on the port. Non-limiting examples of this wiring may pass through the walls of the port through a conduit, or can be oriented on the inner or outer sides of the port, as well as be used in conjunction with a PCB or flexible PCB, etc. The wiring refers to any mechanism to transfer the electrical signals or information they carry generated by the ultrasound signals from the array to the ultrasound control system where it may be collected and analyzed.
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3.1.2 Access Ports and Imaging Sleeves with Integrated Ultrasonic Transducers
The preceding embodiments of Section 3 have disclosed various example insertable ultrasonic imaging probes and introducers. However, understood is that in alternative embodiments, one or more ultrasound transducers may be provided formed on or within, e.g., embedded or recessed within, an access port, or a sleeve that is insertable into an access port, as initially described in Sections 1.3 and 1.4.
In one embodiment, one or more ultrasonic transducers are formed on, or embedded within, an access port, thus providing a hollow imaging sleeve wherein instruments such as surgical tools can be inserted during a medical procedure. This provides an entry point for other imaging devices, image guided therapies, or contrast agent administration. This may include biopsy tools, deep brain stimulation devices, thermal imaging equipment, or ultrasound devices among others. Such embodiments are similar to the access ports with integrated MR coils, as disclosed in Section 2.6.
In other embodiments, an imaging sleeve with one or more integrated ultrasonic transducers may be provided, where the imaging sleeve is insertable into an access port, thereby providing a reconfigurable and optional means of port-based-imaging while still providing a central bore that provides access (direct or indirect) to internal tissues. This embodiment was introduced in Section 1.4, and is similar to the MR imaging sleeve embodiments disclosed in Section 2.6.
In one embodiment, one or more ultrasonic transducers are formed on, or embedded within, a sleeve that is slidably received within an access port, thus providing a hollow imaging sleeve wherein instruments such as surgical tools can be inserted during a medical procedure.
3.2 Embodiments with Combinations of Multiple Insertable Ultrasonic Imaging Devices
Finally, understood is that, as described in Section 1.5 (and in Sections 1.5.1-1.5.5), additional embodiments may be provided by combining two or more of the above insertable ultrasonic imaging devices.
For example, in one example implementation, an insertable imaging apparatus may include one insertable imaging device that includes an access port having an array of integrated laterally directed ultrasonic transducer elements, and an insertable imaging probe having an array of ultrasonic transducer elements that are oriented for forward-looking (end-fire) imaging.
4. Conductive Sensors for Local Resistance MapIn another embodiment, an additional measurement modality can be realized through the inclusion, on an insertable imaging device configured to contact the tissue, of an array of electrical sensors for the generation of a local resistance map. This is achieved by sensing the conductivity between pairs of conductors where the tissue forms part of the electrical circuit. By sharing one of the conductors, a map may be generated by measuring conductivity between a shared conductor and an array of complementary conductors that are individually addressable. The resulting measurements may be then used to construct a vector indicating the physical orientation of least resistance.
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Such measurement may be also extended to discerning bioelectric differences, so that presence of sufficient healthy tissue margin can be confirmed after resecting tumor tissue. For example, bulk of tumor tissue may be resected first and the above described tool may be introduced in the open cavity left after resection to assess the electrical characteristic of the tissue surface. The conductance measurement can be used to assess if the residual tissue left after resecting bulk of the tumor still contains tumor tissue. This inference technique is described in detail in “A Review of Parameters for the Bioelectrical Characterization of Breast Tissue,” Jacques Jossinet, Michel Schmitt, Annals of the New York Academy of Sciences, April 1999.
In another embodiment, a series of real-time sensing electrode arrays may be located on the introducer, where the sensing arrays record physiologic information as the access port is introduced into the tissue, or is repositioned within the patient.
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Insertable optical imaging devices according to the embodiments described here may be, for example, an insertable optical imaging probe, an insertable optical imaging introducer for inserting an access port, an access port with one or more integrated optical devices or channels provided therein, one or more optical imaging sleeves that are configured to be coaxially inserted into an access port, or various combinations of these insertable imaging devices, as illustrated in Section 1. Various example implementations of such insertable optical imaging devices are described in detail below.
5.1 Insertable Imaging Device with Integrated Optical Channels
The terms optical fiber and light guide can be used interchangeably in the following section. The optical fibers or light guides provide light delivery and/or collection from the tissue, with each fiber being purposed for illumination, light collection, or both. In addition, imaging could be performed using an insert optical imaging device comprising of a coherent array of fiber optics or light guides. In these configurations, each optical fiber or light guide provides a single illumination and/or collection measurement, which when combined with all other fibers or light guides provides a plurality of spatial measurements or an image.
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The acquisitions of measurements with vary illumination and detection geometries is used to construction a volumetric image of optical properties of the tissue (absorption, scattering, fluorescence, etc.), typically in a tomographic fashion. The multiple illumination and collection fibers or waveguides also form an ideal platform for multichannel or multiplexed optical coherence tomography (OCT). The acquisition of an OCT A-scan can be done through each fiber or light guide by either multiplexing using a single OCT detector, having detector for each fiber or light guide, or using spatially separated pixels or rows on an array or 2D detector. The fibers or light guides could also be used for excitation light for photoacoustic imaging (PA) if used in conjunction with an ultrasonic transducer to acquire the stimulated pressure wave, in this case the fibers or light guides would be used to delivery excitation light. More conventional optical imaging could also be performed using these fiber or light guide structures, particularly the insert coherent array where imaging is performed is a similar manner to conventional fiberscopes.
Beyond optical imaging modalities, these fiber or wave guide structures can be used for a wide variety of optical measurements either individually or as part of a multichannel systems. These measurements include, but are not limited to spectroscopy, NIR spectroscopy, Raman spectroscopy, surface enhanced Raman spectroscopy, stimulated Raman spectroscopy, and coherent anti-stokes Raman spectroscopy, fluorescence spectroscopy.
5.2 Insertable Optical Imaging Device with Integrated Optical Imaging Camera
In one example embodiment, a lower resolution video chip with an integrated lens may be placed as an insert to acquire local video information about the distal portion of the port. According to various example implementations, the optical imaging device may employ imaging modalities such as visible imaging, infrared imaging, e.g., near infrared imaging, hyperspectral imaging, and Raman Imaging.
5.3 Imaging Through a Conical Distal Portion of Introducer or Access PortReferring to
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All port-based surgical methods are limited by the amount of light that can be delivered to the tissue at the distal end of the port during surgical procedure. Introduction of tools occludes light delivery from externally placed light sources such as overhead surgical lamps. This limitation can be overcome as follows. Light energy can be projected onto the tissue via fiber bundles embedded in the walls of the port or by guiding the light through the port walls using total internal reflections within the wall. Light can be efficiently captured from an external light source using the ring located at the top of the port and then guided within the walls. Appropriately shaped lens can be fabricated along the top ring to maximize light capture and transmission to the inside of the port walls. A symmetrical lens will not be as efficient as a radially asymmetric lens fabricated or mounted on the top ring surface of the port.
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In one embodiment the device provides localized magnetic resonance images that enables parallel imaging protocols by way of multiple channel coil imaging, while also providing a means to enable additional imaging modalities such as ultrasound, optical imaging, hyperspectral imaging and photo acoustic imaging. This device can be inserted and/or re-inserted during imaging protocols to provide updated MR images of the area of interest during points of a surgical procedure. Noted is that in the case of embodiments involving multiple imaging modalities, the said modalities can be registered relative to each other since the respective transducers are located at fixed geometric locations relative to each other. Hence, image acquired in the first modality can be geometrically transformed to appropriately overlap with the image acquired using the second modality.
The following are further examples where multiple transducers can be used with multiple imaging modalities:
6.1 MR-ElastographySimilarly, the stiffness of various regions of the brain that are close to the port coil can be estimated using MR-elastography. This technique presents the elastographic data as an image map. In this embodiment, the conductive elements along the perimeter of the port can be interspersed with piezoelectric plates driven by a pulse generator that oscillates at approximately 300 Hz. The resulting vibration is transmitted to the tissue and relative movement of the tissue can be imaged via MR imaging techniques. Hence, a stiffness distribution of tissues in the vicinity of the port can be generated to identify presence of different tissue types. Use of this elastographic information to model tissue deformation is presented in PCT Patent Application No. PCT/CA2014 050243, titled “SYSTEM AND METHOD FOR DETECTING TISSUE, FIBER TRACT DEFORMATION,” and filed on Mar. 14, 2014, the entire contents of which is incorporated herein by reference.
6.2 Other Imaging Modalities Involving Excitation of TissueIn addition, proximity to the tissue, particularly in the case of the brain, providing access through the skull and, hence, enables a multitude of tissue excitation methods previously not anticipated or possible. For instance, one may provide a local audio vibrational excitation to allow for elastography imaging (using MRI, US or OCT), or provide for novel photo-acoustic excitation strategies, including direct excitation down the port, or through the patient's ear canals. In the case of elastographic imaging, the stiffness of the tissue can be measured as the device is being driven through the tissue and then displayed to the surgeon. As described previously, use of optical delivery paths in the port enable the use of optical measurements systems such as OCT for understanding elastographic property of local tissue and polarization imaging to visualize anisotropy of the tissue.
6.3 Insert Imaging Devices Including Mechanism of Infusing Contrast AgentsAdditional configurations embodiments of the distal portion of the insert component include the ability to infuse into the adjacent surface, a known concentration of contrast agent. In this way, a controlled delivery of fluids can be delivered to targets of interest in ways not previously allowed due to the presence of the blood-brain barrier. The infusion strategy can include, for example, a pre-saturated surface of contrast agent; an irrigation tube or array of tubes on the surface, that can deliver saline, contrast agent, or chemotherapy locally that allows for clearance of fluids (this allows for better distal surface imaging, as well as clearance of contrast agents to enable local bolus delivery of agents); an integrated suction device or array to remove fluids; or an activated array, that delivers agents only when activated (either by a touch probe, or interaction with the navigation system).
Such embodiments can be used to deliver a variety of contrast agents, such as MRI based contrast agents (gadolinium, iron-oxide particles, etc.), CT (Iodine), ultrasound (micro-bubbles), photodynamic contrast agents (gold spheres, carbon nanotube agents), PET (nuclear agents). Including biological bound contrast agents.
In addition, the concept can be extended to include chemotherapy agents. In the manner described above, specific locations within the port field of view can be indicated (either through navigation system or touch), and the chemotherapeutic agents can be delivered to those areas. In this way the systematic delivery of agents through the vascular system can be avoided. This provides the ability to deliver a high dose to an area of interest, as well as being able to delivery multiple agents to various regions. Fast acting chemo-therapy agents may also be flushed from the area.
To provide for even more accurate delivery of therapy, a combination of detection and treatment agent can be used, for instance photodynamic therapy. With the method described prior, localized delivery of agents can be performed, and an external light source can be used to activate the photo-sensitizing agent.
6.4 Bottom of Insert Component Having “Flat Transparent Surface Laden with Biochemical Assays”
In another embodiment, the distal portion of the insert component may be a flat transparent surface that is laden with biochemical markers arranged as a micro-array or as a binding surface with a single type of binding molecule. An embodiment of this may be a substrate (distal portion of port that is covered) that has specific receptors laid out in patterns. A non-limiting example of a receptor may be calcitonin receptor (reference: “The expression of calcitonin receptor detected in malignant cells of the brain tumor glioblastoma multiforme and functional properties in the cell line A172,” Wookey et. al., Histopathology, 2012 May, 60(6):895-910). The composition of the chemical assay shall be any of previously published biochemical means of differentiating tumor and healthy tissues. The selective binding of tumor cells or particles associated with them may be measured using an external video scope equipped with sensors sensitive to the appropriate wavelengths, e.g., Hyperspectral imaging at specific wavelength ranges. Alternatively, the binding surface may be illuminated using a technique similar to that described in (U.S. Pat. No. 7,314,749) to automatically identify selective binding of molecules and cells.
Referring to
Once the MR imaging probe has been inserted, it may be fixated to a mechanical arm for stability during imaging, or to the port cuff or surgical clamping device, or alternatively held in place manually. This port coil may form part of an overarching navigation system in which case the MR imaging probe's location will be tracked and recorded. The use of tracking system or vibration sensors located on the Imaging Probe can also enable detection of movement of the probe during measurement and appropriate compensation for motion artefacts introduced in the acquired data.
In addition, calibration elements may be included, as well as fiducials, to allow for accurate registration. Coupling this probe with a tracking, or position device will allow for 3D imaging reconstruction if the imaging planes of interests are known. Coupling this imaging device with external volumetric imaging systems (whole organ), will allow for a larger scale volumetric scan if needed (i.e. significant tissue removal or deflection during surgery).
Within the port coil, fiducial elements may be included for reference, navigation, or registration purposes. These fiducials may be T1 and/or T2 markers and are intentionally included within the imaging area of the MR probe. When the MR probe is used after the retraction of an introducer, the former component may be equipped with a pressure sensor at the tip so that a signal is generated when the port coil reaches the tissue surface. This signal can be translated into a warning signal to alert the surgeon that the port coil has reached the tissue surface and, hence, prevent application of excessive pressure on the tissue surface.
8. Use of Insert Imaging for Minimally Invasive ProceduresReferring to
Several stages of a minimally invasive procedure, including similar procedures applied to the brain, will benefit from the use of appropriate imaging modalities. Application of specific imaging techniques and their embodiments for surgical removal of brain tumors is explained in the next several sections.
Referring to
Referring back to
Referring to
In one embodiment, imaging contrast mechanisms that were acquired with a pre-operative imaging modality, will be able to be performed with the insert imaging modality, except with a higher performance (higher signal to noise, and/or higher resolution image). For instance, tissue anisotropy, water content, oxygen concentration, blood flow, tissue stiffness, etc.
8.2 Real-Time Imaging During Insert Process, Sulci-Based Port DeliveryIn some embodiments, the device may be configured to perform various multi-modal imaging combinations in real-time while it is being inserted. Imaging in this way allows for delivery of the insert device to the location of interest with updating imaging guidance. For example, the sulci may be detected as the device is inserted. These structures provide minimally invasive orifice access into the brain, and their distinctive folds and branch points can provide a means to navigate to the point of interest. In addition, unique patterns of vessels can be used as internal landmarks. Most neurosurgical applications do not plan the delivery of the tracked devices along a specific trajectory, but rather a only target to a point—in the application of sulci-based port delivery, the trajectory is also important so as to minimize the white matter trauma of the patient.
Upon successful navigation, the body of the imaging device can then be removed, while leaving the rigid tube structure in place to allow for surgical access to the tissue. The outer sleeve can be inserted using the introducer through the sulci and subsequent retraction of the introducer. The inner imaging array can be inserted at any time to allow for re-imaging of the tissue.
8.3 Surgical Planning-Craniotomy/Incision GuidanceThe first stage of surgery generally involves utilizing images of the whole head, in order to determine the location of the diseased tissue, the minimally invasive access corridors, and the structures that need to be avoided (vessels, white matter tracts).
Typically a pre-operative scan (done on a previous day) has been done using MRI or CT, that allows for diagnosis of the tissue, and visualization of the critical structures in a single scan. If multiple scans are required (MRI and CT), they are registered using a variety of strategies. In some cases, intra-operative scanning (at the time of surgery) may be performed, before the incision is made into the head, which could provide for more accurate surgical guidance information as it is acquired at the time of the surgery. Current systems do not provide for high performance imaging intra-operatively either due to limited performance coils of MRI hardware.
Alternatively, a localized coil may be used to image the region of interest that is important, for instance, the quadrant of the brain for which the incision is planned. Until the skull is opened in surgery, it is expected that the brain position would be substantially similar to the position in which it was in for pre-operative imaging, however once a piece of the skull is removed, the brain will swell outside of the skull, where it has been documented the shift of the brain at that point could exceed 1 cm.
Therefore quadrant, or whole head imaging done pre or post skull resection addresses the following concerns: differences in patient position and general brain condition (brain sagging or swelling); pathologies causing shifts and displacements—i.e. growth of the tumor, fluid build-up, internal bleeding since pre-operative imaging; brain shift due to skull opening-craniotomy (smaller with burr-hole; poor tissue differentiation—higher resolution local imaging (higher acquisition matrix can be addressed when imaging a smaller volume of interest); the need to provide better visualization of tumor close to surface for better surgical planning and compressed gyms to locate sulcus for sulcus based approaches; and poor differentiation of sulci, nerves and tumor pre-operatively—focused local imaging will provide better imaging locally (higher resolution, better contrast, better defined nerve fibers (more angular acquisitions, thinner slices); reduced brain shift due to large craniotomy—better located craniotomy and smaller dura opening reduces brain shift; and more accurate location of head supports (pinning) based on more accurate intraoperative plan (reduce head trauma associated with poor head pinning).
Imaging may be performed using a whole head coil array, a quadrant array, or by positioning a port coil close to the entrance of the skull. In addition, according to embodiments disclosed herein, after the skull has been resected, MRI imaging can be done using the insert coil, US imaging can be done through the burr-hole, or surface imaging can be done through the dura using an external optical imaging system (photo acoustic imaging has been shown to image sulci through the skull and dura, where US will permit imaging through the dura, and can adequately visualize sulci with a high frequency probe (upwards of 7 MHz).
MRI imaging can be directly registered to the pre-operative MRI images, or alternatively the structure of the gyms, or blood vessels in the area may be used to register to pre-operative structures. If the visualization of the sulci is difficult to determine before the craniotomy or dura opening, additional sequences may be acquired at the discretion of the surgeon.
8.4 Guidance of Access PortReferring to
Imaging at a smaller field of view (less than 6 cm, 1 cm close to tumor), a faster temporal resolution (approaching 30 fps), and higher resolution that is more appropriate to insertion of a port into the brain (less than 1 mm to resolve sulci), will address the following problems at this stage of the procedure: travelling down an incorrect sulcus corridor; traversing or puncturing the sulcus; traversing or puncturing critical banks of grey and white matter; puncturing/shearing or cutting a blood vessel; mis-targeting or displacing the tumor; avoiding moving off of pre-planned navigated pathway; navigating past nerves in real-time, i.e. taking a non-linear pathway; measuring tissue stiffness to minimize tissue mechanical trauma; measuring tissue state-measuring electrical activity and/or measuring tissue oxygenation and/or tissue pH, and/or tissue anisotropy.
Expected is that the introduction of the port, and introducer will displace a significant amount of tissue internally, as well as displace the folds of the sulci as it is pushed into the brain. For tissues that are stiffer than the surrounding brain tissue, for instance some clots/hematomas, cellular tumors, there will be an expected internal shift of tissue as the introducer pushes against the tissue.
In one embodiment, this displacement can be predicted with accurate simulation, using a priori tissue stiffness information, geometric knowledge of the introducer and port, a biomechanical model of tissue deformation, (using the skull as a boundary condition) and using pre-operative imaging data. This model can be updated using real-time imaging information as the introducer is positioned inside of the head, and more accurately if real-time imaging is performed using the in-situ port. For instance, real-time ultrasound imaging done on the tip of the port, can detect tissue stiffness inside the brain. This information can be used instead of the priori-predicted stiffness, and can provide a better estimate of tissue movement. In addition, ultrasound can be used to identify sulci patterns as the port is being introduced. These sulci patterns can be matched to the pre-operative sulcus patterns, and a deformed pre-operative model can be generated based on this information.
Alternatively, the port can be guided based on the actual real-time imaging from the port. In the most basic form is the use of an optical path to the bottom of the port by way of a set of glass fibers, or a clear path with a lens at the bottom that is aligned with an external camera (as described in a related patent application—see below). Alternatively a combination of an optical lens, and a plurality of US elements could be used. In this combination the US elements may be mechanically scanned, or focused appropriately to image forward and sideways, thus providing an optical and US image in real-time. Alternatively, or in addition, photo-acoustic imaging may be used with an external laser excitation, and receiving using the ultrasound elements. Alternatively, or in addition, OCT may be used to measure local tissue structure, Doppler imaging, or in-combination with photo-acoustic imaging. For the purpose of guiding the port into position, there should be at least a 1 cm forward field of view for imaging. Optimally the field of view would be larger when inserting into the sulcus, and when approaching the tumor, it would be reduced, and the imaging resolution is increased.
Expected is that a discrepancy exists between the pre-operative imaging data, and the real-time port information (US, OCT, photo acoustic, optical). This can be measured by matching sulci patterns, blood vessel positions, or by quantifiable common contrast mechanisms such as elastic modulus, tissue anisotropy, blood-flow, etc. The real-time port information would be expected to represent the truth, and when there is a significant discrepancy, a scan would be done to update the volumetric MRI and/or CT scans to update the pre or intraoperative scanning volume. In the optimal configuration, an MRI port coil would be used in conjunction with an external MRI system to acquire a 3D volume demonstrating sulci path, tumor, nerve fascicles by way of DTI acquisition, and blood vessels. As the acquisition time is typically much longer than US, OCT or photo-acoustic imaging, it is not expected to be used as a real-time modality, however it can be effectively utilized as a single modality to position the access port with pseudo-real time capability (typically not faster than 1 fps).
Alternatively sensors on the outside surface of the port, can measure quantifiable physical measures, such as electrical conductivity/resistivity, stress/strain, temperature in real-time. This provides valuable physiologic information pertaining to the forces applied to the nerve fibers, the port (and associated tissues), and the nerve activations. This real-time physiologic information can be used to ascertain tissue conditions around all surfaces of the port.
8.5 De-Bulking of Diseased Tissue and Precision Zone ResectionReferring to
The objective at this point is to establish a pattern of tissue resection, bleeding management, and port alignment so as to remove the maximum amount of diseased tissue, while, minimizing trauma to surrounding tissue. This will be done in conjunction with clearing the margins of the tumor, where the diseased tissue comes into contact with normal brain tissue.
The process involves a multi-resolution approach to resection of tissue at a coarse resolution with coarse tools (for instance using scissors, forceps, tissue ablation, suction or large volume aspiration cutting tool setting) in combination with real-time imaging, (external video scope feed), and fine resection using shaving tools (for instance small volume aspiration cutting tool, or small focus laser ablation), in combination with high resolution imaging (high resolution focused external video scope, tool based OCT, tool based spectroscopy, tool based US, tool based photo acoustic). In each case, the imaging resolution, and field of view is appropriately sized to the surgical implement.
Imaging in this manner allows the following issues to be addressed: healthy to diseased tissue differentiation in vivo; visualization of blood vessels to better manage bleeding and cauterization; imaging of nerves in vivo to avoid their resection/damage; tracking of pathology samples to known imaging properties (currently not possible in any surgical or radiology system); and assessing the state of grey matter/white matter in-vivo.
Referring to
However, as the surgery processes, this volume becomes a less accurate representation of the actual tumor, margin and surround tissue position. In order to achieve a more accurate local representation, a new volume representing the local region of interest can be acquired. For instance, an MRI port coil can be introduced into the coil and a 3D volume may be acquired (approximately 2 cm volume). In addition, a scan of the volume can be accomplished using high-frequency ultrasound (5 mm-2 cm), OCT (2-3 mm), or photo-acoustic imaging (variable field of view with resolution, therefore 2 cm to 2 mm).
Referring to
In addition, Raman spectroscopic probes can be used to gather chemical information relating to the tissue, and the multiple imaging signatures of resected tissue can be recorded and tracked relative to specific surgical resection samples. This information will be important to select the appropriate margin treatment protocols, and help to identify tissue types relative to other tissues in the same patient, or between patients.
One aspect of the present disclosure is the ability to use the distal surface of the port, or any imaging devices inserted into the port to immobilize tissue. This is demonstrated in
Current surgical procedures are limited by the inability to image at a very fine resolution, provide fine tissue contrast, and provide tools to selectively resect small areas of tissue, or small populations of cells. The use of microscopes can be effective at the surface of the brain, but in deep tissue, or tissue with pulsatile flow, this is not possible. In addition, current tools, or the precision of the surgeon's hand with a scalpel is limited to >400 micrometers. Relative to the novel imaging modalities immerging, where resolutions of 10's of micrometers are achievable, this degree of surgical resection control is not sufficient. Even using traditional lasers at this scale is impractical with a zone of damage >800 micrometers.
Referring to
Referring to
Understood is that the more of the tumor volume is resected, the more effective secondary treatment strategies can be, to provide more localized cellular level therapy. These therapies include radiation therapy and chemotherapy. As with surgical approach, these therapies also follow the premise that the more healthy tissue is spared, the better the patient's recovery and longer-term functional outcomes. A fundamental limitation to this is the ability to do high resolution imaging at the margins of the tumor, and high-resolution therapy delivery in conjunction. Combining the two and delivering therapy in-vivo through a port device, provides surface access and imaging, the expected patient outcomes would be significantly improved.
Combining therapy and imaging in such a manner may be overcomes fundamental issues with plaguing therapy today: movement of tissue within body on the order of 2-5 mm from pulsatile flow, respiration limits fundamental therapy delivery; skull and sensitive brain tissue makes margins inaccessible; chemotherapies have been ineffective due to blood-brain barrier and non-selective killing mechanism; radiation therapy has been ineffective due to cell killing mechanism, inaccuracies of delivery, tissue differentiation, and collateral damage; high-frequency ultrasound cannot focus well through the brain; laser ablation cannot limit collateral damage; photodynamic therapy inability to access tissue, and tissue delivery through the blood-brain barrier.
By providing localized access to tissues of interest, and de-bulking the diseased tissue to a small region and depth through a multi-resolution imaging and resection approach, the problem of localized margin treatment can be more effectively managed in-vivo. In fact, the ability to administer imaging contrast agents, externally activated therapy agents, locally targeted biological agents, and local chemotherapy agents are available. The ability to use surface imaging techniques, particularly with external imaging sources such as the automated external imaging system, and specialized external laser ablative sources provides a means to treat residual disease at a level finer than a surgeon's scalpel.
8.7 Closure VerificationReferring to
In some instances devices to assist in tissue recovery, such as chemotherapy delivery devices, or stem cell delivery devices may be left in the cavity, or in the sulcus folds of the brain. In the case of neuro-stimulation devices, the ability to image inside of the brain can enable predicting whether the anticipated surgical outcome will occur (for instance, Hall effect imaging with MRI, or local DTI to visualize nerve fiber integrity). Insert imaging may be done as the port is withdrawn, and after the dura is closed. Additional imaging may be used, in conjunction with navigation tip tracing, and external optical imaging, to define the appropriate geometry of bone flap and craniotomy closure hardware. A final scan may be required to validate there is no internal bleeding or excessive swelling after the surgeon has completed.
In some of the embodiments presented herein, an insert imaging device is provided that allows for image acquisition using one or more multiple modalities, and optionally the ability to acquire images at various resolutions. Such a device may enable the acquisition of images using one of the following possible configurations, (or combinations of configurations) through the surgical port:
1. Imaging of the distal end of the surgical port using an externally placed imaging device such as an external video scope, stand-off Raman sensor or hyper-spectral imager.
2. Imaging of the walls and the distal end of the surgical port through the use of sensors or sensor arrays placed in an insert in the port. This data may be used to construct 3D volume at high resolution due to proximal placement of sensors to areas of interest.
3. Image or analyze specific points on the exposed tissue located at the distal end of the port using touch sensors such as Raman probes, conductance measurement probes (or arrays), spectrometer-on-a-chip located at the tip of surgical tools or assay-based bio-chemical sensors. Any of the touch probes can be also tracked by attaching the touch probes, such as a Raman probe, to a holding assembly that also includes fiducial markers. Such tracking of the touch probe enables the association of measured data with exact location in the brain where such data was collected.
The device may be used in conjunction with therapeutic approaches, where the improved access afforded by the access port provides for better imaging, and better bi-manual access to the tissue and better therapeutic delivery. The therapeutic mechanism may be integrated into the insert imaging array, or located externally as shown in
Examples of surgical and therapeutic fields that may be impacted by the present disclosure include: imaging and navigation used in surgery; intraoperative tumor removal and critical structure detection; accessing brain regions via the skull base, removal of deep seeded tumors and stem cell detection; placement of probes and devices for deep brain stimulation, shunts, implantable devices; vascular brain defect surgery, Intra-cerebral hemorrhage (ICH); surgical procedures to address neurodegenerative disease (Parkinson's, Alzheimer's, Huntington's, Dystonia, Major Depression, OCD, Epilepsy, Brain Tumor); and access to inner brain regions via various access ports to the brain.
8.8 Robotic PositioningNoted is that at each stage of the surgery where guidance of devices, instruments, lasers, or surgical tools are performed, the means of delivery and guidance of said devices may be performed by a human operator, a human-assisted robotic delivery, or a closed loop robotic guidance/delivery of the instruments. The insert imaging array concept can be utilized to augment robotic, or semi-automatic delivery of tools by way of improved dynamic imaging, and/or static imaging with immobilization. Examples of robotic positioning systems and methods are provided in PCT Patent Application No. PCT/CA2014/050271 titled “INTELLIGENT POSITIONING SYSTEM AND METHODS THEREFORE” and filed on Mar. 14, 2014, the entire contents of which is incorporated herein by reference.
8.9 Surgical Workflow (Methods)The utility of the present disclosure may be employed at a multitude of stages of surgical intervention. While pre-operative imaging is used to guide the decision on incision location, local imaging is used to guide the port along the sulci. This may be realized through ultrasound, MR, or OCT imaging modalities. Such images help identify potential risk of deviating from the sulci and potentially severing nerve bundles. The surgical region of interest may be identified through any of the tissue differentiation modalities such as MR, OCT, ultrasound and Raman spectroscopy. The diseased tissue is then de-bulked and any bleeding may be managed by preventing the excess fluid from occluding the image. Impact of glare and excessive fluid in the image can be minimized through selective filtering achieved through Hyper-spectral imaging, NIR imaging and OCT.
Subsequent to de-bulking of tumor mass, selective regions may be identified through probe-based Raman spectroscopy or assay-based chemiluminescence achieved through the use of appropriate chemical probes at the distal portion of the insert component in the port. Presence of healthy tissue margin after resection of tumor may be confirmed through the use of bio-electric sensors located at the distal portion of the insert probe. Upon confirmation that all tumor regions have been removed, the port may be closed and external video scope based imaging may be used to check for bleeding immediately below the dermis.
In
The specific embodiments described above have been shown by way of example, and it should be understood that these embodiments may be susceptible to various modifications and alternative forms. It should be further understood that the claims are not intended to be limited to the particular forms disclosed, but rather to cover all modifications, equivalents, and alternatives falling within the spirit and scope of this disclosure.
Claims
1. An imaging system for performing intraoperative imaging during a minimally invasive medical procedure involving an access port, the imaging system comprising at least one of at least one imaging sleeve and at least one imaging probe, each at least one of the at least one imaging sleeve and the at least one imaging probe comprising:
- a hollow cylindrical body configured to be slidably and removably received within an inner lumen of the access port;
- at one imaging element integrated with, and supported by, said hollow cylindrical body, the at one imaging element positioned for imaging through the access port, the at one imaging element comprising at least one ultrasound transducer, and the at one imaging element configured to image by a modality comprising ultrasound imaging;
- at least one externally accessible connector disposed near a proximal region of the hollow cylindrical body; and
- at least one connection channel integrated with the hollow cylindrical body for supporting signal transmission between the at least one externally accessible connector and the at one imaging element.
2. The system of claim 1, wherein the at one imaging element comprises an imaging array.
3. The system of claim 1, wherein the at one imaging element is oriented to perform lateral imaging through at least one side wall of the access port.
4. The system of claim 1, wherein the hollow cylindrical body has a distal end and further comprises a window, the window enclosing the distal end, and wherein the at one imaging element is integrated with the window for imaging a distal region of interest.
5. The system of claim 1, wherein the at one imaging element further comprises at least one of: at least one magnetic resonance imaging coil; at least one optical focusing element; at least one optical imaging element; and at least one other ultrasound imaging element.
6. The system of claim 1, wherein the at one imaging element is configured to image by at least one other imaging modality of optical coherence tomography, hyper-spectral imaging, polarized light imaging, Raman Imaging, fluorescence Imaging, electrophysiology, computerized tomography, spectral x-ray, photo-acoustic imaging, positron emission tomography, thermal imaging.
7. The system of claim 1, further comprising at least one tracking marker.
8. The system of claim 1, wherein each at least one imaging sleeve is configured to slidably and removably receive another at least one imaging sleeve, and wherein each at least one imaging sleeve is contemporaneously nestable in relation to receive another at least one imaging sleeve within the access port during a medical procedure.
9. The system of claim 1, wherein the access port comprises an inner lumen, and wherein the inner lumen is configured to slidably and removably receive the at least one imaging sleeve.
10. A method of providing an imaging system for performing intraoperative imaging during a minimally invasive medical procedure involving an access port, the imaging system comprising at least one of at least one imaging sleeve and at least one imaging probe, the method comprising:
- providing at least one of at least one imaging sleeve and at least one imaging probe, providing the at least one of the at least one imaging sleeve and the at least one imaging probe comprising providing each at least one of the at least one imaging sleeve and the at least one imaging probe with:
- a hollow cylindrical body configured to be slidably and removably received within an inner lumen of the access port;
- at one imaging element integrated with, and supported by, said hollow cylindrical body, the at one imaging element positioned for imaging through the access port, the at one imaging element comprising at least one ultrasound transducer, and the at one imaging element configured to image by a modality comprising ultrasound imaging;
- at least one externally accessible connector disposed near a proximal region of the hollow cylindrical body; and
- at least one connection channel integrated with the hollow cylindrical body for supporting signal transmission between the at least one externally accessible connector and the at one imaging element.
11. The method of claim 10, wherein providing the at one imaging element comprises providing an imaging array.
12. The method of claim 10, wherein providing the at one imaging element comprises orienting the at one imaging element to perform lateral imaging through at least one side wall of the access port.
13. The method of claim 10, wherein providing each at least one of the at least one imaging sleeve and the at least one imaging probe with the hollow cylindrical body comprises: providing the hollow cylindrical body with a distal end and a window; and enclosing the distal end with the window, and wherein providing the at one imaging element comprises integrating the at one imaging element with the window for imaging a distal region of interest.
14. The method of claim 10, wherein providing the at one imaging element further comprises providing at least one of: at least one magnetic resonance imaging coil; at least one optical focusing element; at least one optical imaging element; and at least one other ultrasound imaging element.
15. The method of claim 10, wherein providing the at one imaging element comprises configuring the at one imaging element to image by at least one other imaging modality of optical coherence tomography, hyper-spectral imaging, polarized light imaging, Raman Imaging, fluorescence Imaging, electrophysiology, computerized tomography, spectral x-ray, photo-acoustic imaging, positron emission tomography, thermal imaging.
16. The method of claim 10, wherein providing each at least one imaging sleeve comprises configuring each at least one imaging sleeve to slidably and removably receive another at least one imaging sleeve, and wherein providing each at least one imaging sleeve comprises configuring each at least one imaging sleeve to contemporaneously nest in relation to receive another at least one imaging sleeve within the access port during a medical procedure.
17. The method of claim 10, wherein providing each at least one of the at least one imaging sleeve and the at least one imaging probe with the hollow cylindrical body comprises providing the access port with an inner lumen, and wherein providing the access port with the inner lumen comprises configuring with the inner lumen to slidably and removably receive the at least one imaging sleeve.
18. A method of performing intraoperative imaging during a minimally invasive medical procedure involving an access port by way of an imaging system, the imaging system comprising at least one of at least one imaging sleeve and at least one imaging probe, the method comprising:
- providing the imaging system, providing the imaging system comprising providing at least one of at least one imaging sleeve and at least one imaging probe, providing at least one of at least one imaging sleeve and at least one imaging probe, providing the at least one of the at least one imaging sleeve and the at least one imaging probe comprising providing each at least one of the at least one imaging sleeve and the at least one imaging probe with: a hollow cylindrical body configured to be slidably and removably received within an inner lumen of the access port; at one imaging element integrated with, and supported by, said hollow cylindrical body, the at one imaging element positioned for imaging through the access port, the at one imaging element comprising at least one ultrasound transducer, and the at one imaging element configured to image by a modality comprising ultrasound imaging; at least one externally accessible connector disposed near a proximal region of the hollow cylindrical body; and at least one connection channel integrated with the hollow cylindrical body for supporting signal transmission between the at least one externally accessible connector and the at one imaging element; and
- intraoperatively imaging at least one portion of a patient by employing at least one of the at least one imaging sleeve and the at least one imaging probe.
19. The method of claim 18,
- wherein providing the at one imaging element comprises at least one of: providing an imaging array; orienting the at one imaging element to perform lateral imaging through at least one side wall of the access port; configuring the at one imaging element to image by at least one other imaging modality of optical coherence tomography, hyper-spectral imaging, polarized light imaging, Raman Imaging, fluorescence Imaging, electrophysiology, computerized tomography, spectral x-ray, photo-acoustic imaging, positron emission tomography, thermal imaging, integrating the at one imaging element with the window for imaging a distal region of interest,
- wherein providing each at least one of the at least one imaging sleeve and the at least one imaging probe with the hollow cylindrical body comprises at least one of: providing the hollow cylindrical body with a distal end and a window; and enclosing the distal end with the window, configuring each at least one imaging sleeve to slidably and removably receive another at least one imaging sleeve; and configuring each at least one imaging sleeve to contemporaneously nest in relation to receive another at least one imaging sleeve within the access port during a medical procedure, and
- wherein providing the at one imaging element further comprises integrating the at one imaging element with the window for imaging a distal region of interest,
- wherein providing each at least one of the at least one imaging sleeve and the at least one imaging probe with the hollow cylindrical body comprises providing the access port with an inner lumen, and
- wherein providing the access port with the inner lumen comprises configuring with the inner lumen to slidably and removably receive the at least one imaging sleeve.
20. The method of claim 18, wherein providing the at one imaging element further comprises providing at least one of: at least one magnetic resonance imaging coil; at least one optical focusing element; at least one optical imaging element; and at least one other ultrasound imaging element.
Type: Application
Filed: Mar 3, 2021
Publication Date: Mar 17, 2022
Applicant: SYNAPTIVE MEDICAL INC. (Toronto)
Inventors: Cameron Piron (Toronto), Michael Wood (Toronto), Murugathas Yuwaraj (Toronto), Alex Panther (Toronto), Nishanthan Shanmugaratnam (Toronto), William Lau (Toronto), Monroe M. Thomas (Toronto), Gal Sela (Toronto), Joshua Richmond (Toronto), Wes Hodges (Toronto), Simon Alexander (Toronto), David Gallop (Toronto)
Application Number: 17/190,897