阅读说明：本技术 用于多点激光探针的多芯光纤 (Multi-core optical fiber for multi-point laser probe ) 是由 刁晨光 A·米尔斯帕西 R·T·史密斯 M·H·法利 D·理查森 于 2018-12-12 设计创作，主要内容包括：本披露涉及一种多芯光纤缆线(MCF)。在一些实施例中,MCF包括被包层环绕的多个芯以及环绕所述包层的涂层,其中,所述多个芯中的一个或多个芯的折射率大于所述包层的折射率。所述MCF进一步包括探针,所述探针包括与所述MCF的远端联接的探针尖端；以及位于所述探针尖端的远端处的透镜。在一些实施例中,所述透镜被配置用于将激光束从所述MCF的远端平移以在目标表面上产生激光束多点图案；并且所述MCF的远端在与所述透镜的界面处终止。(The present disclosure relates to a multicore fiber cable (MCF). In some embodiments, an MCF includes a plurality of cores surrounded by a cladding and a coating surrounding the cladding, wherein a refractive index of one or more of the plurality of cores is greater than a refractive index of the cladding. The MCF further includes a probe including a probe tip coupled with a distal end of the MCF; and a lens located at a distal end of the probe tip. In some embodiments, the lens is configured to translate a laser beam from a distal end of the MCF to create a laser beam multi-spot pattern on a target surface; and the distal end of the MCF terminates at an interface with the lens.)

1. A multi-spot laser probe comprising:

a probe body shaped and sized for grasping by a user;

a probe tip comprising a cannula configured to be inserted into an eye;

a graded-index GRIN lens disposed in the cannula at a distal portion thereof;

a multi-core fiber optic cable (MCF) extending at least partially through the cannula, the MCF comprising:

a plurality of cores formed of germanium-doped silica;

a cladding formed of fused silica, the cladding surrounding the plurality of cores, one or more of the plurality of cores having a refractive index greater than a refractive index of the cladding;

a coating surrounding the cladding; and

a distal end disposed at an interface with the GRIN lens, a portion of the coating omitted from a length of the distal end of the MCF, and the GRIN lens configured to translate laser light from the distal end of the MCF to produce a laser beam multi-spot pattern on a target surface.

2. The multi-point laser probe assembly of claim 1, wherein the plurality of cores form a 2X2 array configured to match a 2X2 multi-point pattern from a Diffractive Optical Element (DOE) of a laser system.

3. The multipoint laser probe assembly of claim 2, wherein a distal end of the MCF abuts the GRIN lens at the interface at a positive pressure.

4. The multipoint laser probe assembly of claim 2, wherein a distal end of the MCF is separated from the GRIN lens by an air gap.

5. The multi-spot laser probe according to claim 1, wherein the portion of the coating removed from the MCF has a length in a range of 0.5mm to 5.0mm extending proximally from the distal end of the MCF.

6. The multi-spot laser probe according to claim 5, wherein the portion of the coating removed from the MCF has a length in a range of 0.1mm to 3.0mm extending proximally from the distal end of the MCF.

7. The multi-spot laser probe of claim 1, further comprising:

a second cladding surrounding the cladding, the second cladding comprising a polymer, wherein the coating surrounds the second cladding, the coating comprising a polymer.

8. A multi-spot laser probe comprising:

a multi-core fiber optic cable (MCF) including a plurality of cores surrounded by a cladding and a coating surrounding the cladding, wherein a refractive index of one or more of the plurality of cores is greater than a refractive index of the cladding;

a probe comprising a probe tip coupled with a distal end of the MCF; and

a lens located at a distal end of the probe tip, wherein:

the lens is configured to translate a laser from a distal end of the MCF to create a laser beam multi-spot pattern on a target surface; and

the distal end of the MCF terminates at an interface with the lens.

9. The multi-point laser probe assembly of claim 8, wherein:

the coating comprises a polyimide coating;

the plurality of cores comprise germanium-doped silica; and

the cladding comprises fused silica.

10. The multi-spot laser probe according to claim 8, wherein a portion of the coating in the range of 1.0mm to 3.0mm is omitted from a length of the distal end of the MCF.

11. The multi-point laser probe assembly of claim 8, wherein the plurality of cores form a 2X2 array configured to match a 2X2 multi-point pattern from a Diffractive Optical Element (DOE) of a laser system.

12. The multipoint laser probe of claim 8, wherein the probe tip comprises a cannula configured to be inserted into an eye, and wherein the distal end of the MCF and the lens are disposed in the cannula.

13. The multipoint laser probe of claim 8, wherein the lens comprises a graded index GRIN lens, and wherein a distal end of the MCF abuts the GRIN lens at a positive pressure.

14. The multipoint laser probe of claim 8, wherein the lens comprises a graded index GRIN lens, and wherein a distal end of the MCF is separated from the GRIN lens by a void.

15. The multi-spot laser probe of claim 8, further comprising:

a second cladding surrounding the cladding, the second cladding comprising a polymer, wherein the coating surrounds the second cladding, the coating comprising a polymer.

Technical Field

The present disclosure relates to a multi-point laser probe, and more particularly to a system and method for delivering a multi-point laser beam via a surgical probe having a multi-point fiber optic cable.

Background

In a wide variety of medical procedures, lasers are used to assist in surgery and to treat the anatomy of a patient. For example, in laser photocoagulation, a laser probe is used to cauterize blood vessels at various laser cauterization points on the retina. Certain types of laser probes burn multiple spots at a time, which can allow for faster and more efficient photocoagulation. Some of these multi-spot laser probes split a single laser beam into multiple laser beams exhibiting a laser spot pattern and deliver these beams to a fiber array exhibiting a corresponding fiber pattern. Typically, the fibers should be closely packed so that the fiber pattern matches the laser dot pattern. Furthermore, the laser spot pattern should be accurately aligned with the fiber pattern.

In addition to cauterizing blood vessels at the laser cauterization site, the laser may also damage the rod and cone cells present in the retina that provide vision, thereby affecting vision. Since vision is most acute at the central macula of the retina, the surgeon arranges the laser probe to create laser cautery spots in the peripheral region of the retina. In this way, some peripheral vision can be sacrificed while central vision is preserved. During surgery, the surgeon drives the probe with the non-cauterizing aiming beam so that the area of the retina to be photocoagulated is illuminated. Due to the availability of low power red laser diodes, the aiming beam is typically a low power red laser. Once the surgeon has positioned the laser probe to illuminate the desired retinal spot, the surgeon activates the laser via a foot pedal or other means and then photocoagulates the illuminated area. After cauterizing the retinal spot, the surgeon repositions the probe to illuminate a new spot with aiming light, activates the laser, repositions the probe, and so on until the desired number of cauterized laser spots are distributed on the retina.

For diabetic retinopathy, a whole retinal photocoagulation (PRP) procedure may be performed, and the number of laser photocoagulations required for PRP is typically large. For example, typically 1,000 to 1,500 dots are cauterized. Thus, it can be readily appreciated that if the laser probe is a multi-point probe capable of simultaneously cauterizing multiple points, the photocoagulation process will be faster (assuming sufficient laser source power). Accordingly, multi-spot/multi-fiber laser probes have been developed and described in U.S. patent nos. 8,951,244 and 8,561,280, the entire contents of which are incorporated herein by reference.

Vitreoretinal surgery also benefits from directing illumination light into the eye and onto retinal tissue. Vitreoretinal surgeons typically use laser probes to deliver laser aiming and treatment beams, and also use additional instruments to direct illumination beams onto the retinal surface to view the patient's anatomy.

Disclosure of Invention

According to one embodiment, the present disclosure relates to a multi-spot laser probe, the probe comprising: a probe body shaped and sized for grasping by a user; a probe tip comprising a cannula configured to be inserted into an eye; a graded index (GRIN) lens disposed in the cannula at a distal portion thereof; and a multi-core fiber optic cable (MCF) extending at least partially through the cannula. The MCF may include: a plurality of cores formed of germanium-doped silica; forming a cladding from fused silica; a coating surrounding the cladding; and a distal end disposed at an interface with the GRIN lens. The cladding may surround the plurality of cores. One or more of the plurality of cores may have a refractive index greater than a refractive index of the cladding. A portion of the coating may be omitted from a length of the distal end of the MCF, and the GRIN lens may be configured to translate laser light from the distal end of the MCF to create a laser beam multi-spot pattern on a target surface.

Another embodiment relates to a multi-spot laser probe comprising a MCF and a probe, the MCF comprising a plurality of cores surrounded by a cladding and a coating surrounding the cladding. The probe can include a probe tip coupled to a distal end of the MCF. The multi-point laser probe may also include a lens located at a distal end of the probe tip. The lens may be configured to translate a laser from a distal end of the MCF to create a laser beam multi-spot pattern on a target surface. The distal end of the MCF may terminate at an interface with the lens. One or more of the plurality of cores may have a refractive index greater than a refractive index of the cladding.

Further embodiments relate to a method for applying a multi-spot laser beam pattern. The method may include: generating a laser beam by a laser source; collimating the laser beam; directing the collimated laser beam to a Diffractive Optical Element (DOE) configured to generate a multi-spot laser pattern of the laser beam; and focusing the laser beam multi-spot pattern into an interface plane of the proximal end of the MCF. Each laser beam in the multi-spot laser pattern of laser beams may be transmitted into one of the cores of the MCF. The laser beam may propagate along a core of the MCF. The plurality of cores may be surrounded by a cladding, and the cladding may be surrounded by a coating. Each of the plurality of cores may have a refractive index greater than a refractive index of the cladding, and a portion of the coating may be omitted from a length of the distal end of the MCF. The method can further include transmitting the laser beam multi-point pattern to a distal end of the MCF and directing the laser beam multi-point pattern through a lens to a distal end of a surgical probe.

Various embodiments of the present disclosure may include one or more of the following features. The plurality of cores may form a 2X2 array, which may be configured to match a 2X2 multi-point pattern from a Diffractive Optical Element (DOE) of a laser system. A distal end of the MCF may abut the GRIN lens at the interface at a positive pressure. The distal end of the MCF may be separated from the GRIN lens by an air gap. A portion of the length of the coating may be removed from the MCF, and the length may be in a range of 0.5mm to 5.0mm extending proximally from the distal end of the MCF. The portion of the coating removed from the MCF may have a length in a range of 1.0mm to 3.0mm extending proximally from the distal end of the MCF.

Various embodiments of the present disclosure may also include one or more of the following features. A portion of the coating may be omitted from a length of the distal end of the MCF. The length of the coating omitted from a length of the distal end of the MCF may be in a range of 1.0mm to 3.0 mm. The plurality of cores may form a 2X2 array configured to match a 2X2 multi-point pattern from a Diffractive Optical Element (DOE) of a laser system. The lens may comprise a GRIN lens and the distal end of the MCF may abut the GRIN lens at a positive pressure. The lens may comprise a GRIN lens, and the distal end of the MCF may be separated from the GRIN lens by a gap. The probe tip may include a cannula configured to be inserted into an eye. The distal end of the MCF and the lens may be disposed in the cannula. A portion of the coating may be omitted at the MCF, thereby improving the power handling characteristics of the multi-spot laser probe. The lens, which may be located at a distal end of the probe tip, may comprise a GRIN lens. The distal end of the MCF may abut the GRIN lens at a positive pressure. The distal end of the MCF may be separated from the GRIN lens by an air gap. The coating may comprise a polyimide coating. The plurality of cores may include germanium-doped silica. The cladding may comprise fused silica.

Drawings

For a more complete understanding of the present technology, its features and advantages, reference is made to the following description taken in conjunction with the accompanying drawings, in which:

fig. 1 illustrates an exemplary system for generating a laser beam multi-point pattern for delivery to a surgical object, in accordance with certain embodiments of the present invention.

Fig. 2 illustrates an exemplary multi-spot laser probe according to certain embodiments of the present invention.

Fig. 3 and 4 illustrate one end of an exemplary multi-core fiber optic cable (MCF) for use with a non-illuminated multi-point laser probe, in accordance with certain embodiments of the present invention.

Figure 5 illustrates one end of an exemplary MCF for use with an illuminated multi-point laser probe, in accordance with certain embodiments of the present invention.

Fig. 6 is a partial cross-sectional detailed view of a distal portion of an exemplary multi-point laser probe tip according to certain embodiments of the invention.

Fig. 7A-7F 2 illustrate various aspects of a multi-point/multi-fiber laser probe compared to aspects of an MCF laser probe to highlight various advantages and benefits of a multi-core fiber cable laser probe, in accordance with certain embodiments of the present invention.

Fig. 8 illustrates exemplary operations performed by a surgical laser system, in accordance with certain embodiments of the present invention.

Fig. 9 illustrates a distal portion of an exemplary multi-spot laser probe operable to generate a laser beam multi-spot pattern in accordance with certain embodiments of the invention.

Fig. 10 illustrates a distal portion of another exemplary multi-spot laser probe in which a lens having a convex end is disposed between the distal end of the MCF and the protective window, according to certain embodiments of the invention.

Fig. 11 is a side view of an exposed end of an exemplary multi-spot laser probe showing the alignment of the exposed end of the MCF with the lens, in accordance with certain embodiments of the present invention.

Figure 12 shows the exposed end of the MCF misaligned with the lens due to the annular gap formed between the MCF and the inner wall of the cannula.

Figure 13 illustrates a ring disposed within an annular void formed around an inner cladding of an MCF at an exposed end of the MCF, according to certain embodiments of the invention.

FIG. 14 illustrates a cannula including a countersink of another exemplary multi-point laser probe, in accordance with certain embodiments of the present invention.

Fig. 15 illustrates an exemplary multi-spot laser probe, wherein alignment of the exposed end of the MCF is provided by the reduced inner diameter of the cannula, in accordance with certain embodiments of the present invention.

Fig. 16 illustrates the potential risk of damage to the distal end of the MCF during assembly, in accordance with certain embodiments of the present invention.

Figures 17 and 18 illustrate the formation of a necked-down portion of a cannula of an exemplary multi-point laser probe for maintaining alignment of the distal end of the MCF with the lens, according to certain embodiments of the invention.

Fig. 19 illustrates exemplary operations for producing a multi-spot laser probe, in accordance with certain embodiments of the present invention.

Detailed Description

In the following description, details are set forth by way of example in order to facilitate understanding of the disclosed subject matter. However, it will be apparent to those of ordinary skill in the art that the disclosed embodiments are exemplary and not exhaustive of all possible embodiments. Accordingly, it should be understood that reference to the described examples is not intended to limit the scope of the disclosure. Any alterations and further modifications in the described devices, apparatus, and methods, and any further applications of the principles of the disclosure as described herein are contemplated as would normally occur to one skilled in the art to which the disclosure relates. In particular, it is fully contemplated that the features, components, and/or steps described for one implementation may be combined with the features, components, and/or steps described for other implementations of the present disclosure.

The present disclosure describes illuminated and non-illuminated multi-core laser probes and systems and methods associated therewith. Fig. 1 illustrates an exemplary system 100 for generating a laser beam multi-spot pattern according to some embodiments.

The system 100 includes a surgical laser system 102 that includes one or more laser sources for generating a laser beam that may be used during ophthalmic surgery. For example, the ophthalmic surgical laser system 102 may alternatively generate a surgical treatment beam having a first wavelength (e.g., about 532 nanometers (nm)) and a laser aiming beam having a second wavelength (e.g., about 635 nm). A user, such as a surgeon or surgical staff, may control the surgical laser system 102 (e.g., via foot switch, voice command, etc.) to alternately emit a laser targeting beam and a treatment beam to treat a patient's anatomy, such as to perform photocoagulation. In some cases, the surgical laser system 102 may include a port, and the laser beam may be emitted through the port in the surgical laser system 102. The surgical laser system 102 may include a laser system port adapter containing optics (not shown) for generating a laser beam multi-spot pattern with a laser beam from a laser source.

The system 100 may deliver the multiplexed optical beam from the port to the surgical probe 108 via a multi-core fiber optic cable (MCF) 110. The probe 108 may generate a laser beam multi-spot pattern to be delivered to the retina 120 of the patient's eye 125. The probe 108 includes a probe body 112 that houses and protects the MCF 110 and a probe tip 140. The distal portion 145 of probe tip 140 also contains a lens (not shown, described in more detail below) that translates the multiplexed light beam from the distal end of MCF 110 onto retina 120.

A number of different systems and methods may be employed to create the laser beam multi-point pattern and multiplex the laser beam multi-point pattern with the illumination beam. In some cases, the port adapter may contain optical elements operable to generate a multi-drop pattern and/or multiplex the light beams. In some implementations, the surgical laser system 102 can further include a female chimney port (not shown), and the port adapter can include a ferrule that serves as a male coupling for the female chimney port. The ferrule may include an opening to allow laser light from the surgical laser system 102 to enter, and one or more optical elements to collimate the laser light received from the laser source. In some examples, the optical element in the ferrule may be a graded index (GRIN) lens whose length and pitch are selected such that the optical element collimates laser light received at the opening of the ferrule at a selected distance adjacent to a Diffractive Optical Element (DOE). In other examples, the optical element may be one of several other types of lenses (e.g., spherical, aspherical, biconvex glass, etc.). The DOE may focus the laser beam multi-point pattern into an interface plane at the proximal end of the MCF such that each laser beam in the multi-point laser pattern of laser beams propagates along the entire length of a selected core of a plurality of cores contained within the MCF to the distal end of the surgical probe.

In operation, the laser source of the surgical laser system 102 generates a laser beam. The collimating optics in the surgical laser system 102 collimate laser light directed to a diffractive optical element configured to generate a multi-spot laser pattern of a laser beam. The multi-point laser pattern is then directed to a condenser lens and focusing optics of the surgical laser system 102 to focus the multi-point pattern onto an interface plane of the proximal end of the MCF such that each of the multi-point laser pattern of laser beams propagates along the entire length of a selected core of the plurality of cores contained within the MCF 110. The laser beam multi-spot pattern is transmitted by the MCF 110 to a probe 108 disposed at a distal end of the MCF 110. The laser beam multi-spot pattern exits the MCF 110 and is transmitted through a lens at the distal portion 145 of the probe 108. The laser beam multi-point pattern exiting probe 108 may be projected onto retina 120 of eye 125.

Fig. 2 illustrates an embodiment of probe tip 140 of fig. 1 in more detail. As described above, the stylet 108 includes a stylet body 112 shaped and sized for grasping by a user. Extending from the probe body 112 is a probe tip 140 that includes a cannula 251 and a cannula 250. As shown, the cannula 250 is partially received by the sleeve 251 and extends beyond its distal end. In the illustrated example, the probe tip 140 includes a straight portion 216 (e.g., a straight portion of the cannula 251 and the cannula 250) and a curved portion 218 (e.g., a curved portion of the cannula 250). In other implementations, probe tip 140 may have other shapes. For example, in some cases, probe tip 140 may be perfectly straight, include more than one curved portion, be perfectly curved, or be shaped in any desired manner.

Probe tip 140 may be formed from one or more materials including, for example, stainless steel, titanium, nitinol, and platinum. In some examples, a first portion (e.g., straight portion 216) of probe tip 140 may comprise a first material and a second portion (e.g., curved portion 218) of probe tip 140 may comprise a second material. In some cases, the first material may be different from the second material. For example, in some cases, the first material may comprise stainless steel, such as tubular stainless steel, and the second material may comprise nitinol, such as tubular nitinol. A distal portion 145 of probe tip 140 may be inserted into the eye to perform a surgical procedure.

Fig. 3 and 4 illustrate the distal end of an exemplary MCF300 (e.g., similar to MCF 110) from different angles. MCF300 includes a plurality of cores 302 disposed in a cladding 304, which may be formed of fused silica. The laser light sources discussed above, such as the laser light provided by the surgical laser system 102, may be split into multiple beams. Each bundle is directed into one of the cores 302 of the MCF 300. Thus, each core 302 directs one of the beams along the length of the MCF 300. In some implementations, these cores 302 may be composed of, for example, germanium-doped silica, and cladding 304 may be composed of fused silica, such that laser light traveling along core 302 is contained within core 302 and prevented from escaping from core 302 into cladding 304. For example, the refractive index of one or more cores 302 may be greater than the refractive index of cladding 304.

Although four cores 302 are shown in the illustrated example, the scope of the present disclosure is not so limited. Rather, in other implementations, MCF300 may include fewer cores 302, while other implementations may include more than four cores 302. In some implementations, the MCF300 may include two, four, or more inner cores 302, and in some examples, these cores 302 may form a 2x2 array that matches a 2x2 multi-point pattern generated by a diffractive optical element that may be disposed in a surgical laser system, such as the surgical laser system 102. A coating 306 is formed on the cladding 304. In some cases, the coating 306 may be a polyimide coating. In other cases, the coating 306 may be formed from other materials, such as acrylates. In some implementations, the refractive index of the coating 306 can be greater than, less than, or equal to the refractive index of the cladding 304.

In certain embodiments, each core 302 may have a diameter of about 75+/-2 μm, cladding 304 may have an outer diameter of about 295+/-5 micrometers (μm), and coating 506 may have an outer diameter of about 325+/-5 μm. In certain embodiments, the centers of two adjacent cores 302 may be about 126+/-5 μm from each other, and the distance between the centers of two cores 302 that are diagonal with respect to each other may be about 178+/-5 μm.

In fig. 3 and 4, MCF300 is a non-illuminated MCF. That is, while each core 302 is adapted to conduct light, such as laser light, the cladding 304 itself is not used to conduct light for general illumination at the treatment site.

Fig. 5 shows an example of an illumination MCF, shown as MCF 500. MCF500 includes a plurality of cores 502 disposed in an inner cladding 504, which may be formed of fused silica. These cores 502 function similarly to the cores 302 described above. Although four cores 502 are shown in the illustrated example, the scope of the present disclosure is not so limited. Rather, in other implementations, MCF500 may include fewer cores 502, while other implementations may include more than four cores 502. In some implementations, the MCF500 may include two, four, or more inner cores 502, and in some examples, these cores 502 may form a 2x2 array that matches a 2x2 multi-point pattern generated by a diffractive optical element that may be disposed in a surgical laser system, such as the surgical laser system 102. An outer cladding 506 is formed on the inner cladding 504. MCF500 also includes a coating 508 formed on the outer cladding 506. The coating 508 may refer to an outer jacket. In some cases, the outer cladding 504 and the coating 508 may be formed of a polymeric material.

An illuminated MCF is one that transmits light for general illumination (as opposed to targeted laser light for treatment) through the MCF's cladding to provide general illumination at the treatment site. Thus, the inner cladding 504 may be used to transmit light therealong to provide general illumination at the treatment site (as opposed to a laser used for treatment). In illuminating the MCF500, the refractive index of the outer cladding 506 can be less than the refractive index of the inner cladding 504. The outer cladding 506 (which may be a hard silica cladding) may be formed from a polymeric material that may be unstable at high temperatures. Accordingly, a portion of the outer cladding 506 may be stripped or otherwise removed from the MCF500 near the interface with the lens (e.g., about 0.5 to 5mm), as described below, to improve the power handling capability of a probe including the MCF 500. In certain embodiments, the removal of the coating 508 is measured from the distal end of the MCF500 to a length of about 50 millimeters (mm). This length may correspond to the length of a cannula (e.g., cannula 250). The coating 508 may be removed to allow the MCF500 to fit into a cannula because the MCF500 may have an outer diameter that is larger than the inner diameter of the cannula when the coating 508 is thereon.

In certain embodiments, the diameter of each core 502 may be approximately 75+/-2 μm, the outer diameter of the inner cladding 504 may be 295+/-5 μm, the outer diameter of the outer cladding 506 may be 325+/-5 μm, and the outer diameter of the coating 508 may be 425+/-30 μm. In certain embodiments, the centers of two adjacent cores 502 may be approximately 126+/-5 μm from each other, and the distance between the centers of two cores 502 that are diagonal to each other may be approximately 178+/-5 μm.

Fig. 6 is a partial cross-sectional detail view of distal portion 145 of probe tip 140 shown in fig. 2. Note that the distal portion 145 of the probe tip 140 may also be a distal portion of the cannula 250. As described above, the probe tip 140 (including the cannula 250) may be formed from one or more materials, such as, for example, stainless steel, titanium, nitinol, or platinum. MCF600 (which may be an illuminated MCF (e.g., MCF500 described above) or a non-illuminated MCF (e.g., MCF300 described above) extends through cannula 250 of probe tip 140 and includes a plurality of cores 602, which may function similarly to cores 302 and 502 of fig. 3 and 5, respectively.

Distal portion 604 of MCF600 is disposed at distal portion 145 of probe tip 140 and is described in more detail below. Distal portion 604 terminates at an interface 606 with lens 608. Interface 606 can be configured to translate the geometry of the multiplexed multi-spot laser pattern from the distal end of MCF600, through lens 608, and onto a target surface, such as tissue at a treatment site.

In some cases, the outer cladding 610 may be removed or omitted for a length L measured from the distal end 616 of the MCF600 to mitigate or eliminate thermal problems (e.g., temperature rise at the MCF600 and lens 608 interface) to thereby improve the performance of the laser probe.

In some cases, length L may be in the range of 0.5mm to 5.0mm in some cases, length L may be in the range of 1.0mm to 3.0mm and may be any length therein in particular, in some cases, length L may be 1.0mm, 1.5mm, 2.0mm, 2.5mm, or 3.0mm in addition, length L may be any length between these values in some cases, at interface 606, distal face 618 of MCF600 may abut proximal face 614 of lens 608 in other cases, distal face 618 of MCF600 may be offset from proximal face 614 of lens 608.

In some implementations, a distal face 618 formed at the distal end 616 of the MCF600 can abut the proximal face 614 of the lens 608 at a positive pressure. In other implementations, the distal face 618 of the MCF600 may be separated from the proximal face 614 of the lens 608 by an air gap. In still other implementations, one or more optically transmissive elements or materials may be located at the interface 606 between the MCF600 and the lens 608. In some implementations, the lens 608 may be a GRIN lens, a spherical lens, or an aspheric lens. In still other implementations, the lens 608 may be a set of lenses formed of an optically transparent material.

Lens 608 may include one or more lenses formed of a visibly transparent glass or ceramic. For example, the material used to form one or more of the lenses 608 may include fused silica, borosilicate, or sapphire. In some implementations, lens 608 may comprise a single element cylindrical GRIN rod shaped lens operable to receive one or more laser beams from distal end 616 of MCF600 and relay the received laser beams toward distal tip 620 of probe tip 140. In some cases, distal tip 620 of probe tip 140 may also correspond to the distal end of lens 608. In other cases, a protective window may be disposed between the distal end of lens 608 and the distal tip 620 of probe tip 140. In still other implementations, the window can extend from the distal tip 620 of the probe tip 140.

Although MCF600 is described in the context of a non-illumination type, the scope of the present disclosure is not so limited. Rather, the concepts described herein are equally applicable to illuminating MCFs. Thus, MCF600 may be an illuminating MCF, similar to MCF500 of fig. 5.

Fig. 7A-7D, 7E 1-7E 2, and 7F 1-7F 2 compare embodiments of multi-point/multi-fiber laser probes and MCF laser probes as described herein to highlight various advantages and benefits of MCF laser probes. Fig. 7A-7B illustrate a plurality of optical fibers 710 that may be used in a multi-spot/multi-fiber laser probe (not shown), where each optical fiber 710 is used to conduct a single laser beam. More specifically, fig. 7A illustrates a front view of an optical fiber 710 housed in a multi-lumen tube 760 (e.g., a micro-spacer). As shown, the multi-lumen tube 760 includes four tunnel-shaped passages or holes 716 that each receive an optical fiber 710. Adhesive 715 is used to adhere each optical fiber 710 to its corresponding hole 716. Fig. 7B shows a side view of the optical fiber 710 extending from the cannula 750. Note that fig. 7B does not show the multi-lumen tube of fig. 7A.

In general, it is difficult to precisely control a plurality of individual optical fibers 710 during the fabrication of a multi-spot/multi-fiber laser probe. Multi-spot/multi-fiber laser probe designs may require precise alignment of multiple individual fibers 710 within the Inner Diameter (ID) of the ferrule in order to accommodate the multiple laser beams with the desired high coupling efficiency. For example, it may be time consuming to manage multiple individual fibers 710 using polyimide tubing and to strip each fiber 710 separately. After stripping, the plurality of optical fibers 710 are inserted into corresponding holes in the multi-lumen tube 760, which can be difficult and slow. In addition, the optical fibers 710 are cleaved separately, retracted into the polyimide tube and the multi-lumen tube 760, made flush by stops, and UV bonded together during bonding. This assembly is then subjected to a second heat cure to improve adhesion stability at elevated temperatures. Such manufacturing processes associated with multi-point/multi-fiber designs are complex and slow. The adhesive 715 used between each fiber and its corresponding hole or housing 716 in the multi-lumen tube 760 may also be susceptible to thermal damage and may cause probe failure.

In comparison to fig. 7A and 7B, fig. 7C and 7D illustrate an MCF 720, similar to MCFs 300, 500, and 600 shown in fig. 4-6. More specifically, fig. 7C illustrates a front view of MCF 720, which includes a plurality of cores 702 embedded in cladding 704, which is coated with coating 724. Fig. 7D illustrates a side view of the MCF 720 extending from the cannula 752. As shown, the MCF 720 is a single optical fiber having a plurality of cores 702, each of which transmits a laser beam, compared to the plurality of optical fibers 710 of the multi-spot/multi-fiber laser probe.

Laser probes incorporating MCFs, such as MCF 720, do not require the use of an adhesive between cores 702, as cores 702 are embedded in cladding 704 and contained within a single optical fiber. Accordingly, a laser probe including an MCF may have significantly improved power handling capability. Furthermore, the assembly of the MCF laser probe is relatively simple, since only a single optical fiber needs to be aligned and manipulated during manufacturing. Accordingly, the use of polyimide tubing and multi-lumen tubing to manage multiple individual fibers during assembly is not required, and the time taken to strip a single MCF 720 is significantly less than the time taken to strip multiple individual fibers 710 of a multi-point/multi-fiber probe.

In addition, the use of MCF in laser probes may allow for tight control of the direction of the propagating beam. More specifically, the use of MCF may ensure that the beam propagated by the laser probe is tightly controlled and not directed towards the inner surface of the cannula. Fig. 7E 1-7E 2 and 7F 1-7F 2 illustrate a comparison between laser beam patterns associated with multiple fibers of a multi-spot/multi-fiber laser probe and laser beam patterns associated with the core of an MCF.

Fig. 7E1 depicts a fiber pattern within the multi-lumen tube 760 at the distal end of a fiber optic assembly comprising a plurality of optical fibers 710. Fig. 7E2 illustrates a laser beam pattern 770 corresponding to the fiber pattern of fig. 7E1, including a laser beam spot 772. As shown, some of the optical fibers 710 (e.g., the upper right core and the lower right core) are not centered within the passageway 716 of the multi-lumen tube 760, which results in the bundle propagated by these optical fibers 710 being likely to be skewed outward, as shown in fig. 7E 2. In some cases, some optical fibers 710 may not be centered within their corresponding passageways 716 due to loose tolerances between the outer diameter of the optical fibers 710 and the inner diameter of the passageways 716 of the multi-lumen tube 760, such that the optical fibers 710 are instead directed toward the inner surface of the cannula (not shown). Thus, the bundle propagated by the optical fiber 710 is also directed toward the inner surface of the cannula, rather than in a straight direction toward the patient's eye. This causes these beams to escape the lens of the laser probe, such as lens 608, and be absorbed by the inner surface of the cannula, which may cause the cannula to overheat. In addition, the non-centering of the fiber 710 within its corresponding passage 716 may result in undesirable uniformity among the corresponding four beam spots.

In contrast to fig. 7E 1-7E 2, fig. 7F 1-7F 2 show the fiber and bundle patterns associated with MCFs, respectively. Fig. 7F1 shows cores 702 of MCFs that point in a straight direction and are not skewed outward. This is because the cores 702 are tightly embedded together in the cladding. Thus, the core 702 is able to propagate beam spots 782 (shown in the beam pattern 782 of fig. 7F 2), which also point in a straight direction and not towards the inner surface of the cannula (not shown) in which the MCF is housed. In this way, the use of MCF improves control of the laser beam pattern (e.g., desired uniformity among four beam spots) of the laser probe and increases power handling by preventing over-heating of the cannula due to the beam being directed at the inner surface of the cannula.

Accordingly, the disclosed MCF laser probe design can simplify manufacturing by eliminating complex and expensive manufacturing requirements, improve power handling by eliminating adhesive failure during bonding of the distal ends of multiple fibers or introducing contaminants into the distal fiber assembly of a multi-fiber probe, increase coupling efficiency by employing precisely aligned MCFs and avoiding difficulties associated with aligning individual fibers with multiple input laser beams in a multi-fiber assembly, and improve control of laser beam patterns (which also further improves power handling). These and other advantages will be apparent to those skilled in the art in view of this disclosure.

Fig. 8 illustrates an exemplary flowchart 800 illustrating steps in a method for applying a multi-spot laser beam pattern in accordance with certain embodiments of the invention. In certain embodiments, operation 800 is performed by a system, such as surgical laser system 102 of fig. 1, coupled to an MCF laser probe, such as MCF laser probe 108 of fig. 1.

At block 802, the system generates a laser beam by a laser source. As described above, the laser source may be part of or coupled with the surgical laser system 102.

At block 804, the system collimates the laser beam. A collimated laser beam refers to a laser beam having parallel rays.

At block 806, the system directs the collimated laser beam to a Diffractive Optical Element (DOE) configured to generate a multi-spot laser pattern of the laser beam. As recognized by one of ordinary skill in the art, DOEs are used to shape and split the laser beam.

At block 808, the system directs the laser beam multi-point pattern to a condenser lens.

At block 810, the system focuses the laser beam multi-point pattern into an interface plane of the proximal end of the MCF such that each laser beam in the multi-point laser pattern of laser beams is transmitted into and propagates along one of a plurality of cores of the MCF, the plurality of cores are surrounded by a cladding, and the cladding is surrounded by a coating, the refractive index of each of the plurality of cores is greater than the refractive index of the cladding, and a portion of the coating is omitted from a length of the distal end of the MCF.

For example, the surgical laser system 102 focuses the laser beam multi-spot pattern into an interface plane of the proximal end of the MCF (e.g., MCF 110, MCF300, MCF500, MCF600, etc.) such that each laser beam of the multi-spot laser pattern of the laser beam is transmitted into and propagates along one of a plurality of cores (e.g., cores 302, 502, 602, etc.) of the MCF surrounded by a cladding (e.g., claddings 304, 504, 506, 612), and the cladding is surrounded by a coating (e.g., 306, 508, etc.), each core of the plurality of cores having a refractive index greater than the cladding, and a portion of the coating is omitted from a length (e.g., shown as length L of fig. 6) of the distal end of the MCF.

At block 812, the system transmits a laser beam multi-spot pattern to the distal end of the MCF. For example, the system transmits a laser beam multi-spot pattern to the distal end (e.g., distal end 616) of the MCF.

At block 814, the system directs the laser beam multi-point pattern through a lens (e.g., lens 608) to a distal tip (e.g., distal tip 620) of a surgical probe (e.g., probe 108).

Fig. 9 illustrates a distal portion of another exemplary probe 901 operable to generate a laser beam multi-spot pattern. The illustrated exemplary probe 901 includes an illuminated MCF900, which can be similar to the MCF500 described above. Thus, probe 901 is operable to emit both general illumination for illuminating the surgical field, and a plurality of laser beams for treating a treatment site, such as the retina. Probe 901 can be similar in many respects to probe 108. As shown, the probe 901 includes a cannula 902. The cannula 902 includes an inner surface 936 defining an internal passageway 942. The MCF900 extends through at least a portion of the cannula 902 to a first interface 906 with the lens 908. MCF900 may abut lens 908 or a void, such as an air-filled void, may be disposed between a distal end 916 of MCF900 and a proximal end 914 of lens 908. In some cases, the distal end 916 of MCF900 may abut the proximal end 914 of lens 908 at a positive pressure. In some cases, lens 908 may be formed from fused silica, borosilicate, or sapphire. In some cases, lens 908 may be a spherical lens. Lens 908 may be a GRIN lens, such as a single element cylindrical GRIN rod lens, operable to receive one or more laser beams from the distal end of MCF900 and relay the received laser beams toward distal tip 920 of probe 901.

Probe 901 also includes a protective window 918 that extends from a second interface 922 with lens 908. As shown in fig. 9, protective window 918 abuts lens 908. In other implementations, there may be a void, such as an air-filled void, between the protective window 918 and the lens 908. In the illustrated example, the protective window 918 extends distally beyond the distal end 924 of the cannula 902, and the distal end 926 of the protective window 918 defines the distal tip 920 of the stylet 901. In other implementations, the distal end 926 of the protective window 918 may be aligned with the distal end of the distal end 924 of the cannula 902 such that the distal end 924 of the cannula 902 and the distal end 926 of the protective window 918 are substantially flush. One of ordinary skill in the art recognizes that the relative positions of the end surface of the distal end 924 of the cannula 902 and the end surface of the distal end 926 of the protection window 918 may vary slightly due to manufacturing tolerances.

The protective window 918 may be formed of an optically stable and high temperature resistant material. In some cases, the protective window 918 may be formed of sapphire or quartz. In some cases, the protection window 918 may have a flat proximal surface, as shown in fig. 9. In other cases, the protection window 918 may have a convex proximal surface 928. Fig. 10 shows an example of such a lens.

In fig. 10, lens 1008 has convex proximal and distal ends. Although the lens 1008 is elongated in the longitudinal direction, in other examples it may instead be a spherical or spherical lens. In some implementations, a lens having a flat proximal end and/or a flat distal end, such as lens 908 shown in fig. 9, may be used in conjunction with protective window 1018 having a convex proximal end, similar to that shown in fig. 10. In still other implementations, the probe may include a lens, such as a spherical lens or the lens shown in fig. 9, with a convex proximal end and/or a convex distal end to combine with a protective window having a flat proximal end, such as protective window 918 shown in fig. 9.

Referring back to fig. 9, the MCF900 includes an outer cladding 930, which may be similar to the outer cladding 506 shown in fig. 5 the outer cladding 930 is stripped from the inner cladding 932, e.g., by a length L measured from the distal end 916 of the MCF900 and extending proximally, thereby exposing the underlying inner cladding 932.

In some cases, length L may be in the range of 0.5mm to 5.0mm in some cases, length L may be in the range of 1.0mm to 3.0mm and may be any length therein in particular, in some cases, length L may be 1.0mm, 1.5mm, 2.0mm, 2.5mm, or 3.0mm in addition, length L may be any length between these values.

However, with a portion of the outer cladding 930 removed, an annular gap 934 exists between the inner cladding 932 and the inner surface 936 of the cannula 902. The annular void 934 introduces a risk of misalignment between the MCF900 and the lens 908 (i.e., the MCF900 may be decentered with respect to the lens 908). Fig. 11 is a side view of exposed end 938 of probe 901, where exposed end 938 of MCF900 is aligned with lens 908. The exposed end 938 of MCF900 is the portion of MCF900 from which the outer cladding 930 has been removed.

However, fig. 12 shows that the exposed end 938 of MCF900 is misaligned with lens 908 due to annular void 934. As shown in fig. 12, exposed end 938 of MCF900 is not concentric with lens 908. With the exposed end 938 of the MCF900 misaligned with the lens 908, the resulting laser spot and illumination beam pattern is no longer concentric with the cannula 902. Such misalignment between the MCF900 and the lens 908 may also result in a portion of the light being transmitted for general illumination and striking the inner wall 936 of the cannula 902 through the inner cladding 932. This reduces the illumination efficiency of the probe 901 and results in an undesirable illumination pattern.

In certain embodiments, to maintain alignment between the MCF900 and the lens 908, a ring formed of a thermally stable material may be disposed in the annular void 934 to maintain concentricity of the MCF900 with the cannula's internal passageway and the lens. In certain embodiments, the material may include, for example, polyimide, metal, stainless steel, nickel, silver, copper, brass, and the like. While polyimide and metal are possible materials from which the ring can be made, other materials can be used. Fig. 13 illustrates an example of a ring for maintaining alignment between MCF900 and lens 908.

FIG. 13 illustrates a ring 940 disposed within an annular void 934 formed around the inner cladding 932 at an exposed end 938 of the MCF 900. the ring 940 maintains concentricity of the MCF900 with the lens 908, for example, by limiting lateral movement of the exposed end 938 of the MCF 900. in some cases, an inner diameter of the ring 940 corresponds to an outer diameter of the exposed end 938 of the MCF 900. in some cases, an outer diameter of the ring 940 corresponds to an inner diameter of the internal passageway 942. the ring 940 may span the entire length L of the exposed end 938 or less than the entire length L.

Fig. 14 illustrates another exemplary implementation for maintaining alignment of MCF900 with lens 900. In the example shown in fig. 14, cannula 1402 includes an internal passageway 942 having a first inner diameter 1444 that more conforms to the outer diameter of MCF 900. Cannula 1402 also includes a counter bore 946 having a second inner diameter 1448 that is greater than the first inner diameter 1444. Counterbore 946 is provided to receive lens 908 and protection window 918 (if included) within cannula 1402 because the transverse cross-sectional size of these components is larger compared to the transverse cross-sectional size of MCF 900. Thus, along the exposed end 938, the passage 942 having a reduced cross-sectional size as compared to the counterbore 946 is able to maintain alignment of the exposed end 938 of the MCF900 with the lens 908 to a greater extent than if the inner diameter 1444 of the passage 942 were the size of the inner diameter 1448 of the counterbore 946. Thereby, the alignment between the MCF900 and the lens 908 is improved. In some instances, the countersink 946 extends proximally from the distal end of the cannula 1402.

Fig. 15 shows the following example: the reduced inner diameter 1550 of the cannula 1502 provides alignment of the exposed end 938 of the MCF 900. The necked-down portion 1552 of the cannula 1502 (which may be the result of crimping) provides a reduced diameter 1550. The reduced inner diameter 1550 can be made to correspond to the outer diameter of the exposed end 938 of MCF 900. The reduced inner diameter 1550 maintains alignment of the exposed end 938 with the lens 908, thereby enabling improved general illumination performance and alignment of the laser spot pattern with the longitudinal axis of the cannula 1502.

Fig. 16 illustrates the potential risk of damage to MCF900 during assembly of the multi-point laser probe in the context shown in fig. 15. If the necked-down portion 1652 of the cannula 1602 (such as that resulting from crimping applied to the cannula 1602) is formed prior to introducing the MCF900 into the necked-down portion 1652, there is a risk of damage to the distal end 1654 of the MCF900 when attempting to insert the distal end 1654 (and particularly the edge 1656 of the distal end 1654) through the necked-down portion 1652. Misalignment of the distal end 1654 with the necked portion 1652 during assembly may generate a force that may gouge and damage the distal end 1654 of the MCF 900. Even small loads applied to distal end 1654, and particularly to edge 1656 thereof, may cause damage, such as gouging of distal end 1654 and edge 1656, which damage, whether in the event of poor general illumination or an inaccurate or distorted laser spot pattern or both, may result in impaired performance. Such damage may render the resulting laser probe unusable. Thus, a necked portion may be formed in the cannula after the MCF is introduced into the cannula, as shown in fig. 17 and 18.

Fig. 17 and 18 show distal end 1654 of MCF 800 abutting lens 908 at first interface 906. However, as explained above, a gap may be disposed between the distal end 1654 of the MCF 800 and the lens 908. In some implementations, one or both of lens 908 and window 918 may be installed in cannula 1702 prior to assembly of MCF 900. In some implementations, MCF900 can be installed before one or both of lens 908 and window 918.

With the MCF900 positioned at a desired location within the cannula 1702, a necked-down portion 1752 may be formed in the cannula 1702, such as by crimping. The necked-down portion 1752 maintains the exposed end 938 of MCF900 concentric with lens 908. Thereby, the risk of damage to the distal end 1654 of the MCF900 by the necked-down portion 1752 is eliminated.

In some cases, the necked-down portion 1752 is a reduced annular body that completely surrounds the exposed end 938 of the MCF 900. The necked-down portion 1752 thereby defines a reduced diameter 1858 of the internal passageway 942 that coincides with the outer diameter of the exposed end 938. In some cases, the reduced diameter 1858 of the necked portion 1752 is equal to or slightly larger than the outer diameter of the exposed end 938. By way of example, a 5 μm annular gap may be formed between the inner surface of the cannula 1702 at the necked-down portion 1752 and the outer surface of the exposed end 938. In some embodiments, the exposed end 938 can contact the inner surface of the necked portion 1752 at one or more locations.

In certain embodiments, necked-down portion 1752 may form diametrically opposed protrusions at one or more locations around the circumference of cannula 1702, thereby centering exposed end 938 of MCF900 with lens 908. For example, in some cases, necked portion 1752 may comprise two sets of diametrically opposed tabs that are offset from each other by 90 °. In certain other implementations, three or more non-diametrically opposed protrusions may be formed in the cannula to center the exposed end 938 of the MCF 900. In some cases, the projections may be formed along a common circumference of the cannula 1702. In other implementations, one or more projections may be longitudinally offset relative to one or more other projections.

Additionally, although MCF900 is described as an illuminating MCF, in some implementations MCF900 may be a non-illuminating MCF and still be within the scope of the present disclosure.

Fig. 19 illustrates an exemplary flow chart 1900 showing steps in a method for producing a multi-spot laser probe, in accordance with certain embodiments of the invention.

At block 1902, a probe tip is provided that includes a cannula configured to be inserted into an eye. For example, a technician or machine may provide a stylet tip 901 having a cannula 1702 as shown in fig. 18.

At block 1904, a lens is inserted into the cannula. For example, lens 908 is inserted into cannula 1702.

At block 1906, an MCF is inserted into the cannula, proximate to the lens. For example, MCF900 is inserted into cannula 1702, proximal to lens 908, MCF900 including a plurality of cores 933. As shown, MCF900 includes cladding 932, shown at exposed end 938 of MCF 900.

At block 1908, a necked-down portion is formed in the cannula, the necked-down portion forming a reduced cross-sectional size to maintain the exposed portion of the MCF centered within the cannula. For example, a necked-down portion 1752 is formed in the cannula 1702.

Although several of the figures described herein show probes having a protection window, it should be understood that the protection window may be omitted. It is further within the scope of the present disclosure that the ends of the lens and/or the protective window may be shapes other than flat. For example, one or more of the distal and proximal ends of the lens and/or the protective window may have a convex shape, as described herein.

The above-disclosed subject matter is to be considered illustrative, and not restrictive, and the appended claims are intended to cover all such modifications, enhancements, and other embodiments, which fall within the true spirit and scope of the present disclosure. Thus, to the maximum extent allowed by law, the scope of the present disclosure is to be determined by the broadest permissible interpretation of the following claims and their equivalents, and shall not be restricted or limited by the foregoing detailed description.