Technical Field
Embodiments disclosed herein are related to improved visualization for vitreo-retinal, glaucoma, or other ophthalmic surgeries. More specifically, embodiments described herein relate to a movable wide-angle ophthalmic surgical system that can be implemented as a diagnostic imaging system and/or a treatment beam delivery system.
Related Art
Developing techniques to assist ophthalmic surgery with imaging and visualization is one of the hottest areas of development and innovation. One class of ophthalmic surgeries, the vitreo-retinal procedure, involves vitrectomy, the removal of the vitreous body from the posterior chamber to access the retina. The successful execution of vitrectomy requires an essentially complete removal of the vitreous, including the most challenging regions near the vitreous base. Using imaging techniques and devices can be of substantial help to improve the efficiency of the vitreous removal.
However, assisting vitrectomy with imaging is particularly challenging for several reasons. One of them is that the vitreous is transparent. Another challenge is that visualization of the periphery requires imaging beams with a high angle of obliqueness. Wide angle contact-based or non-contact based lenses are commonly used to address the latter challenge, with only limited success. There are many other reasons that surgeons need to have a wider field of view into the eye in vitreoretinal surgeries, such as for retinal break detection, photocoagulation, etc. Wide-angle contact based lenses can reach approximately 120° field of view, while non-contact based lenses offer an even narrower field of view. Sometimes, surgeons have to rotate the patient's eyeball or perform sclera depression to move the eye into the microscope field of view for observation.
Improvement of the imaging can be achieved by using optical coherence tomography (OCT), a technique that enables visualization of the target tissue in depth by focusing a laser beam onto the target, collecting the reflected beam, interfering the reflected beam with a reference beam and detecting the interference, and measuring the reflectance signature within the depth of focus of the beam. The result is a line scan in depth, a cross-sectional scan, or a volumetric scan.
OCT has become common practice in the clinic as a diagnostic tool. Surgeons take pre-op images into the operating room for reference. OCT scanning is currently not available in the operating room, and thus does not support decision making during surgery. Pre-op images have limited utility following morphologic modifications to the target during a procedure.
Efforts to develop real-time intra-surgical OCT systems are being made by multiple companies ranging from startups to large corporations. The approaches to intra-surgical OCT to date have been microscope-based, handheld probe-based, or endoprobe-based. Microscope-based OCT systems have conventionally mounted the OCT system to the microscope with a fixed orientation with respect to the microscope and/or a patient's eye. Accordingly, integrating OCT into standard surgical microscopes can require substantial modifications of the microscope. Further, even with these modifications, the scanning angle and/or the target location of the OCT beam into the eye is fixed and limited. Moving the patient and/or microscope, both of which can be impractical or infeasible, are the only options for change the scanning angle and/or the target location of the OCT beam.
The presented solution fills an unmet medical need with a unique solution to provide movable wide-angle diagnostic imaging and/or treatment beam delivery system intra-surgically, without surgical overhead or disruption to the surgical workflow, with an adjustable beam scanning/delivery angle and/or location in the eye to maximize usability.
Consistent with some embodiments, an ophthalmic surgical system comprises: at least one light source, configured to generate a light beam; a beam guidance system, configured to guide the light beam from the at least one light source; a beam scanner, configured to receive the light from the beam guidance system, and to generate a scanned light beam; a beam coupler, configured to redirect the scanned light beam; and a wide field of view (WFOV) lens, configured to guide the redirected scanned light beam into a target region of a procedure eye; wherein the beam coupler is movably positioned relative to the procedure eye such that the beam coupler is selectively movable to change at least one of an incidence angle of the redirected scanned light beam into the procedure eye and the target region of the procedure eye.
Consistent with some embodiments, a method of operating a surgical optical coherence tomography (OCT) visualization comprises: generating an imaging light beam using a light source; guiding the imaging light beam from the light source to a beam scanner using a beam guidance system; generating a scanned imaging light beam using the beam scanner; redirecting the scanned imaging light beam using a beam coupler, including redirecting the scanned imaging light beam into the optical pathway of a surgical microscope; guiding the redirected scanned imaging light beam into a target region of a procedure eye using a wide field of view (WFOV) lens; and selectively moving the beam coupler to change at least one of an incidence angle of the redirected scanned imaging light beam into the procedure eye and the target location of the procedure eye.
Additional aspects, features, and advantages of the present disclosure will become apparent from the following detailed description.
In the drawings, elements having the same designation have the same or similar functions.
In the following description specific details are set forth describing certain embodiments. It will be apparent, however, to one skilled in the art that the disclosed embodiments may be practiced without some or all of these specific details. The specific embodiments presented are meant to be illustrative, but not limiting. One skilled in the art may realize other material that, although not specifically described herein, is within the scope and spirit of this disclosure.
The real-time, intra-surgical, adjustable wide-field of view imaging systems of the present disclosure provide numerous advantages relative to microscope-based OCT systems, including (1) reduced complexity of usage with a large number of different surgical microscopes; (2) optical access to large variety of laser scanning visualization techniques; and (3) wider scan angles, including the ability to scan in the periphery of the eye, by permitting rotational and translation motion that changes the incidence angle and/or incidence location of the scanning beam in the eye. The real-time, intra-surgical, adjustable wide-field of view imaging systems of the present disclosure also provide numerous advantages relative to handheld probe-based OCT systems, including (1) hands-free imaging; (2) simplified surgical workflow; (3) more stabilized OCT imaging with fewer motion related artifacts; and (4) simultaneous OCT imaging and microscope observation. The real-time, intra-surgical, adjustable wide-field of view imaging systems of the present disclosure also provide numerous advantages relative to endoprobe-based OCT systems, including (1) non-invasive OCT imaging; (2) simplified surgical workflow; (3) volume scan ability; (4) more stabilized OCT imaging with fewer motion related artifacts; (5) improved lateral resolution; and (6) the ability to be combined with surgical microscope imaging. Many similar advantages can be realized using the real-time, intra-surgical, adjustable wide-angle treatment beam delivery systems of the present disclosure.
The ophthalmic surgical system of the present disclosure can be configured to facilitate delivery of intra-surgical, adjustable wide angle laser scanning via a movable beam coupler. The beam coupler, together with one or more optical elements, can be part of an integrated optical block component. The entirety of the optical block can be rotated or translated, or the beam coupler can be rotated independent of the optical block. A wide-field of view for laser scanning can be provided as selective movement of the beam coupler changes the angle of incidence of the scanning beam into the eye and/or the incidence location of the scanning beam in the eye. The movable wide-angle ophthalmic surgical system can be implemented as diagnostic imaging system(s) such as optical coherence tomography (OCT), multispectral imaging, fluorescence imaging, photo-acoustic imaging, etc., as well as treatment beam delivery system(s) for laser treatment such as photocoagulation. The wide-angle laser scanning can be diagnostic and/or therapeutic in nature. Diagnostic laser scanning can include optical coherence tomography (OCT) imaging. For example, such a system may provide adjustable, wide-field intra-surgical OCT without disrupting the surgical workflow. The treatment laser scanning can include laser beam scanning. The scanning beam can be delivered into the eye through a contact based or non-contact based surgical lens. If non-visible laser wavelengths are used, then the contact lens can also serve as a standard surgical contact lens. A non-contact WFOV lens can be implemented in a manner similar to a binocular indirect ophthalmomicroscope (BIOM). Coupled with a real-time acquisition and display system, the diagnostic imaging and/or treatment beam delivery system can improve intra-surgical visualization. Further, the diagnostic imaging and/or treatment beam delivery system can be operable independent of a microscope, and can even be used without a microscope. The diagnostic imaging and/or treatment beam delivery system can also be coupled to a stereoscopic camera viewing system as a microscope replacement technology and/or a surgical guidance technology for surgical robots or remote surgical systems.
The diagnostic imaging and/or treatment beam delivery system 100 can include a beam guidance system, including an optical fiber 106 and/or free space, configured to guide the light beam from the light source 104. The diagnostic imaging and/or treatment beam delivery system can include a collimator 136 that is configured to receive the light beam from the beam guidance system and collimate light.
The diagnostic imaging and/or treatment beam delivery system 100 can include an optical beam scanner 138 configured to receive the light beam from the collimator 136 and/or the beam guidance system, and generate a scanned light beam 146. For example, the beam scanner 138 can be configured to receive the diagnostic light beam from the beam guidance system and to generate a scanned diagnostic light beam. The beam scanner 138 can be configured instead or additionally to receive the treatment light beam from the beam guidance system and generate a scanned treatment light beam. The beam scanner 138 can be configured to generate the scanned light beam 146 having any desired one-dimensional or two-dimensional scan patterns, including a line, a spiral, a raster, a circular, a cross, a constant-radius asterisk, a multiple-radius asterisk, a multiply folded path, and/or other scan patterns. The beam scanner 138 can include one or more of a pair of scanning mirrors, a micro-mirror device, a MEMS based device, a deformable platform, a galvanometer-based scanner, a polygon scanner, and/or a resonant PZT scanner.
The diagnostic imaging and/or treatment beam delivery system 100 can also include a beam coupler 142 configured to redirect the scanned light beam 146 towards a wide field of view (WFOV) lens 120 configured to guide the redirected scanned light beam into a target region 124 of a procedure eye 122. The target region 124 can include the retina, macula/fovea, optic disk, vitreous body, and/or trabecular meshwork/Schlemm's canal. The diagnostic imaging and/or treatment beam delivery system 100 can be configured to image these and other particular regions-of-interest with higher resolution.
The diagnostic imaging and/or treatment beam delivery system 100 can also include a surgical microscope 108 (
The beam coupler 142 can be configured to redirect the scanned light beam 146 into the optical pathway 116 of the surgical microscope 108. To redirect the scanned light beam 146 into the target region 124 of the procedure eye 122 and/or the optical pathway 116 of the surgical microscope, the beam coupler 142 can include a mirror. As shown in
The beam scanner 138 and/or the optical block 102 can also include focusing optics for defining a depth of focus of the scanned light beam 146. For example, one or more lenses 140 can be included within the optical block 102 (
The lens(es) 140 can be adjusted by a zoom-controller to adapt an optical power of the diagnostic imaging and/or treatment beam delivery system 100 to the desired target region 124 of the procedure eye 122. Further, the adjustable zoom lens(es) 140 can be controlled by the zoom-controller in real-time to adapt the optical power of the diagnostic imaging and/or treatment beam delivery system 100 to keep an aberration below a predetermined value as the scanned light beam 146 scans across the target region 124 of the procedure eye 122. In that regard, the zoom-controller can control each adjustable zoom lens 140 by adjusting a physical position of the zoom lens 140 (e.g., using piezo-electric or other suitable actuators) and/or adjusting an optical power of the zoom lens 140 without adjusting the physical position of the zoom lens 140 (e.g., by varying a voltage supplied to a liquid crystal zoom lens).
In some embodiments, the diagnostic imaging and/or treatment beam delivery system 100 can include a visible guidance beam, such as when the scanned light beam 146 is outside of the visible range. For example, the scanned light beam 146 can be in the infrared range. As shown in
Referring again to
The beam coupler 142 and/or the optical block 102 can be operated with or without a defined optical/optomechanical relationship to the surgical microscope 108. For example, the beam coupler 142 or the optical block 102 can be maintained separate from and independently positionable relative to the surgical microscope 108. In such instances, the beam coupler 142 can be a hand-held device, a lens holder, a self-stabilized component or other component. As shown in
Referring again to
Referring again to
The WFOV lens 120 can be configured to operate in contact with the procedure eye 122, as a contact lens, or spaced from the procedure eye 122, as a non-contact lens. As shown in
As shown in
The light source 104, the beam guidance system, and the beam scanner 138 can be part of an optical coherence tomographic (OCT) imaging system. To that end, the WFOV lens 120 and the beam coupler 142 can be configured to guide a returned image light from the target region 124 of the procedure eye 122 back to the OCT imaging system. The returned image light can be interfered with a reference beam of the OCT imaging system, and from the interference an OCT image of the target region in a range of depths can be generated and displayed to a user. The diagnostic imaging and/or treatment beam delivery system can be configured to generate the imaging information based on processing the returned image light in less than 30 seconds, less than 10 seconds, and/or less than 5 seconds, including in real time. A single scanned light beam 152 or A-scan is shown in
Selective movement of the beam coupler 142 and/or the optical block 102 can be configured to provide a field of view of the procedure eye 122 greater than 15 degrees, greater than 30 degrees, greater than 45 degrees, greater than 60 degrees, greater than 80 degrees and/or greater than 100 degrees. Accordingly, the diagnostic imaging and/or treatment beam delivery system 100 can be configured to provide various field of view ranges, such as between 0 degrees and 30 degrees, between 15 degrees and 80 degrees, between 30 degrees and 120 degrees, and/or other desired ranges up to ora serrata.
In some embodiments, the optical block 102 can be movable with one, two, three, four, five, six, or more degrees of freedom. For example, the optical block 102 can have one, two, three, or more rotational degrees of freedom. A first rotational degree of freedom can be about an axis 128 or z-axis (
A second rotational degree of freedom can be about an axis 132 or y-axis (
A third rotational degree of freedom can be about an axis 130 or x-axis (
For example, the optical block 102 can have one, two, three, more translational degrees of freedom. A first translational degree of freedom can be along the axis 128. As shown in
A second translational degree of freedom can be along the axis 132. As shown in
A third translational degree of freedom can be along the axis 130. As shown in
In some embodiments, movement of the optical block 102 can include only rotation or only translation. In some embodiments, movement of the optical block 102 can include both rotation and translation. The optical block 102 can be rotated about and/or translated along one or more of the axes 128, 130, and 132 to provide an adjustable wide field of view for the diagnostic imaging and/or treatment beam delivery system 100. The optical block 102 can be translated in one or more directions and then rotated in one or more directions, or vice versa, in order to direct the scanned light beam 146 into the target region 124 (and prevent the scanned light beam 146 from encountering interference with, e.g., the iris). For example, the optical block 102 can be moved based on the visible guidance beam (
In some embodiments, the beam coupler 142 can be rotatable relative to the procedure eye 122 and/or the microscope 108. Rotation of the beam coupler 142 can be independent of movement of the optical block 102. In that regard, rotation of the beam coupler 142 can be utilized to facilitate full circumferential scanning of the procedure eye 122 and/or to target a particular region of interest within the procedure eye 122. The beam coupler 142 can be rotatable about the axis 132 (
In some embodiments, moving the beam coupler (step 260) can include rotating the beam coupler. For example, the beam coupler 142 can be rotated about at least of one of a first axis, a second axis, and a third axis (e.g., axes 132, 128 and 130). In some embodiments, moving the beam coupler (step 260) can include rotating the optical block about at least one of a first axis, a second axis, and a third axis (e.g., axes 128, 130, and 132) and/or translating the optical block along at least one of the first axis, the second axis, and the third axis (e.g., axes 128, 1302, 132). In some embodiments, the method 200 can include repeating the moving step to generate imaging information associated with different incidence angles and/or different target locations in the procedure eye and combining the imaging information associated to generate combined imaging information. For example, OCT data can be generated at various incidence angles and/or target locations. The OCT data from the individual angles and/or target locations can be combined or stitched together through one or more processing steps to generate OCT data for a wider field of view (e.g., a cross-sectional and/or volumetric scan). For example, a treatment beam can be delivered to various incidence angles and/or target locations.
Embodiments as described herein can provide devices, systems, and methods that facilitate real-time, intra-surgical, adjustable wide-angle beam scanning for diagnostic imaging and/or treatment beam delivery. The examples provided above are exemplary only and are not intended to be limiting. One skilled in the art may readily devise other systems consistent with the disclosed embodiments which are intended to be within the scope of this disclosure. As such, the application is limited only by the following claims.
Number | Name | Date | Kind |
---|---|---|---|
6902326 | Ames | Jun 2005 | B1 |
8403921 | Palankar | Mar 2013 | B2 |
20080212738 | Gertner | Sep 2008 | A1 |
20090257065 | Hauger et al. | Oct 2009 | A1 |
20100324543 | Kurtz | Dec 2010 | A1 |
20110202044 | Goldshleger et al. | Aug 2011 | A1 |
20120092615 | Izatt et al. | Apr 2012 | A1 |
20120274900 | Horn et al. | Nov 2012 | A1 |
20130096543 | Palanker et al. | Apr 2013 | A1 |
20130141695 | Buckland et al. | Jun 2013 | A1 |
20130194581 | Yoshida | Aug 2013 | A1 |
20130231644 | Hanft et al. | Sep 2013 | A1 |
20130235343 | Hee | Sep 2013 | A1 |
20130278898 | Kato | Oct 2013 | A1 |
20140107634 | Vogler | Apr 2014 | A1 |
20140125952 | Buckland et al. | May 2014 | A1 |
20150018645 | Farkas | Jan 2015 | A1 |
20150230702 | Uhlhorn | Aug 2015 | A1 |
Number | Date | Country |
---|---|---|
103251382 | Aug 2013 | CN |
103314270 | Sep 2013 | CN |
2815694 | Dec 2014 | EP |
2012166116 | Dec 2012 | WO |
Entry |
---|
International Search Report and Written Opinion issued for PCT/US2014/071153, dated Mar. 31, 2015, 11 pgs. |
Number | Date | Country | |
---|---|---|---|
20160008169 A1 | Jan 2016 | US |