BR112019010438B1 - INTRAOCULAR LENS INJECTOR - Google Patents

Abstract

The present invention relates to an intraocular lens injector. The injector (10) includes a passage (64) formed in a distal terminal portion (60) of the intraocular lens injector. The passageway defines an interior surface (710), and a ramp (708) is formed on the interior surface so as to cause a driving haptic (450) of an intraocular lens (70) advanced through the passageway to rise above of a surface of an optic (460) of the IOL to ensure correct folding of the IOL.

Description

TECHNICAL FIELD

[0001] The present disclosure relates to systems, apparatus, and methods for intraocular lens injectors. Particularly, the present disclosure relates to systems, apparatus, and methods for intraocular lens injectors including features for elevating an intraocular lens driving haptic for improved intraocular lens bending performance.

BACKGROUND

[0002] The human eye in its simplest terms functions to provide vision by transmitting and refracting light through a clear outer portion called the cornea, and additionally focusing the image through the lens on the retina at the back of the eye. The quality of the focused image depends on many factors, including the size, shape and length of the eye, and the shape and transparency of the cornea and lens. When trauma, age, or disease cause the lens to become less transparent, vision deteriorates because of the decreased light that can be transmitted to the retina. This deficiency in the lens of the eye is medically known as a cataract. Treatment for this condition is surgical removal of the lens and implantation of an artificial intraocular lens ("IOL").

[0003] Many cataract lenses are removed by a surgical technique called phacoemulsification. During this procedure, an opening is made in the anterior capsule and a thin phacoemulsification cutting tip is inserted into the diseased lens and ultrasonically vibrated. The vibration cutting tip liquefies or emulsifies the lens so that the lens can be aspirated out of the eye. The diseased lens, once removed, is replaced with an artificial lens.

[0004]The IOL is injected into the eye through the same small incision used to remove the diseased lens. An IOL injector is used to deliver an IOL into the eye.

[0005] Prior art IOL injectors are disclosed in WO 2015/112146 A1 and US2009/0270876A1.

SUMMARY

[0006] According to one aspect, the disclosure describes an intraocular lens injector that includes an injector body and a plunger. The injector body includes a bore defined by an interior wall, a longitudinal axis extending centrally along the injector body, and a distal end portion. The distal terminal portion may include a first side wall; a second side wall disposed opposite the first side wall; a third side wall extending between the first side wall and the second side wall; and a fourth side wall opposite the third side wall, the first side wall, second side wall, third side wall, and fourth side wall, joined to define the passage forming a portion of the hole. The injector body may also include a first ramp formed on an interior surface of the passage along the first side wall, and laterally offset from the longitudinal axis. The first ramp may be disposed at a position within the passage to contact a driving haptic of an intraocular lens. The first ramp may include a first driving surface being inclined and extending inwardly from the interior surface in the passage, and a first peak disposed at a distal end of the first ramp disposed at a distal end of the first driving surface. The intraocular lens injector may also include a slideable plunger within the hole defined by the interior wall. The first driving surface may include a first plurality of steps thereon.

[0007] Aspects of the present disclosure may include one or more of the following features. Each of the first plurality of steps may include a riser and a base. The rise and base of each step is uniform. At least one of the rise and base of at least one step of the first plurality of steps may be different from the rise and base of another of the steps of the first plurality of steps. The injector body may also include a compartment configured to receive the intraocular lens. The compartment may join and be in fluid communication with the passage. A boundary can be defined between the passage and the compartment. A proximal end of the first driving surface of the first ramp may be located along the boundary.

[0008] One or more of the following features may also be included in various aspects of the present disclosure. A second ramp may be formed on the interior surface of the passage along the third side wall, and adjacent to the first ramp. The first ramp and the second ramp can be integrally formed. The second ramp may include a second driving surface, and the second driving surface may be inclined and extend inwardly from the interior surface of the passage. The second ramp may also include a second peak disposed at a distal end of the second driving surface. The second driving surface may include a second plurality of steps. Each of the second plurality of steps may include a riser and a base. The rise and base of each step can be uniform. At least one of the rise and base of at least one step of the second plurality of steps may be different from the rise and base of another of the steps of the second plurality of steps. The first conduction surface and the second conduction surface may be integrally formed. The first ramp may additionally include a first towing surface disposed distally from the first peak. The first towing surface may have a positive slope. A second ramp may be formed on the interior surface of the passage along the second side wall, and adjacent to the first ramp. The second ramp may include a second driving surface that is inclined and that extends inwardly from the interior surface of the passage, a second spike disposed at a distal end of the second driving surface, and a second towing surface. The second towing surface may have a positive slope. The first towing surface and the first towing surface may be integrally formed.

[0009] It is to be understood that both the preceding general description and the following detailed description are exemplary and explanatory in nature, and are intended to provide an understanding of the present disclosure without limiting the scope of the present disclosure. In this particular, additional aspects, features, and advantages of the present disclosure will be apparent to one skilled in the art from the following detailed description.

BRIEF DESCRIPTION OF THE DRAWINGS

[0010] FIG. 1 is a perspective view of an example intraocular lens injector.

[0011] FIG. 2 shows a longitudinal cross-sectional view of the intraocular lens injector of FIG. 1.

[0012] FIG. 3 is a perspective view of a distal portion of an exemplary injector body of the intraocular lens injector of FIG. 1.

[0013] FIG. 4 is a cross-sectional view of the distal portion of the injector body shown in FIG. 3.

[0014] FIG. 5 is an example cross-sectional shape of a nozzle of an intraocular lens injector.

[0015] FIG. 6 shows a cross-sectional view of an intraocular lens receiving the housing formed in an injector body.

[0016] FIG. 7 shows a perspective view of an intraocular lens receiving the housing formed in an injector body.

[0017] FIG. 8 is a cross-sectional view of a plunger.

[0018] FIG. 9 is a bottom view of a plunger.

[0019] FIG. 10 is a partial perspective view showing the tabs and a plunger latch of an example intraocular lens injector.

[0020] FIG. 11 is a detail view of an example piston tip of the piston.

[0021] FIG. 12 shows an exemplary interior surface of a tip enclosing a lens receiving compartment of an intraocular lens injector.

[0022] FIG. 13 is a detail view of the distal terminal portion of the IOL injector showing a demarcation designating a pause position of an IOL being advanced through the IOL injector.

[0023] FIG. 14 is a view of a distal terminal portion of an IOL injector with an IOL located therein in a paused position.

[0024] FIG. 15 is a detail view of an example IOL injector showing an opening at an interface between a housing in which an IOL is received, and an internal bore of an injector body, the detail view being transverse to a longitudinal axis of the injector. IOL injector, and the detail view showing a flexible wall portion in contact with a rod of the injector.

[0025] FIG. 16 is a partial cross-sectional view of an example IOL injector.

[0026] FIG. 17 shows an example IOL.

[0027] FIG. 18 is a perspective view of an example plunger tip.

[0028] FIG. 19 is a side view of the tip of the example piston of FIG. 18.

[0029] FIG. 20 is a top view of the tip of the example piston of FIG. 18.

[0030] FIG. 21 is a side view of a distal terminal portion of an example IOL injector.

[0031] FIG. 22 is a cross-sectional view taken along line A-A of FIG. 21.

[0032] FIG. 23 is a plan view of the distal end portion of the IOL injector of FIG. 21.

[0033] FIG. 24 is a cross-sectional view taken along line B-B of FIG. 23.

[0034] FIG. 25 is a detail view of a ramp formed in an interior passage of a distal terminal portion of an IOL injector.

[0035] FIG. 26 is a cross-sectional view taken along line C-C of FIG. 23.

[0036] FIG. 27 is a detail view of a ramp formed in an interior passage of a distal terminal portion of an IOL injector.

[0037] FIG. 28 shows an exemplary elevation feature disposed within an interior passage of an IOL injector (not itself an embodiment of the invention) operable to elevate an IOL driving haptic during advancement of the IOL.

[0038] FIG. 29 shows another example elevation feature disposed within an interior passage of an IOL injector (not itself an embodiment of the invention) operable to elevate an IOL driving haptic during IOL advancement.

[0039] FIGS. 30-33 illustrate the elevation of an IOL driving haptic by a ramp shape on an interior surface of a distal terminal portion of an IOL injector as the IOL is advanced through an interior passage of the IOL injector.

DETAILED DESCRIPTION

[0040] For the purpose of promoting an understanding of the principles of the present disclosure, reference will now be made to the implementations illustrated in the drawings, and specific language will be used to describe the same. It will, however, be understood that no limitation of the scope of disclosure is intended. Any further changes and modifications to the devices, instruments, methods described, and any further application of the principles of the present disclosure, are fully 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 with respect to one implementation may be combined with the features, components, and/or steps described with respect to the other implementations of the present disclosure.

[0041] The present disclosure relates to systems, apparatus, and methods for delivering an IOL to an eye. Particularly, the present disclosure relates to intraocular lens injector systems, apparatus, and methods having features for improving the elevation of the conduction haptic during folding of the intraocular lens. FIGS. 1 and 2 show an example IOL injector 10 that includes an injector body 20 and a plunger 30. The injector body 20 defines a bore 40 that extends from a proximal end 50 of the injector body 20 to a distal end portion. 60 of the injector body 20. The plunger 30 is slideable within the 40. Particularly, the plunger 30 is slideable within the bore 40 to advance an IOL, such as the IOL 70, within the injector body 20. The IOL injector 10 also includes a longitudinal axis 75 disposed centrally through the body 20. The longitudinal axis 75 may extend along the plunger 30, and defines a longitudinal axis of the plunger 30.

[0042] The injector body 20 includes a housing 80 operable to house an IOL prior to insertion into an eye. In some examples, a tip 90 may be included to provide access to the compartment 80. The tip 90 may include a hinge 100, such that the tip 90 may be hinged on the hinge 100 to open the compartment 80. The injector body 20 may be also include tabs 110 formed on the proximal end 50 of the injector body 20. The tabs 110 may be manipulated by the fingers of a user, such as an ophthalmologist or other medical professional, to advance the plunger 30 through the hole 40.

[0043] FIGS. 3-5 illustrate details of the distal end portion 60 of the injector body 20. In some examples, the distal end portion 60 has a tapered outer surface. Additionally, the distal end portion 60 includes a passage 64 that tapers toward a distal opening 125. The injector body 20 also includes a nozzle 120 in the distal end portion 60. The nozzle 120 is adapted for insertion into an eye, of so that an IOL can be implanted. An IOL is expelled from the distal opening 125 formed in the nozzle 120. As shown in FIG. 5, the nozzle 120 may have a cylindrical cross section. Additionally, the nozzle 120 may include a beveled tip 130. The housing 80, passage 64, and opening 125 may define a dispensing passage 127. A size of the dispensing passage 127 may vary along its length. That is, in some examples, a passage height H1 may change along a length of delivery passage 127. Variation in the size of delivery passage 127 may contribute to bending of the IOL as it advances along it. .

[0044] In some examples, the injector body 20 may include an insertion depth guard 140. The insertion depth shield 140 may form a flanged surface 150 that is adapted to encyst into an outer eye surface. The insertion depth guard 140 abuts a surface of the eye and thereby limits an amount by which the nozzle 120 is permitted to extend into an eye. In some implementations, the flanged surface 150 may have a curvature that conforms to the outer surface of an eye. For example, the flanged surface 150 may have a curvature that conforms to a scleral surface of the eye. In other examples, the flanged surface 150 may have a curvature that corresponds to a corneal surface of the eye. In still other examples, the flanged surface 150 may have a curvature, part of which corresponds to a scleral surface, and another part of which corresponds to a corneal surface. In this way, the flanged surface 150 can be concave. In other examples, the flanged surface 150 may be flat. In still other examples, the flanged surface 150 may be convex. Additionally, the flanged surface 150 may have any desired contour. For example, the flanged surface 150 may be a curved surface having radii of curvature that vary along radial directions other than a center of the flanged surface 150. In still other examples, the flanged surface 150 may define a surface that has varying curvature along the along different radial directions, as well as curvature that varies along one or more particular radial directions.

[0045] In FIG. 3, the insertion depth guard 140 is shown as a continuous feature that forms a continuous flanged surface 150. In some implementations, the insertion depth guard 140 may be segmented into a plurality of features or protrusions that form a plurality of insertion depth surfaces. eye contact. These eye contact surfaces can operate in concert to control the depth to which the nozzle 120 can penetrate an eye. In other implementations, insertion depth protection 140 may be omitted.

[0046] FIG. 6 shows a detailed cross-sectional view of the housing 80 and a bore portion 40 of the example injector body 20 shown in FIG. 2. Bore 40 is defined by an interior wall 298. The interior wall 298 includes a tapered portion that includes a first tapered wall 301 and a second tapered wall 303. The tapered portion of the interior wall 298 defines an opening 170 at an interface 172 between hole 40 and compartment 80. Opening 170 includes a height H2. A distal end portion 211 of the plunger rod 210 has a height of H3. In some examples, the height H2 may be greater than the height H3 such that initially there is no interference between the plunger rod 210 and the inner wall 298 in the opening 170. In other examples, the height H2 may be equal to or greater than height H3 such that the plunger rod 210 and the opening 170 initially have an interference fit. In some implementations, the first tapered wall 301 includes a flexible wall portion. In the example shown, the flexible wall portion 162 is a flexible portion extending obliquely from the interior wall 298 and particularly from the first tapered wall 301. As shown in FIG. 7, in some examples, portions of the first tapered wall 301 are removed, forming voids 163 that flank the flexible wall portion 162. Thus, in some examples, the flexible wall portion 162 may extend in a cantilever manner.

[0047] Referring again to FIG. 6, in some examples, the flexible wall portion 162 may be inclined toward the distal end portion 60 of the injector body 20. In some examples, an angle B defined by the flexible wall portion 162 and the longitudinal axis 75 may be at the range from 20° to 60°. For example, in some examples, angle B may be 20°, 25°, 30°, 35°, 40°, 45°, 50°, 55°, or 60°. Additionally, angle B may be greater than or less than the defined range, or anywhere within the recited range. Furthermore, the scope of disclosure is not thus limited. Thus, angle B can be any desired angle.

[0048] The injector body 20 may also include a contoured ramp 180 formed along an interior receiving surface 190 of the housing 80. Generally, the interior receiving surface 190 is the surface on which an IOL, such as IOL 70, is placed. , is placed when loaded into the IOL injector 10. FIG. 7 is a perspective view of a portion of the body of the example injector 20 shown in FIG. 2. The 90 tip is not shown. In some examples, a vertical distance C between a tip of the flexible wall portion 162 and the top of the contoured ramp 180 may correspond with a height H3 of a distal end portion 211 of the plunger rod 210. In other examples, the distance C may be greater or less than the height H3 of the distal terminal portion 211 of the plunger rod 210. The flexible wall portion 162 and contoured ramp 180 are discussed in more detail below. In some implementations, the flexible wall portion 162 may be omitted. For example, in some implementations, the flexible wall portion may be unnecessary, as the plunger 30 and associated plunger rod 210 holds are configured such that a plunger tip, e.g., plunger tip 220 discussed in more detail below, it remains in contact with the contoured ramp 180 during the advancement of the piston 30.

[0049] As also shown in FIG. 7, the injector body 20 may include a contoured surface 192 that is spaced away from the receiving surface 190. A wall 194 is formed adjacent the contoured surface 192. A freely extending end 452 of a haptic 450, shown in FIG. . 17, contacts the contoured surface 192 when the IOL 70 is received in the compartment 80.

[0050] Referring to FIGS. 1 and 8-9, the plunger 30 may include a body portion 200, a plunger rod 210 extending distally from the body portion 200, and a plunger tip 220 formed at a distal end 230 of the plunger rod. 210. The plunger 30 may also include a flange 240 formed at a proximal end 250 of the body portion 200. A biasing element 260 may be disposed on the plunger 30. In some examples, the biasing element 260 may be a spring. In some implementations, the bias member 260 may be disposed adjacent the flange 240. A proximal end 262 may be fixedly attached to the body portion adjacent the flange 240. In other examples, the bias member 260 may be disposed at another location adjacent to the flange 240. along the body portion 200. In still other implementations, the biasing member 260 may be formed or otherwise disposed in the injector body 20, and adapted to engage the plunger 30 at a selected location during advancement of the plunger 30 through of hole 40. Still further, in other implementations, bias element 260 may be omitted.

[0051] The flange 240 can be used in conjunction with the tabs 110 to advance the plunger 30 through the injector housing 20. For example, a user can apply pressure to the tabs 110 with two fingers, while applying opposite pressure to the flange 240 with the user's thumb. A surface of the flange 240 may be textured to provide positive gripping by a user. In some examples, the texture may be in the form of a plurality of grooves. However, any desired texture can be used.

[0052] The body portion 200 may include a plurality of transversely arranged ribs 270. In some examples, the ribs 270 may be formed on both a first surface 280 and a second surface 290 of the body portion 200, shown in FIG. 1. In other examples, ribs 270 may be formed on only one of the first surface 280 and second surface 290. A longitudinally extending rib 300 may also be formed on one or both of the first and second surfaces 280, 290.

[0053] In some examples, the body portion 200 may also include one or more protrusions 202, as shown in FIG. 9. The protrusions 202 may extend longitudinally along a length of the body portion 200. The protrusions 202 may be received in grooves 204 formed in the injector body 20, as shown in FIG. 1. Protrusions 202 and grooves 204 interact to align plunger 30 within hole 40 of injector body 20.

[0054] The body portion 220 may also include cantilever members 292. The cantilever members 292 may extend from a distal end 294 of the body portion 200 toward the proximal end 250. The cantilever members 292 may include flared portions 296. The cantilever members 292 may also include substantially horizontal portions 297. The flared portions 296 are configured to engage the interior wall 298 of the injector body 20 that defines the bore 40, as shown in FIG. 2. The engagement between the cantilever members 292 and the interior wall 298 generates a resistive force for advancing the plunger 30, and provides tactile feedback to the user during advancement of the plunger 30. For example, in some implementations, the resistive force generated by the contact between the cantilever members 292 and the interior wall 298, may provide a baseline resistance that resists the advancement of the plunger 30.

[0055] In some examples, the plunger rod 210 may include an angled portion 212. The distal end portion 211 may form part of the angled portion 212. The angled portion 212 may define an angle, A, within the range of 1° to 5° with the longitudinal axis 75. In some examples, angle A may be 2°. In some examples, angle A may be 2.5°. In still other examples, angle A may be 3°, 3.5°, 4°, 4.5°, or 5°. Additionally, while the above values of A are provided as examples, angle A may be greater or less than the indicated range, or any value in between. Thus, angle A can be any desired angle.

[0056] The angled portion 212 ensures that the tip of the plunger 220 contacts and follows the receiving surface 190 as the plunger 30 is advanced through hole 40. In particular, the angle A defined by the angled portion 212 exceeds what is necessary to cause the tip of the plunger 220 to contact the inner wall 298 of the bore 40. That is, when the plunger 30 is disposed within the bore 40, engagement between the tip of the plunger 220 and the inner wall 298 causes the portion angled portion 212 bends internally due to angle A. Consequently, the angled portion 212 ensures that the tip of the plunger 220 correctly engages the haptics and optics of an IOL being inserted from the IOL injector 10. This is described in greater detail below. Although the angled portion 212 is shown to be a substantially straight portion curved at an angle relative to the remainder of the plunger rod 210, the scope is not so limited. In some examples, a portion of piston rod 210 may have a continuous curvature. In other examples, a full length of the plunger rod 210 may be curved, or have a curvature. Additionally, the amount of angular deviation from the longitudinal axis 75, or amount of curvature may be selected so as to provide a desired amount of engagement between the tip of the plunger 220 and the interior surfaces of the injector body 20.

[0057] The biasing element 260 may be attached to the body portion 200 adjacent to the flange 240. In some examples, the biasing element 260 may form a loop 310 that extends distally along the body portion 200 that functions as a spring to resist advancement of the plunger 30 when the shackle 310 engages the injector body 20. The biasing member 260 may also include a collar 261 that defines a channel 320 through which the body portion 200 extends. Thus, in operation, as the plunger 30 is advanced through the bore 40 of the injector body 20 (i.e., in the direction of the arrow 330 shown in FIG. 2), a distal end 265 of the biasing member 260 contacts the proximal end 50 of the injector body 20 at a selected location along the stroke of the plunger 30. As the injector 30 is further advanced, the biasing element 260 is compressed, and the channel 320 allows the distal end 265 of the element of bias 260 moves relative to body portion 200. Similarly, channel 320 allows relative movement between body portion 200 and the distal end 265 of bias member 260 during proximal movement of plunger 30 (i.e., in the direction of arrow 340, also shown in FIG. 2).

[0058] Referring to FIGS. 2, 9, and 10, the IOL injector 10 may also include a plunger lock 350. The plunger lock 350 is removably disposed in a groove 360 formed in one of the flaps 110. The plunger lock 350 includes a protrusion 370 formed at one end of it. The plunger lock 350 may include a simple protrusion 370 as shown in FIG. 2. In other examples, the plunger latch 350 may include a plurality of protrusions 370. For example, FIG. 10 illustrates an exemplary plunger lock 350 having two protrusions 370. In other examples, the plunger lock 350 may include additional protrusions 370.

[0059] When installed, the protrusion 370 extends through an opening 375 formed in the injector body 20, and is received in a notch 380 formed in the plunger 30. When the plunger lock 350 is installed, the protrusion 370 and notch 380 interlock to prevent the plunger 30 from moving within the hole 40. That is, the installed plunger lock 350 prevents the plunger 30 from being advanced through or removed from the hole 40. After removing the plunger lock 350, the plunger 30 may be freely advanced through hole 40. In some examples, the plunger lock 350 may include a plurality of raised ribs 390. The ribs 390 provide tactile resistance to aid in removal from and insertion into the groove 360.

[0060] The plunger lock 350 may be U-shaped, and defines a channel 382. The channel 382 receives a portion of the flap 110. Additionally, when seated on the flap 110, a proximal portion 384 of the plunger lock 350 may be externally inflected. Consequently, the plunger lock 350 can be frictionally retained in the flap 110.

[0061] Referring to FIGS. 2 and 8, in some implementations, the body portion 20 may include bosses 392 formed in bore 40. Bosses 392 may be formed at a location in bore 40 where bore 40 narrows from a widened proximal portion 394, and a narrower distal 396. In some examples, the boss 392 may be a curved surface. In other examples, shoulder 392 may be defined as a stepped change in the size of hole 40.

[0062] The cantilever members 292 may engage the shoulder 392. In some implementations, the flared portion 296 of the cantilever members 292 may engage the shoulder 392. In some examples, a location in which the cantilever members 292 engage the shoulder 392 may be one in which the notch 380 aligns with the opening 375. Thus, in some implementations, engagement between the cantilever members 292 and shoulder 392 may provide a convenient arrangement for insertion of the plunger lock 350 to lock the plunger 30 in location relative to the injector body 20. In other implementations, the notch 380 and the opening 375 may not align when the cantilever members 292 engage the shoulder 392.

[0063] As the plunger 30 is advanced through hole 40, the widened portion 296 of the cantilever members 292 may be internally displaced to comply with the narrowed distal portion 396 of hole 40. As a result of this deflection of the widened portion 296 , the cantilever members 292 apply an increased normal force to the interior wall 298 of the hole 40. This increased normal force generates a frictional force that resists the advancement of the plunger 30 through the hole 40, thereby providing tactile feedback to the user.

[0064] Referring to FIGS. 1 and 2, the IOL injector may also include an IOL stop 400. The IOL stop 400 is received in a recess 410 formed in an outer surface 420 of the tip 90. The IOL stop 400 may include a protrusion 430 that extends through an opening 440 formed at the tip. Protrusion 430 extends between a haptic and optics of an IOL loaded in compartment 80. As shown in FIGS. 1 and 17, the IOL 70 includes haptics 450 and an optic 460. The protrusion 430 is disposed between one of the haptics 450 and the optic 460. The stop of the IOL 430 may also include a tab 435. The tab 435 may be grasped by a user to remove the IOL 430 stop from the injector body 20.

[0065] The IOL stop 400 may also include an opening 470. The opening 470 aligns with another opening formed in the tip 90, e.g., opening 472 shown in FIG. 13. The opening 470 and second opening 472 in the tip 90 form a passage through which a material, such as a viscoelastic material, can be introduced into the compartment 80.

[0066] The IOL stop 400 is removable from the tip 90. When installed, the IOL stop 400 prevents advancement of the IOL, such as an IOL 70. Particularly, if advancement of the IOL 70 is attempted, the optic 460 contacts the protrusion 430, thereby preventing advancement of the IOL 70.

[0067] FIG. 11 shows an example plunger tip 220. The plunger tip 220 may include a first protrusion 480 and a second protrusion 490 extending from opposite sides. The first and second protrusions 480, 490 define a first groove 500. The first groove 500 defines a surface 502. A second groove 510 is formed within the first groove 500. The first groove 500, particularly in combination with the first protrusion 480, serves to capture and fold the towing haptic of an IOL. The second slot 510 functions to capture and bend an IOL optic.

[0068] A side wall 520 of the tip of the plunger 220 may be tapered. The tapered side wall 520 may provide a docking space for an accordion portion of an IOL towing haptic. The accordion portion of the haptic tends to remain close to the IOL optic. In this way, the tapered sidewall 520 can provide a fitting space that promotes correct folding of the IOL during delivery to an eye.

[0069] FIGS. 18-20 show another example plunger tip 220. This plunger tip 220 includes a first protrusion 600, a second protrusion 602, and a groove 604. The first protrusion extends at an oblique angle θ from the longitudinal axis 606. In some examples, the angle θ can be between 25° to 60°. In other examples, the angle θ may be smaller than 25°, or greater than 60°. In other examples, the angle θ can be between 0° to 60°. In still other implementations, the angle θ can be between 0° and 70°; 0° and 80°; or 0° and 90°. Generally, the angle θ can be selected to be any desired angle. For example, the angle θ may be selected based on one or more of the following: (1) a dimension, such as a height, of the passage 64 formed within the nozzle 60; (2) the height of the compartment 80; (3) how the height of the passage 64 and/or compartment varies along their respective lengths; and (3) the thickness of the tip of the plunger 220. The second protrusion 602 may include a tapered portion 608. The tapered portion 608 is operable to engage an optic of an IOL, such as the optic 460 shown in FIG. 17. The optic can slide along the tapered surface so that the optic can be moved in the groove 604. As a result, the second protrusion 602 is positioned adjacent to a surface of the optic.

[0070] The example plunger tip 220 shown in FIGS. 1820 also includes a surface 610 that may be similar to surface 502. Surface 610 is adapted to contact and displace a towing haptic or proximally extending haptic, such as haptic 450 shown in FIG. 17, so that the haptic bends. In some example, surface 610 may be a flat surface. In other examples, surface 610 may be a curved surface or otherwise contoured surface. The example plunger tip 220 may also include a side wall 612 and support surface 613. Similar to the side wall 520, the side wall 612 may be tapered, as shown in FIG. 20. In some examples, the side wall 612 may include a first curved portion 614. The first curved portion 614 may receive a curved portion of the towing haptic that remains close to the optics during folding. The towing haptic is supported by the support surface 613 during the folding process. The side wall 612 may also include a second curved surface 615.

[0071] The first obliquely extending protrusion 600 effectively increases a height H4, as compared to the plunger tip 220 shown in FIG. 11, for example. This increased height H4 improves the ability of the plunger tip 220 to capture the towing haptic during advancement of the plunger 30. In operation, as the plunger 30 is advanced distally, the distal end 618 engages an interior wall of the dispensing passage 127 due to changes in the height H1 of the distribution passage 127. As the height H1 decreases, the first protrusion 600 pivots over the hinge 620, effectively reducing the total height H4 of the plunger tip 220. As the first protrusion 600 pivots over hinge 620, and rotates in a direction toward the second protrusion 602, the first protrusion 600 captures the tow haptic between the IOL optics and the first protrusion 600. Therefore, with the first protrusion 600 pivotable over the hinge 620, The size of the plunger tip 220 is able to adapt and conform to the change in height H1 of the delivery passage 127 as the IOL is advanced distally and extended.

[0072] FIG. 12 shows an interior surface 530 of the tip 90. The surface 510 may include a ridge 530. The ridge 530 may include a curved portion 540. In the illustrated example, the curved portion 540 extends proximally and inwardly toward the longitudinal axis 75. curved portion 540 is configured to overlap a portion of an IOL towing haptic, which promotes correct bending of the IOL when the plunger 30 is advanced through the injector body 20.

[0073] In operation, the plunger lock 350 may be inserted into the slot 360 to lock the plunger 30 in position relative to the injector body 20. An IOL, such as the IOL 70, may be carried in the housing 80. For example, tip 90 may be opened by a user, and a desired IOL inserted into compartment 80. Tip 90 may be closed after insertion of the IOL into compartment 80. In some examples, an IOL may be preloaded during production.

[0074] The stop of the IOL 400 can be inserted into the recess 410 formed in the tip 90. The viscoelastic material can be introduced into the compartment 80, via the aligned opening 470 and corresponding opening formed in the tip 90. The viscoelastic material functions as a lubricant for promote advancement and bending of the IOL during advancement and distribution of the IOL in one eye. In some examples, viscoelastic material may be introduced into compartment 80 at the time of production.

[0075] The IOL stop 400 can be removed from the recess 410 formed in the tip 90, and the plunger lock 350 can be removed from the groove 360. The plunger 30 can be advanced through the hole 40. The engagement of Sliding between the cantilever members 292 and the interior wall 298 of the injector body 20 generates a resistive force that resists the advancement of the plunger 30. In some examples, the plunger 30 may be advanced through the bore 40 until the tip of the plunger 220 extends into compartment 80. For example, plunger 30 may be advanced until the tip of plunger 220 is adjacent to or in contact with the IOL. In other examples, plunger 30 may be advanced through hole 40 such that the IOL is partially or completely bent. Additionally, plunger 30 may advance the IOL to a position within the nozzle just short of being ejected from distal opening 125. For example, in some examples, advancement of plunger 30 prior to insertion of nozzle 120 into a wound formed in the eye, may be terminated at the point where the distal end 265 of the biasing member 260 contacts the proximal end 50 of the injector body 20.

[0076] FIG. 21 shows the distal terminal portion 60 of the IOL injector 10. FIG. 22 is a cross-sectional view of the distal terminal portion 60 of the IOL injector 10 taken along line A-A. The longitudinal axis 75 is shown in FIG. 22, and extends centrally along passage 64 such that longitudinal axis 75 bisects distal terminal portion 60 symmetrically in FIG. 22. Referring to FIGS. 21 and 22, the distal end portion 60 includes a first side wall 700, a second side wall 702 opposite the first side wall 700, a third side wall 704 disposed between the first and second end walls 700 and 702, and a fourth side wall 706 opposite the third side wall 704, and also disposed between the first and second end walls 700 and 702. The side walls 700, 702, 704, and 706 define the passage 64.

[0077] In order to provide improved bending of an IOL, such as IOL 70, a ramp 708 is formed on an interior surface 710 of the first side wall 700. Referring to FIGs. 22, 23, and 28, ramp 708 includes a spike 709, a driving surface 712 disposed proximally to spike 709, and a towing surface 713 disposed distally from spike 709. Spike 709 extends over a width of the ramp. 708, and separates the driving surface 712 from the towing surface 713. Peak 709 represents a portion of ramp 708 with the greatest separation from plane C, shown in FIG. 24, and discussed in more detail below. As is readily apparent, the driving surface 712 of the ramp 708 increases the lift, i.e., displacement in the direction of the arrow, of an IOL driving haptic (e.g., IOL driving haptic 450, shown in FIG. 10) at a much faster rate as the IOL is advanced through passage 64 than would otherwise be provided by surface 710 if ramp 708 were omitted. Ramp 708 operates to prevent or eliminate improper folding of the conduction haptic during folding of the IOL within the IOL injector 10. For example, ramp 708 may prevent improper folding where the conduction haptic remains distal to and in contact with an edge. 728 (shown in FIG. 24) of the optic 460 during folding of the IOL 70. Thus, the ramp 708 is operable to raise the driving haptic 450 above the optic 460, such that the haptic 450 is capable of being folded over the optic 460 as the IOL 70 is folded before being expelled from the IOL injector 10 and into one eye for implantation.

[0078] As shown in FIG. 22, the ramp 708 is laterally offset from the longitudinal axis 75, which forms a centerline along the IOL injector 10, toward the third side wall 704. The location of the ramp 708 is such that an end extending freely of an IOL driving haptic, such as the freely extending end 452 of the IOL 70 haptic 450 that digitally extends from the optic 460, meets the ramp 708 as the IOL is advanced along the passage distribution valve 127 by piston 30.

[0079] FIG. 23 is a plan view of the distal terminal portion 60 of the IOL injector 10 showing the second side wall 702. FIG. 24 is a cross-sectional view of the distal terminal portion 60 taken along the line B-B shown in FIG. 22. Line B-B represents a plane passing through a portion of ramp 708 having the greatest distance between a point along peak 709 and plane C, shown in FIG. 24. H5 represents the maximum dimension between ramp 708 and plane C. Ramp 708 is positioned within passage 64 to contact and engage the freely extending end of the driving haptic. In the illustrated example, ramp 708 is disposed distally from the boundary 65 between compartment 80 and passage 64. Ramp 708 begins at a proximal end indicated by point 705. In some examples, a longitudinal distance G between point 705 and the peak 709 (which, in some examples, may be coincident with point 707, described in more detail below), may be within the range of 0.5 mm to 1.5 mm. Therefore, in some implementations, the distance G may be 0.5 mm, 0.6 mm, 0.7 mm, 0.8 mm, 0.9 mm, 1.0 mm, 1.1 mm, 1.2 mm, 1.3 mm, 1.4 mm, or 1.5 mm. However, the distance G can be selected to be any value within the indicated range, or a value greater or less than the indicated range. Line 710 corresponds to an interior surface of the first side wall 700 that defines passage 64 distant from and not forming part of ramp 708. A length L of ramp 708 along the cross section shown in FIG. 24 can be within the range of 8mm to 10mm. In other implementations, the length L of ramp 708 may be greater than 10 mm or less than 8 mm.

[0080] Referring to FIGs. 30-33 illustrated, the operation of the ramp 708 in elevating the driving haptic 450 above the optic 460 as the IOL 70 is advanced into the IOL injector 10. In operation, as the plunger rod 210 advances the IOL 70 along the distribution passage 127, the freely extending end 452 of the driving haptic 450 contacts and supports a driving surface 712 of the ramp 708. As the IOL 70 continues to be advanced, the driving haptic 450 is raised as it supports the driving surface 712. Elevation of the driving haptic 450 continues until the driving haptic 450 has obtained a sufficient height above the optics 460 of the IOL. For example, a height obtained by the driving haptic 450 as a result of supporting the driving surface 712 of the ramp 708 may be selected to ensure that the driving haptic avoids being retained on or distal from a driving edge 714 of the optic 460. Additionally , a position of the driving surface 712 of the ramp 708 longitudinally along the distal terminal portion 60 and a slope of the driving surface 712 may be selected such that the driving haptic 450 reaches a desired height above the optic 460 before or simultaneously with undulation. of the side edges 453 (shown in FIG. 14) of the optic 460 as the optic 460 begins to bend. A ramp 708 so configured ensures that the freely extending end 452 of the driving haptic 450 is threaded proximal to the driving edge 714 of the optic, and between the folded side sides 453 thereof. An illustration of this folding arrangement of the conduction haptic relative to the optics is shown in FIG. 19.

[0081] In the example shown in FIG. 24, the driving surface 712 is a smooth surface. That is, in some implementations, the driving surface 712 may be free from discontinuities or rapid changes in curvature. However, according to the invention, the driving surface 712 of the ramp 708 comprises a stepped surface. FIG. 25 shows a detailed cross-sectional view of an exemplary driving surface 712 of ramp 708 wherein the driving surface 712 includes a plurality of steps 716. In some examples, the driving surface 712 may be formed entirely of steps 716 In other examples, the driving surface 712 may have a plurality of steps along only a portion of its length. In other implementations, the sizes of one or more steps 716 may vary from the sizes of one or more other steps 716 of the driving surface 712.

[0082] In some implementations, each of the rungs 716 includes a riser 718 and a base 720. The base 720 extends in a direction parallel to a longitudinal axis 75 of the IOL injector 10, while the riser 718 extends in a direction perpendicular to the longitudinal axis 75 of the IOL injector 10. In some implementations, the rise 718 of one or more of the steps 716 may have a length in the range of 0.2 to 0.5 mm. Particularly, the length of rise 718 may be 0.2 mm, 0.3 mm, 0.4 mm, or 0.5 mm. However, these dimensions are merely examples. In other implementations, the length of rise 718 may be greater or less than the indicated range. That is, in some examples, the rise 718 may be greater than 0.5 mm or less than 0.2 mm.

[0083] The base 720 of one or more of the steps 716 may have a length in the range of 0.2 to 0.5 mm. Particularly, the length of the base 720 may be 0.2 mm, 0.3 mm, 0.4 mm, or 0.5 mm. However, these dimensions are merely examples. In other implementations, the length of base 720 may be greater or less than the indicated range. That is, in some examples, the base 720 may be greater than 0.5 mm or less than 0.2 mm.

[0084] Although FIG. 25 shows an exemplary driving surface 712 having a plurality of steps 716 that are uniform in size. Thus, in some implementations, with the driving surface 712 having a plurality of uniformly sized steps 716, the driving surface 712 defines a linear slope. However, the scope of disclosure is not so limited. Preferably, in other examples, one or more of the rise 718, the base 720, or both the rise 718 and base 720 of one or more of the rungs 716 may be different than one or more other rungs 716. In some example, the base 718 of the steps may decrease in the distal direction along the driving surface 712. In other implementations, the rise 718 of the steps may increase in the distal direction along the driving surface 712. In some examples, the rise 718 of the steps may increase in the distal direction along the driving surface 712. In other implementations, the rise 718 of the steps may decrease in the distal direction along the driving surface 712. In examples where the rise 718 and base 720 of one or more of the steps 716 vary, the driving surface 712 may define a fully curved surface or, more generally, a non-linear surface. In some implementations, the stepped driving surface 712 may be arranged to form a full parabolic shape for the driving surface 712. A full parabolic shape of the driving surface 712 may change an amount of lift imparted to the driving haptic 450 as a distance moved by the driving haptic 450 in the distal direction changes. Particularly, the amount of lift imparted to the driving haptic 450 may increase by rate of movement of the driving haptic 450 in the distal direction along the longitudinal axis of the passage 64 of the distal end portion 60. However, the overall shape defined by the driving surface 712 can be any shape desired. For example, the driving surface 712 may have an undulating inclined surface, a flat inclined surface, or any other desired surface.

[0085] A total slope of ramp 708 is defined by a line 703 extending from a point 705, a proximal end of ramp 708, to a point 707 at which line 705 tangentially touches the peak 709 of ramp 708. The line of inclination 703 is angularly deviated from the plane C by an angle T. In some examples, the angle T may be between 17° and 27°. Particularly, in some examples, the angle T may be 17°, 18°, 19°, 20°, 21°, 22°, 23°, 24°, 25°, 26°, or 27°. However, the angle T can be selected to be any value within the indicated range, or a value greater or less than the indicated range.

[0086] Referring to FIGS. 22, 24, and 25, the towing surface 713 of the ramp 708 gradually recedes into the inner surface 710 of the first side wall 700. In the example shown in FIG. 24, towing surface 713 has a positive slope as towing surface 713 extends distally. In some examples, the positive slope of the towing surface 713 is provided for production capacity of the IOL injector 10 and, particularly, for the distal end portion 60. In the case of injection molding, for example, a positive slope of the towing surface 713 is provided. trailer 713 provides a drift angle that facilitates production of the distal end portion 60. However, trailer surface 713 need not have a positive slope. In other implementations, the towing surface 713 may have a neutral slope, that is, a zero slope, or a negative slope. In still other implementations, the towing surface 713 of the ramp 708 may be omitted.

[0087] In some implementations, the third side wall 704 may also include the ramp 722 formed on an interior surface thereof, as shown in FIG. 22. In some examples, ramp 722 may blend with ramp 708. For example, in some examples, ramp 722 may be a continuation of ramp 708 that continues from the inner surface of the first side wall 700 onto the inner surface of the third side wall 704. In some implementations, ramp 722 may be omitted.

[0088] Ramp 722 includes a driving surface 723, a towing surface 725, and a spike 727 disposed between the driving surface 723 and the towing surface 725. Similar to the spike 709, the spike 727 extends along a width of the ramp 722 and separates the driving surface 723 from the towing surface 725. FIG. 26 is a cross-sectional view of the distal terminal portion 60 taken along the line C-C shown in FIG. 23. Line C-C represents a plane passing through peak 709 of ramp 708 and peak 727 of ramp 722. While peaks 709 and 727 are aligned at the exemplary distal terminal portion 60 illustrated in FIG. 21-26, the scope of disclosure is not thus limited. Preferably, peaks 709 and 727 can be shifted. In some examples, peak 709 may be disposed proximally from peak 727. In other examples, peak 709 may be disposed distally from peak 727.

[0089] As shown in FIG. 26, the peak 723 of the ramp 722 is disposed at an angle relative to the vertical axis 729, whereby the peak 709 of the ramp 708 is parallel with the horizontal axis 731. However, in other implementations, the peak 709 may be angled relative to the axis horizontal 731. In some examples, peak 723 may be parallel with vertical axis 729. Referring to FIG. 22, a surface 724 corresponding to an inner surface of the passage 64 of a distal end portion 60 that omits the ramp 722, is illustrated. Consequently, the difference in topography experienced by a driving haptic, such as driving haptic 450, in the examples with ramp 722 as opposed to that without ramp 722, is apparent. As shown in FIG. 26, surface 710 joins with surface 724 to form a representation of a continuous surface that would otherwise exist in passage 64 if ramps 708 and 722 were omitted.

[0090] The freely extending end 452 of the conduction haptic 450 engages the ramp 722 as the IOL 70 is advanced into the passage 64, and operates to restrict the distal movement of the conduction haptic 450 as the haptic The driving haptic 450 is being elevated by the ramp 708. As the IOL 70 continues to advance, the driving haptic 450 engages the driving surface 723 of the ramp 722. As a result, the distal movement of the driving haptic 450 is temporarily reduced. or ceased, such that the driving haptic 450 is folded over the surface 726 of the optic 460. As the advancement of the IOL 70 continues, a point is reached where the force applied to the driving haptic 450 in the distal direction as a result of the advance of the IOL 70 exceeds a resistive force applied to the driving haptic 450 by the ramp 722. As a result, the driving haptic 450 is deflected and forced past the ramp 722 with the driving haptic 450 folded over the optic 460, and adjacent to the surface 726. The point at which the driving haptic 450 is moved past the ramp 722 and folded onto the surface 726 of the optic 460 occurs just prior to the folding of the side sides 453 of the optic 460. The folded side sides 453 of the optic 460 capture the 450 driving optics between them and maintain the 450 driving optics in a folded configuration.

[0091] As explained above, ramp 708 and ramp 722 may be joined into a single topographic feature present within passage 64. In other implementations, ramp 708 and ramp 722 may be separate features formed in passage 64. Additionally , the driving surface 723 of the ramp 722 may be a smooth surface, that is, free discontinuities or rapid changes in curvature. However, similar to the driving surface 712 of the ramp 708, the driving surface 723 of the ramp 722 may have a stepped surface. FIG. 27 shows a detail view of the ramp 722 shown in FIG. 22. The ramp 722 includes a stepped driving surface 723 having a plurality of steps 730. In some examples, the driving surface 723 may be formed entirely of steps 730. In other examples, the driving surface 723 may have a plurality of steps along only a portion of its length. In other implementations, the sizes of one or more steps 730 may vary from the sizes of one or more other steps 730 of the driving surface 723.

[0092] In examples where the ramp 708 and the ramp 722 are joined, one of the driving surface 712 of the ramp 708 and the driving surface 723 of the ramp 722 may include one or more steps, while the other of the driving surface 712 of the ramp 708 and the driving surface 723 of the ramp 722, may omit the steps. In some examples, both the driving surface 712 and the driving surface 723 may include one or more steps. In still other implementations, both the driving surface 712 and the driving surface 723 may omit the steps.

[0093] In examples in which the driving surface 712 of the ramp 708 and the driving surface 723 of the ramp 722 include a plurality of steps, the rise and bottom of the steps of each of the driving surfaces 712 and 723 may be the same, or the rise and base of each of the driving surfaces 712, 723 may vary from each other. Additionally, a slope of each of the driving surfaces 712 and 723 may be the same or different from each other. In some examples, the rise and bottom of the steps of the driving surfaces 712 and 723 may vary both between the driving surfaces 712 and 723 and within each of the driving surfaces 712 and 723.

[0094] Each of the steps 730 includes a riser 732 and a base 734. The base 734 extends in a direction parallel to a longitudinal axis 75 of the IOL injector 10, while the riser 732 extends in a direction perpendicular to the longitudinal axis 75 of the IOL injector 10. In some implementations, the rise 732 of one or more of the steps 730 may have a length in the range of 0.2 to 0.5 mm. Particularly, the length of rise 732 may be 0.2 mm, 0.3 mm, 0.4 mm, or 0.5 mm. However, these dimensions are merely examples. In other implementations, the length of rise 732 may be greater or less than the indicated range. That is, in some examples, the rise 732 may be greater than 0.5 mm or less than 0.2 mm. In examples where the rise 718 and base 720 of one or more of the steps 716 vary, the driving surface 712 may define a fully curved surface or, more generally, a non-linear surface.

[0095] The base 734 of one or more of the steps 730 may have a length in the range of 0.2 to 0.5 mm. Particularly, the length of the base 734 may be 0.2 mm, 0.3 mm, 0.4 mm, or 0.5 mm. However, these dimensions are merely examples. In other implementations, the length of base 734 may be greater or less than the indicated range. That is, in some examples, the base 734 may be greater than 0.5 mm or less than 0.2 mm.

[0096] Although FIG. 27 shows an exemplary driving surface 723 having a plurality of steps 730 that are uniform in size. Thus, in some implementations, with the driving surface 723 having a plurality of uniformly sized steps 730, the driving surface 723 defines a linear slope. However, the scope of disclosure is not so limited. Preferably, in other examples, one or more of the rise 732, the base 734, or both the rise 732 and base 734 of one or more of the rungs 730 may be different than one or more other rungs 730. In some example, the base 734 of the steps may decrease in the distal direction along the driving surface 723. In other implementations, the base 734 of the steps may increase in the distal direction along the driving surface 723. In some examples, the rise 732 of the steps may increase in the distal direction along the driving surface 712. In other implementations, the rise 732 of the steps 730 may decrease in the distal direction along the driving surface 723. In examples where the rise 732 and base 734 of one or more of the steps 730 vary , the driving surface 723 may define a fully curved surface or, more generally, a non-collinear surface. In some implementations, the stepped driving surface 723 may be arranged to form an overall parabolic shape to the driving surface 723. However, the shape of the driving surface 723 may be any desired shape. For example, the driving surface 723 may have an undulating inclined surface, a defined flat surface, or any other desired surface.

[0097] FIG. 27 also shows a plane D that extends parallel to the longitudinal axis 75 of the IOL injector 10. The plane D passes through a first point 731 that defines a proximal end of the ramp 730. A total slope of the ramp 730 is defined by a line 733 extending from point 71 to a point 735 at which line 733 touches tangentially the peak 727 of ramp 730. Slope line 733 is angularly offset from plane D by an angle U. In some examples, angle U it can be between 63° and 73°. Particularly, in some examples, angle U may be 63°, 64°, 65°, 66°, 67°, 68°, 69°, 70°, 71°, 72°, or 73°. However, the angle U can be selected to be any value within the indicated range, or a value greater or less than the indicated range.

[0098] In the illustrated example shown in FIG. 27, ramp 722 is disposed distally from boundary 65 between compartment 80 and passage 64. Ramp 708 begins at a proximal end indicated by point 731. In some examples, a longitudinal distance H between point 731 and peak 709 ( which, in some examples, may be coincident with point 735) may be within the range of 0.4 mm to 1.4 mm. Therefore, in some implementations, the distance H may be 0.4 mm, 0.5 mm, 0.6 mm, 0.7 mm, 0.8 mm, 0.9 mm, 1.0 mm, 1.1 mm, 1.2 mm, 1.3 mm, or 1.4 mm. However, the distance H can be selected to be any value within the indicated range, or a value greater or less than the indicated range.

[0099] Referring to FIGS. 22, 26, and 27, the towing surface 725 of the ramp 722 gradually recedes into the inner surface 724 of the third side wall 704. In the example shown in FIG. 24, towing surface 725 has a positive slope as towing surface 725 extends distally. Similar to the towing surface 713 discussed above, in some examples, the positive slope of the towing surface 725 is provided for production capacity of the IOL injector 10 and particularly for the distal end portion 60. In the case of injection molding For example, a positive slope of the towing surface 725 provides a drift angle that facilitates production of the distal end portion 60. However, the towing surface 725 need not have a positive slope. In other implementations, the towing surface 725 may have a neutral slope, that is, a zero slope, or a negative slope. In still other implementations, the towing surface 725 of the ramp 722 may be omitted.

[00100] As shown in FIG. 26, a height F of passage 64 may be within the range of 2.4 mm to 2.6 mm. However, such dimensions are merely illustrative, and the height F of the passage may be greater than 2.6 mm or less than 2.4 mm. Additionally, a height E of the ramp 722 where the ramp 722 converges on the inner surface of the passage 64 (i.e., the inner surface of the passage 64 which is a continuation of the surface 724) may be within the range of 1.5 mm to 1, 8mm. However, in some implementations, the height E may be greater than 1.8 mm or less than 1.5 mm. The height D of ramp 708 at peak 709 may be within the range of 0.5 mm to 1.0 mm. As is apparent, the example dimensions provided are for the features indicated in the cross section along line C-C (shown in FIG. 27). Thus, in some implementations, the height E of ramp 722 may be within the range of 57% to 75% of the height E of passage 64. Also, in some implementations, the height F of ramp 708 may be within the range of 19 % and 42% of the height E of passage 64. Again, although the ranges indicated are illustrative only, and the heights D and E of ramps 708 and 722, respectively, relative to the height F of passage 64, may be selected to be any quantity desired.

[00101] FIG. 28 shows another exemplary elevation feature 800 disposed within the distribution passage 127 operable to elevate the driving haptic 450 of the IOL 70 over the surface 726 of the optic 460. In some implementations, the elevation feature 800 may be disposed in the passage. 64 of the distal end portion 60. For example, the elevation feature 800 may be attached to an upper surface (within the context of FIG. 29). That is, in some examples, the lifting feature 800 may be attached to a surface of the passage 64 that is adjacent to the interior surface 530 of the tip 90 (shown in FIG. 12), and opposite the receiving surface 190 (shown in FIG. 6). In the illustrated example, the lifting feature 800 is attached to an interior surface 802 of the passage 64. The lifting feature 800 includes a base 804, a hinge portion 806, and a hinge 808 that connects the hinge portion 806 to the base 804. Positions I to V shown in FIG. 28 illustrate the folding of the driving haptic 450 as the IOL 70 is advanced through the passage 64 relative to the optic 460.

[00102] In position I, the pivot portion 806 of the lifting feature 800 is shown in an initial non-distributed configuration with the driving haptic 450 just beginning to engage the pivot portion 806. In position II, the driving haptic conduction 450 is shown elevated in the direction of arrow 810 by an inclined surface 812 formed at the hinge portion 806. Additionally, the elevation feature 800 also causes displacement of the conduction haptic 450 toward the optic 460. In the context of advancing the IOL 70 , the movement of the driving haptic 450 toward the optic 460 means that the elevation characteristic 800 slows or slows the advancement of the driving haptic 450 relative to the optic 460, resulting in the relative movement of the driving haptic 450 toward the optic 460.

[00103] As a result of engagement with the driving haptic 450, the hinge portion 806 is shown slightly deflected distally in a direction of arrow 814. In position III, the driving haptic 450 is shown raised to a maximum amount by the characteristic of elevation 800 along with the hinge portion 806 displaced to a greater extent distally. Position III also shows a driving edge 816 of the optic 460 positioned below the driving haptic 450 (in the context of the view shown in FIG. 28). In position IV, the driving haptic 450 is shown lying over the surface 726, and the articulating portion 806 is additionally folded distally. In the V position, the driving haptic 450 is shown fully folded over the surface 726 of the optic 460. The pivot portion 806 is shown close to the driving haptic 450. Consequently, as the IOL 70 is advanced, a point is reached wherein the hinge portion 806 pivots about the hinge 808 to allow the driving haptic 450 to pass distally in the folding feature 800. Thereby, the folding feature 800 is operable to raise and fold the driving haptic 450, while also being operable to bend and allow the driving haptic 450 to move distally past the bending feature. As folding of the IOL 70 continues, the hinge portion 806 remains curved over the hinge 808 to allow the remainder of the IOL 70 to pass through.

[00104] In some implementations, the inclined surface 812 may be a smooth surface. In other implementations, the inclined surface 812 may include a plurality of steps similar to the steps 716 shown in FIGS. 25 and 27, for example.

[00105] In some implementations, the bending feature 800 may be formed from a flexible material having a lower hardness than a material that forms the IOL 70. Thus, the bending feature 800 is formed from a material that allows the IOL 70 contacts and slides against the bending feature 800, but prevents damage to the bending feature. However, in other implementations, the bending feature 800 may be formed from a material having a hardness that is greater than a material forming the IOL 70. For example, the bending feature 800 may be designed to eliminate sharp edges to prevent damage to the IOL 70 even though the material forming the bending feature 800 has a higher hardness than the material forming the IOL 70.

[00106] FIG. 29 illustrates another exemplary elevation feature 900 disposed within the distribution passage 127 operable to elevate the driving haptic 450 of the IOL 70 over the surface 726 of the optic 460. In some implementations, the elevation feature 900 may be disposed in the passage. 64 of the distal end portion 60. For example, the lifting feature 900 may be attached to a lower surface (within the context of FIG. 29). That is, in some examples, the lifting feature 900 may be attached to a surface of the passage 64 that is opposite the interior surface 530 of the tip 90 (shown in FIG. 12), and adjacent to the receiving surface 190 (shown in FIG. 6). In the illustrated example, the lifting feature 900 is attached to an interior surface 902 of the passage 64.

[00107] The lifting feature 900 includes a base 904, a pivot portion 906, and a hinge 908 that connects the pivot portion 906 to the base 904. The pivot portion 906 has a "V" shape that defines a first inclined surface 910 and a second inclined surface 912. The driving haptic 450 of the IOL 70 engages and slides along the first and second inclined surfaces 910 and 912 so as to elevate the driving haptic 450 above (in the context of FIG. 32). of the surface 762 of the optics 460.

[00108] Positions I to III shown in FIG. 29 illustrate the bending of the driving haptic 450 as the IOL 70 is advanced through the passage 64 relative to the optic 460. In position I, the hinge portion 906 of the elevation feature 900 is shown in an initial non-distributed configuration with the driving haptic 450 just beginning to engage the hinge portion 906. In position II, the driving haptic 450 is partially folded and raised in the direction of arrow 914 by the first and second inclined surfaces 910 and 912 formed on the hinge portion 906. As a result of engagement with the driving haptic 450, the pivot portion 906 is shown deflected distally in a direction of arrow 916 relative to the base 904, resulting in the inclined surface 912 forming a ramp that operates to further elevate the driving haptic. 450 above the top corner of the leading edge of the optic 760 (as seen in the context of FIG. 29). As is also illustrated in II, the elevation characteristic 900 also causes the driving haptic 450 to move toward the optic 460. In the context of advancing the IOL 70, the movement of the driving haptic 450 toward the optic 460 means that the Elevation feature 900 slows or slows the advancement of the driving haptic 450 relative to the optic 460, resulting in the relative movement of the driving haptic 450 toward the optic 460. In position III, the driving haptic 450 is shown raised above and folded over the optic such that the driving haptic 450 is located adjacent to the surface 762 of the optic 460. The bending feature 900 is shown on a side of the optic 460 opposite the driving haptic 450.

[00109] In some implementations, one or both of the inclined surfaces 910 and 912 may be a smooth surface. In other implementations, one or both of the inclined surfaces 910 and 912 may include a plurality of steps similar to the steps 716 shown in FIGS. 25 and 27, for example.

[00110] As the IOL 70 continues to advance along passage 64, the optic 460 presses against and slides over the bending feature 900, such that the hinge portion 906 is further bent. Similar to the bending feature 800, the bending feature 900 may be formed from a flexible material having a lower hardness than a material that forms the IOL 70. However, in other implementations, the bending feature 900 may be formed from a material having a hardness that is greater than a material forming the IOL 70. Similar to the bending feature 800 discussed above, in some examples, the bending feature 800 may be designed to eliminate sharp edges to avoid damage to the IOL 70 even although the material forming the bending feature 800 has a higher hardness than the material forming the IOL 70. Thus, the bending feature 900 is formed from a material that allows the IOL 70 to contact and slide against the bending feature 800. 900 bending capacity, but prevents damage to the bending characteristic.

[00111] The advancement of the plunger 30 through the injector body 20 is discussed below with reference to FIGS. 1, 6, and 11. In some examples, dimensional tolerances between the plunger 30 and the injector body 20 may allow relative movement between the plunger 30 and the injector body 20 such that the distal end portion 211 is capable of moves within hole 40 in the direction of arrows 471, 472 (hereinafter referred to as "tolerance movement"). In examples, particularly those in which the plunger 30 includes angled portion 212, the tip of the plunger 220 typically remains in contact with the interior wall 298 even if the plunger 30 experiences tolerance movement as the plunger 30 advances through the bore 40. Thus, in some examples, despite any tolerance movement, the tip of the plunger 220 remains in contact with the inner wall 298. Accordingly, the second tapered wall 303 directs and centers the tip of the plunger 220 in the opening 170.

[00112] If the plunger 30 experiences tolerance movement such that the tip of the plunger 220 no longer contacts the interior wall 298 of the hole 40, the first tapered wall 301, which includes the flexible wall portion 162, directs and centers the tip of the plunger 220 into the opening 170 formed in the interface 172, resulting in contact between the tip of the plunger 220 and the second tapered wall 303. When the plunger 30 becomes completely engaged with the injector body 20, the tolerance movement is substantially reduced or eliminated, ensuring that the tip of the plunger 220 remains engaged with the tapered second wall 303 and the contoured ramp 180. In some examples, full engagement between the plunger 30 and the injector body 20 occurs when the cantilever members 292 are completely engaged with the inner wall 298 of hole 40. Consequently, in examples where tolerance movement may exist, after full engagement between the plunger 30 and the injector body 20, the flexible wall portion 162 no longer influences the position of the plunger 30 In any case, once the tip of the plunger 220 advances through the opening 170, the flexible wall portion 162 no longer affects the directional path of the plunger 30, nor any part thereof.

[00113] As the plunger tip 220 is advanced through the housing 80 in sliding contact with the receiving surface 190, the first groove 500 of the plunger tip 220 is positioned to engage the IOL towing haptic, such as the trailer haptic 450 of the IOL 70, as shown in FIG. 6. As the plunger tip 220 is further advanced, the plunger tip 220 encounters the contoured ramp 180, and is forced vertically toward the tip 90. This vertical displacement of the plunger tip 220, while remaining in contact with the receiving surface 190, both bend the towing haptic over the optics of the IOL, as well as align the second groove 510 of the tip of the plunger 220 with a towing edge of the haptic. Particularly, the surface 502 of the plunger tip 220 contacts and displaces the haptic 450 as the plunger tip 220 is passed along the contoured surface 180, thereby bending the towing haptic 450. As the towing haptic 450 folds, the contoured surface 192 and wall 194 operate in concert to both locate the freely extending end 452 of the towing haptic 450 above and over the optic 460. The profile of the contoured surface 192 operates to raise the towing haptic 450 as the tip of the plunger 220 is moved toward the distal end portion 60 of the injector body 20. The wall 194 restricts lateral movement of the freely extending end 452 of the towing haptic 450, which causes the haptic to move distally relative to the optic 460. Consequently, the towing haptic 450 is both raised above and folded over the optic 460 as the tip of the plunger 220 contacts the towing haptic 450, and proceeds along the contoured ramp 180. As that the plunger tip 220 is further advanced, the second groove 510 accepts the towing edge of the optic 460, and the plunger tip 220 is displaced vertically away from the tip 90 due to a combination of influences from both the decreasing slope of the contoured ramp 180 and the angled portion 212 of the plunger rod 210. Movement of the plunger tip 220 in the manner described provides improved engagement and bending of the IOL 70.

[00114] FIG. 13 is a detail view of a portion of the distal end portion 60 of the injector body 20. The distal end portion 60 includes a tapered portion 62 and the insertion depth guard 140. The distal end 265 of the bias member 260 may engage the proximal end 50 of the injector body 20 to define a pause location of the bent or partially bent IOL. The nozzle 120 may include a demarcation 1900 that provides a visual indication of the pause position. For example, in the example shown in FIG. 13, the demarcation 1900 is a narrow ridge or line that surrounds all or a portion of the distal end portion 60. In some examples, the demarcation 1900 may be disposed between the tapered portion 62 and the insertion depth guard 140. At least one portion of the injector body 20 may be formed from a transparent or semi-transparent material that allows a user to see an IOL within the injector body 20. Particularly, the distal terminal portion 60 of the injector body 20 may be formed from a transparent material to allow observation of the IOL as it is moved through it by plunger 30.

[00115] FIG. 14 shows a view of the distal terminal portion 60 of the IOL injector 10 with the IOL 70 located therein in a paused position. As shown in FIG. 14, the IOL pause position may be defined as a location where the distal edge 462 of the optic 460 of the IOL 70 substantially aligns with the demarcation 1900. A haptic 450 or a portion thereof may extend beyond the demarcation 1900. Again, the pause position may also correspond to the initial engagement of the distal end 265 of the biasing member 260 with the proximal end 50 of the injector body 20. Therefore, the pause location may be jointly indicated by the positioning of the IOL, or part thereof, relative to the demarcation 1900 and the initial contact between the distal end 265 of the bias member 260.

[00116] In other examples, a location of the IOL relative to the distal opening 12 of the nozzle 120 when the distal end 265 of the biasing element 260 contacts the proximal end 50 of the injector body 20, may vary. In some examples, the IOL may be partially ejected from the distal opening 125 when the distal end 265 of the biasing member 260 contacts the proximal end 50 of the injector body 20. For example, in some examples, approximately half of the IOL may be ejected. ejected from the distal opening 125 when the distal end 265 of the biasing element 260 contacts the proximal end 50 of the injector body 20. In other examples, the IOL may be contained entirely within the IOL injector when the distal end 265 of the biasing element bias 260 contacts the proximal end 50 of the injector body 20.

[00117] FIG. 15 shows a cross-sectional view of the opening 170 formed in the interface 172. In some examples, the opening 170 may define a "T" shape. The tip of the plunger 220 is shown disposed in the opening 170 with the flexible wall portion 162 contacting a surface 214 of the plunger rod 210. In some examples, the cross-section of the plunger rod 210 increases toward the proximal end of the plunger rod 210. Thus, as the plunger rod 210 is advanced through the opening 170, the plunger rod 210 fills the opening as a result of the increased cross-section. Portions 173 and 175 of opening 170 are filled by flanges 213, 215 (shown in FIG. 9).

[00118] As the opening 170 is filled by the increased cross-section of the plunger rod 210 as the plunger rod 210 is advanced distally through the injector body 20, the flexible wall portion 162 is flexed in the direction of the arrow 471 to allow passage of the plunger rod 210, as shown in FIG. 16. Additionally, as a result of the angled portion 212 of the plunger rod 210, the contoured ramp 180, and the bending of the IOL 70 as it is advanced through the IOL injector 10, the plunger tip 220 is produced to follow a defined trajectory through the housing 80, the distal terminal portion 60, and nozzle 120 uninfluenced by the flexible wall portion 162.

[00119] FIG. 16 shows the flexible wall portion 162 being flexed in the direction of 471 as the plunger rod 210 continues to advance distally through the IOL injector 10. Additionally, FIG. 16 also shows the tip of the plunger 220 engaged with the IOL 70 such that the towing haptic 450 is received in the first slot 500 at a location offset from the second slot 510, and the proximal edge of the optic 460 is received in the second slot 510.

[00120] As the IOL 70 is advanced through passage 64 of the distal terminal portion 60, the IOL 70 is folded into a reduced size to allow passage of the IOL 70 through the nozzle 120 and into the eye. During bending of the IOL 70, a resistive force on the plunger 30 is increased. Once the IOL 70 is fully folded, the resistive force on the plunger 30 generally reduces.

[00121] A wound may be formed in the eye. The wound may be sized to accommodate the nozzle 120 of the IOL injector 10. The nozzle 120 may be inserted into the wound. The nozzle 120 may be advanced through the wound until the flanged surface 150 of the insertion depth shield 140 abuts the outer surface of the eye. The contact between the insertion depth shield 140 and the outer surface of the eye limits the depth to which the nozzle 120 can be inserted into the eye, preventing unnecessary stress on the edges of the wound, as well as preventing expansion of the wound due to insertion of the injector. IOL 10. Consequently, insertion depth protection 140 operates to reduce additional trauma to the eye and wound expansion.

[00122] With the nozzle correctly positioned inside the eye through the wound, the user can complete the distribution of the folded IOL into the eye. Referring to FIG. 2, as the advancement of the piston 30 continues, the biasing member 260 is compressed. Compression of the biasing element 260 increases a resistive force for advancing the piston 30, also referred to as a plunging force. This additional resistance to the advancement of the plunger 30 decreases the plunging force changes associated with bending the IOL prior to insertion into the eye. Additionally, in some examples, the biasing element 260 may be made to contact the injector body 120 when, or about when, the IOL 70 has completely bent, such that a reduction in the resistive force that may result from the IOL 70 being completely bent can be compensated for by compression of the biasing element 260. This increase in resistive force provided by compression of the biasing element 260, particularly in light of a reduction that may result due to the IOL 70 being completely bent, provides improved tactile feedback to a user, such as a medical community, during distribution of the IOL 70 to an eye. This improved tactile feedback provides the user with improved control during dispensing of the IOL 70, which can prevent rapid expulsion of the IOL 70 from the eye.

[00123] As a result, the user is able to provide a slight application of force without experiencing any sudden or rapid changes in the advancement of plunger 30. Such sudden or rapid changes may result in the IOL being rapidly expelled from an injector. Rapid expulsion of an IOL in one eye can cause damage such as perforation of the capsular bag. Such damage can increase the time required to compete with the surgical procedure, and can increase the damage caused immediately and post-operatively to the patient. After insertion of the IOL into the eye, the IOL 10 injector can be removed from the eye.

[00124] Although the disclosure provides numerous examples, the scope of the present disclosure is thereby not limited. Preferably, a broad range of modification, change, and substitution is contemplated in the foregoing disclosure. It is understood that such variations may be made to the foregoing without departing from the scope of the present disclosure.

Claims (14)

1. Intraocular lens injector (10) comprising: an injector body (20) comprising: a hole (40) defined by an interior wall (298); a longitudinal axis (75) extending centrally along the injector body (20); a distal end portion (60) comprising: a first side wall (700); a second side wall (702) disposed opposite the first side wall (700): a third side wall (704) extending between the first side wall (700) and the second side wall (702), and a fourth side wall (702), and a fourth side wall (702) 706) opposite the third side wall (704), the first side wall (700), the second side wall (702), the third side wall (704), and the fourth side wall (706) joined to define the passage (64 ) forming a portion of the hole (40): a first ramp (708) formed on an inner surface (710) of the passage (64) along the first side wall (700) and laterally offset from the longitudinal axis (75), the first ramp (708) disposed at a position within the passage (64) for contacting a conduction haptic (450) of an intraocular lens (70), the first ramp (708) comprising: (I) a first conduction surface (712 ) being inclined and extending inwardly from the inner surface in the passage (64): and (II) a first spike (709) disposed at a distal end of the first ramp (708) disposed at a distal end of the first driving surface (712); and a plunger (30) slideable in the hole (40), characterized in that the first driving surface (712) comprises a first plurality of steps (716) along it. 2. The intraocular lens injector of claim 1, wherein each step of the first plurality of steps (716) comprises a riser (718) and a base (720). 3. Intraocular lens injector according to claim 2, characterized in that the rise (718) and base (720) of each of the steps is uniform. 4. Intraocular lens injector according to claim 1, characterized in that the injector body (20) further comprises a compartment (80) configured to receive the intraocular lens (70), the compartment (180) being joins and is in fluid communication with the passage (64), and a boundary (65) is defined between the passage (64) and the compartment (80). 5. The intraocular lens injector of claim 1, further comprising a second ramp (722) formed on the inner surface of the passage (64) along the third side wall (702) and adjacent to the first ramp (708). 6. Intraocular lens injector according to claim 5, characterized in that the first ramp (708) and the second ramp (722) are formed integrally. 7. The intraocular lens injector of claim 5, wherein the second ramp (722) comprises a second driving surface (723), wherein the second driving surface (723) is inclined and extends inward from the inner surface of the passage (64). 8. The intraocular lens injector of claim 7, wherein the second ramp (722) further comprises a second spike (727) disposed at a distal end of the second conduction surface (723). 9. Intraocular lens injector according to claim 7, characterized in that the second conduction surface (723) comprises a second plurality of steps (730). 10. The intraocular lens injector of claim 9, wherein each step of the second plurality of steps (730) comprises a riser and a base. 11. Intraocular lens injector according to claim 10, characterized in that the rise (732) and base (734) of each step is uniform. 12. Intraocular lens injector according to claim 7, characterized in that the first conduction surface (712) and the second conduction surface (723) are formed integrally. 13. The intraocular lens injector of claim 1, wherein the first ramp (708) further comprises a first towing surface (713) disposed distally from the first spike (709). 14. The intraocular lens injector of claim 13, wherein the first towing surface (713) has a positive slope.