WO2010095938A1 - Ophthalmic lens with optical sectors - Google Patents
Ophthalmic lens with optical sectors Download PDFInfo
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- WO2010095938A1 WO2010095938A1 PCT/NL2010/050078 NL2010050078W WO2010095938A1 WO 2010095938 A1 WO2010095938 A1 WO 2010095938A1 NL 2010050078 W NL2010050078 W NL 2010050078W WO 2010095938 A1 WO2010095938 A1 WO 2010095938A1
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- Prior art keywords
- lens
- recessed
- ophthalmic lens
- optical
- lens according
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Classifications
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61F—FILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
- A61F2/00—Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
- A61F2/02—Prostheses implantable into the body
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- A61F2/16—Intraocular lenses
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- A—HUMAN NECESSITIES
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- A61F2/00—Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
- A61F2/02—Prostheses implantable into the body
- A61F2/14—Eye parts, e.g. lenses, corneal implants; Implanting instruments specially adapted therefor; Artificial eyes
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- A61F2/1602—Corrective lenses for use in addition to the natural lenses of the eyes or for pseudo-phakic eyes
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- A—HUMAN NECESSITIES
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- A61F—FILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
- A61F2/00—Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
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- A61F2/1613—Intraocular lenses having special lens configurations, e.g. multipart lenses; having particular optical properties, e.g. pseudo-accommodative lenses, lenses having aberration corrections, diffractive lenses, lenses for variably absorbing electromagnetic radiation, lenses having variable focus
- A61F2/1616—Pseudo-accommodative, e.g. multifocal or enabling monovision
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- A61F2/00—Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
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- A61F2/1613—Intraocular lenses having special lens configurations, e.g. multipart lenses; having particular optical properties, e.g. pseudo-accommodative lenses, lenses having aberration corrections, diffractive lenses, lenses for variably absorbing electromagnetic radiation, lenses having variable focus
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- A—HUMAN NECESSITIES
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- A61F2/00—Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
- A61F2/02—Prostheses implantable into the body
- A61F2/14—Eye parts, e.g. lenses, corneal implants; Implanting instruments specially adapted therefor; Artificial eyes
- A61F2/16—Intraocular lenses
- A61F2/1613—Intraocular lenses having special lens configurations, e.g. multipart lenses; having particular optical properties, e.g. pseudo-accommodative lenses, lenses having aberration corrections, diffractive lenses, lenses for variably absorbing electromagnetic radiation, lenses having variable focus
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61F—FILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
- A61F2/00—Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
- A61F2/02—Prostheses implantable into the body
- A61F2/14—Eye parts, e.g. lenses, corneal implants; Implanting instruments specially adapted therefor; Artificial eyes
- A61F2/16—Intraocular lenses
- A61F2002/1696—Having structure for blocking or reducing amount of light transmitted, e.g. glare reduction
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- G02C7/024—Methods of designing ophthalmic lenses
- G02C7/028—Special mathematical design techniques
Definitions
- the present invention relates to an ophthalmic lens comprising a main lens part and a recessed part.
- MIOL Multifocal Intra Ocular Lens
- haptics supporting parts
- Contrast sensitivity determines the lowest contrast level which can be detected by a patient for a given size target. Normally a range of target sizes are used. In this way contrast sensitivity is unlike acuity. Contrast sensitivity measures two variables, size and contrast, while acuity measures only size.
- Contrast sensitivity is very similar to auditory testing, which determines a patient's ability to detect the lowest level of loudness of various sound frequencies. The patient is asked to depress a button when the tone is just barely audible and release the button when the tone can no longer be heard. This procedure is used to test auditory sensitivity to a range of sound frequencies. If auditory testing were evaluated in a similar way to visual acuity, all the sound frequencies would be tested at one high level of loudness.
- US 4,923,296 which describes a lens divided into a series of substantially discrete near and distant vision zones. Not clear from this disclosure is how these vision zones could be made and or joined together.
- WO 92/06400 describes a aspheric ophthalmic lens. The surface zones are defined three dimensionally forming a junctionless, continuous and smooth surface in conjunction with one another. It will be clear to a person skilled in the art that such a lens will suffer a large decrease of optical quality.
- US4921496 describes a rotation symmetric, radially segmented IOL. That IOL has no junctions at the surface, since the materials for each segment should have different refractive indices to create the different powers.
- a lens with a distance part and a near part is described in EPO858613(B1) and US6409339(Bl) by Procornea Holding B.V. from the current inventor, and which are incorporated by reference as if fully set forth.
- These documents disclose contact lenses, but also refer to IOL's.
- a lens of this type differs from other lenses in that the reading part is located within the (imaginary) boundary of the distance part. That is to say the reading part is on or within the imaginary radius of the outer boundary of the distance part (Rv). If a reading part is used this is preferably made as a sector which extends from the centre of the lens. This lens proved to have many possibilities. There is, however, room for further improvement.
- US-7.004.585 discloses a multifocal contact lens having a blended design for a segmented optical zone.
- the contact lens should move on the eye easily in order to make the lower reading zone available.
- a transition or blend zone should be designed to avoid blur and ghost images.
- the blend zone should have a smooth transition to improve wearers comfort.
- the blend zone should include a curvature magnitude to refract light away from the macular region of the eye.
- the various optical zones should influence each other as little as possible. In this document, patentee seems to have identified that problem.
- the ophthalmic lens design can be further improved, however. In particular for IOL devices, there is room for further improvement.
- the invention provides an ophthalmic lens comprising a main lens part having a surface, a recessed part having a surface which is recessed with respect to said surface of said main lens part, an optical centre, and an optical axis through said optical centre, said main lens part having at least one boundary with said recessed part, said main lens part having an optical power of between about -20 to about +35 dioptre, said recessed part positioned at a distance of less than 2 mm from said optical centre and comprising a near part having a relative dioptre of about +1.0 to about +5.0 with respect to the optical power of said main lens part, said boundary or boundaries of said recessed lens part with said main lens part form a blending part or blending parts, are shaped to refract light away from said optical axis and have a curvature resulting in a loss of light, within a circle with a diameter of 4 mm around said optical centre, of less than about 15%, said loss of light defined as the fraction of the amount of in- focus light from the IOL
- This ophthalmic lens allows various optical parts to be integrated in one single lens in such a way that they influence one another as little as possible. For instance, it allows an ophthalmic lens with a reading part is such a way that distance vision, intermediate vision and near vision influence each other little to not. In fact, it was found that we were able to significantly increase contrast sensitivity of ophthalmic lenses. In the past a lens would be designed to cause as little disturbance as possible. In the current invention, it was found that sharp transitions can be allowed, as long as they cause light to be refracted away from the optical axis.
- light is defined as light in the visual wavelength range. Usually this is between about 400-700 nm.
- the amount of in- focus light is the sum of focussed light in all the main focal planes of the IOL.
- the lens will usually have two focal planes, one for the main lens part and one for the recessed part. If the optical area of the recessed part is 30% of the entire lens area and the area of the main lens part is 70%, and there is no further loss, then 30 % of the focussed light will be available in the focal plane of the recessed part and 70% of the focussed light will be available in the focal plane of the main lens part..
- the lens comprises at least one recessed, semi-meridian optical sector which is radially and/or angularly subdivided into subzones. It thus may comprise an inner sector, an intermediate sector, and an outer sector, located within the (imaginary) boundary of the lens part.
- the inner sector has a first optical power
- the intermediate sector which is adjacent to the inner sector has a second optical power.
- the outer sector adjacent to the intermediate sector has a third optical power.
- the step height between the boundaries of the semi-meridian sectors are joint by means of an optimised transition profile to maximize light energy directed to the macula and to reduce blur and halo's at bigger pupil sizes.
- the ophthalmic lens semi-meridian sectors can have a continuous power profile.
- optical sub circle sectors are blended together. Combinations thereof are also possible.
- the subdivided sector(s) will provide a clear vision at reading and intermediate distances, whereas the distance vision and contrast sensitivity remain comparable with an monofocal ophthalmic lens.
- the present invention may also be configured to provide lenses which perform well in eyes with varying corneal aberrations (e.g., different asphericalities), including spherical aberration, over a range of decentralization, i.e. deviation between the optical axis or centre of the lens and the optical axis of the eye. This means that positioning of the IOL becomes less critical.
- corneal aberrations e.g., different asphericalities
- spherical aberration e.g., different asphericalities
- the ophthalmic lenses of the invention may comprise more than three subdivided semi-meridian or semi-meridian sector zones.
- the opposite surface of the lens may comprise an aspheric surface such that the residual spherical aberration will be reduced to about zero.
- an aspheric surface such as described in, but not limited to EP1850793, 1857077 or US2006279697 incorporated herein by reference.
- the semi-meridian recessed refractive reading part can comprise boundaries at all sides, and may even comprises an additional diffractive optical element (DOE) structure, for instance such as described in, but not limited to, EP0888564B1 or EPl 194797B1, incorporated herein by reference.
- DOE diffractive optical element
- Another object of the invention is to provide a method and optimized curves to optimise and improve the steepness of the transition profile to bridge height differences between parts of the lens.
- These blending parts improved the transition between various parts. Using these blending parts will reduce loss of light energy and maximizes the usable optical area(s) significantly.
- the step height differences at for instance semi- meridian boundaries may be bridged by methods using a cosine trajectory or sigmoid function.
- optimised transition function are proposed.
- These derived transition functions consistent with the outcome of the optimised profile function are consistent with the embodiments of the invention.
- the dimension and/or optical power ratio between various parts for instance a semi- meridian subdivided reading part and a distance part, may mutually vary.
- one lens can be configured for the dominant eye and the other lens for the non-dominant eye. That is to say, the lens for one eye has a different configuration for the reading part or distance part than the lens for the other eye.
- Pupil size is a function of the weighted average of the luminances (popularly called brightness) within the field of view. Pupil size is influenced much more by the part of the retina associated with central, or foveal, vision than by the outer areas of the retina.
- a customized recessed semi-meridian lens could be designed by using certain field brightness conditions to calculate the optimal central part and or reading part in relation to the specific pupil diameter.
- further corrections can be made in the lens sectors to optimize or correct particular optical abnormalities.
- a further structure which makes it possible to correct all kinds of optical abnormalities, such as but not limited to astigmatism and spherical aberration, can be arranged at the anterior or posterior side of the current lens.
- the recessed part for instance formed as a semi-meridian reading sector, is positioned in the eye in an embodiment at the lower part or bottom (inferior) of the lens because this corresponds to the natural inclination of people to look down when reading.
- the positioning of the semi-meridian reading sector in the eye is not critical and can be positioned Superior, Inferior, Nasal or Temporal. Distant and near sectors can even be disposed in opposite arrangement for the two eyes of one person.
- the ophthalmic lens or mould described herein can be made in any way known in the art.
- an intraocular lens for instance, it is in addition possible to make the lens part and the haptic separately and to connect them together later.
- these parts are made as one entity by (injection) moulding.
- a subsequent processing for producing the proper lens parts can be turning.
- a tool bit can be moved every revolution towards and away from the lens in the direction parallel to the rotational axis. This makes it possible to produce the lens part by turning. It is also possible according to an embodiment to perform the turning so finely that a subsequent polishing operation can be omitted.
- the material of the lens can be any desired material.
- the novel ophthalmic lens optic configuration for example can also be used for contact lenses and for pseudophakic intra-ocular lens patients as a so called ,,add on lens".
- This is an extra or additional lens which can be placed in front of a existing natural lens or in front of a artificial intra ocular lens to correct refraction errors and or to restore reading capabilities.
- the add-On lens could be placed in the bag, the sulcus, as cornea inlay or as a anterior chamber lens.
- modern lens power mapping apparatus such as the High resolution Hartmann Shack system "SHSInspect Ophthalmic", commercial available from Optocraft Germany, it is possible to determine the local refractive powers and a wide range of relevant surface variations. Such measurements can therefore identify a lens made in accordance with the present invention very easy.
- the curvature results in a loss of light, within a circle with a diameter of 4 mm around said optical centre, of between about 2% to about 15%.
- the recessed part extends further than 4 mm in radial direction.
- the main lens part has an optical power of between about -10 to about +30 dioptre.
- the recessed part is positioned at a distance of less than 1.5 mm from said optical centre.
- the distance is defined as the nearest radial distance from the optical centre.
- the near part has a relative dioptre of about +1.50 dioptre to about +4.00 dioptre with respect to said main lens part.
- the optics of the central part as well as of the main lens part and of the recessed part can furthermore be designed to be toric, cylindrical or be designed to compensate higher order aberrations. These types of lens design are as such known to a skilled person, and can additionally be applied to the various lens parts of the current invention.
- the semi-meridian boundary or boundaries of said recessed lens part with said main lens part have a curvature resulting in a loss of light, within a circle with a diameter of 4 mm around said optical centre, of below about 10%. This very low loss of light, in particular in combination with the refraction away from the optical axis, already results in a higher contrast sensitivity and good reading ability.
- the main lens part has a curvature with substantially a curvature radius Rv, and the outer limit of the recess, i.e. its surface, lies on or within the curvature radius Rv.
- the ophthalmic lens further comprises a central part which has a relative optical power of -2.0 to +2.0 dioptre with respect to said main lens part.
- a central part which has a relative optical power of -2.0 to +2.0 dioptre with respect to said main lens part.
- the size of said central part is such that it fits within a circumscribing circle with a diameter of about 0.2-3.0 mm. Thus, it was found that distance vision would be influenced as little as possible by the recessed part. In an embodiment, the size of said central part is such that it fits within a circumscribing circle with a diameter of about 0.2-2.0 mm. In an embodiment, said central part is substantially circular.
- the lens comprises a further blending part between the central part and the recessed part.
- This blending part usually is concentric or almost concentric with respect to the optical axis.
- the further blending part has a smooth transition.
- the slope has a kink.
- the first derivative of the slope is discontinuous.
- the curvature radius of the surface has a kink.
- the recessed part is bounded by semi meridians running though said optical centre, the recessed part thus having the shape of a meridian zone.
- the blending parts which blend the main lens part and the recessed part thus follow meridians as much as possible.
- such a blending part will be arranged between two semi meridians running through the optical centre.
- said recessed part is at at least one boundary bounded by said central part.
- said central part has a cross section of about 0.60-1.20 mm. This allows a recessed part which influences for instance contrast sensitivity as little as possible.
- said recessed part has an included angle of about 160 - 200 degrees.
- at least two boundaries with the main lens part substantially follow meridians.
- these boundaries are formed by blending parts.
- usually such a blending parts is clamped between two semi meridians.
- the blending part will not exactly follow a meridian, but will be slightly curved.
- said recessed part has an included angle of about 175-195 degrees.
- the ophthalmic lens has a cross section of about 5.5-7 mm.
- an intraocular lens, or another oculary supported lens like a contact lens it will to in such a diameter range.
- the main lens part is in the form of a distance lens.
- the recessed part forms a reading part.
- said recessed part is bounded by two semi meridians and a line of latitude concentric and at a distance from said central part.
- said recessed part comprises at least two sub-zone having optical powers which differ.
- these sub-zones are concentric.
- optical powers of said sub-zones increase in radial direction. In an embodiment optical powers of said sub-zones decrease in radial direction
- the optical power of the recessed part increases in radial direction.
- the blending between these increasing optical power regions or zones should be designed carefully. It may require compensation of less step height in blending parts.
- said recessed part comprises a diffractive optics part.
- the diffractive optics may be superposed unto the surface of the recessed part.
- a diffractive optical superposed part on a lens surface is known. In case of a recessed part, however, it may allow the recessed part to be less deep.
- the recessed part comprises a first, central subzone and two further subzones circumferentially neighbouring at both sides of said first subzone.
- said first subzone has an optical power larger than the optical power of the further subzones.
- the two further subzones have an optical power larger than the optical power of said remaining lens part.
- meridians bound said recessed part.
- two semi-meridians bound said recessed part, thus defining the recessed part as a sector part or wedge part (like a wedge of pie). If the ophthalmic lens has a central part as defined above, this sector part has a part from the forming a sector part having a part of the tip taken away.
- the blending parts are within meridian which enclose an angle of less than 17°, in a particular embodiment less than 15°. In an embodiment, blending parts can even be designed to be within meridian which enclose an angle of less than 5°. This, however, requires a very careful design of the curves and slopes or derivatives of the curves.
- said slope of the blending parts has an S-curve and have a steepness with a slope or first derivative at a central range of the blending part at 1.6 mm from said optical centre of more than 0.1, in an embodiment more than 0.4 at its steepest part.
- said blending parts have a steepness with a slope or derivative at a central range of the blending part at 2.8 mm from said optical centre of more than 0.2, in an embodiment more than 0.7 at its steepest part.
- At least one of said blending parts in particular at least one semi meridian blending part, has an S-shaped curve which follows a first parabolic curve running from the main lens part surface towards the surface of the recessed part, having an intermediate curve part connecting to said first parabolic curve, and continuing with following a second parabolic curve ending at the recessed surface.
- said intermediate curve part at its steepest part has a first derivative of at least 0.05 at 0.4 mm from said optical centre, in an embodiment at least 0.1 at 0.8 mm, in an embodiment at least 0.15 at 1.2 mm, in an embodiment at least 0.2 at 1.6 mm, in an embodiment at least 0.3 at 2.0 mm, in an embodiment at least 0.4 at 2.4 mm, in an embodiment at least 0.5 at 2.8 mm.
- the invention further pertains to an add-on intraocular lens to be inserted in the bag, the sulcus, as cornea inlay or an anterior chamber lens, comprising the ophthalmic lens according to any one of the preceding claims, wherein said main lens part has an optical power of about -10 to +5 dioptre.
- the invention further relates to an ophthalmic lens comprising a main lens part having substantially a curvature radius Rv, a substantially circular central part having a first optical property and having a cross section of about 0.2-2.0 mm, and a meridian part comprising a recess which is bounded by said substantial circular central part, by two meridians running through the centre of said circular part, and by a lower boundary which is substantially concentric with respect to said circular part, said meridian part formed as a recess in said lens, the outer limit of the recess lying on or within the curvature radius Rv, said meridian part comprising a reading part.
- the invention further relates to a method for the production of one of the ophthalmic lenses described above, comprising a step of turning, in which a lens blank is positioned on a rotating machining holder and is subjected to the influence of one or more material-removing devices, characterized in that during the turning step the rotating lens and said material-removing device are moved to and away from one another in the direction of the axis of rotation, in order to form at least one recessed portion in said ophthalmic lens.
- This production method allows production of lenses having the properties required.
- the invention further relates to an ocularly supported multifocal corrective lens provided with a substantially circular central lens portion, a lower lens portion in a lower lens part neighbouring said central lens portion, and a further lens portion, the lower lens portion comprises a recess comprising two sides which run from said central lens portion towards the rim of the lens, the outer limit of the lower lens portion lies on or within an imaginary sphere having its origin and radius of curvature coinciding with the radius Rv of said further lens portion, wherein said two sides provide sloping from the further lens portion surface to the recessed surface of the lower lens portion, said sloping following a first parabolic curve running from the further lens portion surface towards the lower lens portion surface, and continuing with following a second parabolic curve ending at the recessed surface.
- the invention further relates to an ophthalmic lens comprising a main lens part, a recessed part, an optical centre, and an optical axis substantially through said optical centre, said main lens part having at least one boundary with said recessed part, said recessed part positioned at a distance from said optical centre, boundaries of said recessed lens part with said main lens part are formed as blending parts which are shaped to refract light away from said optical axis, said main lens part, central part, recessed part and blending parts mutually positioned and shaped for providing a LogCS characteristic under photopic light conditions, usually at about 85 cd/m 2 , within 6 months post operative, in a spacial frequency (cpd) between 3-18 which is at least between the population norm of 11-19 years and 50-75 years.
- a spacial frequency (cpd) between 3-18 which is at least between the population norm of 11-19 years and 50-75 years.
- this lens in a spacial frequency (cpd) between about 6 and 18, its LogCS characteristic under photopic light conditions, within 6 months post operative, usually at about 85 cd/m 2 , is in the range of normality above the population norm of 20- 55 years old adults with healty eyes.
- the invention further relates to an intraocular lens comprising a main lens part, a recessed part positioned at a distance from an optical centre, and a central part in said optical centre and which is substantially circular, has a diameter of about 0.8 to 2.8 mm, and at one side bounding said recessed part, wherein the diameter of said central part is adapted to the pupil diameter of the wearer.
- the diameter of said central part is about 20-40 % of the pupil diameter of the wearer at office lighting conditions, i.e. 200-400 lux.
- the IOL can be custom-made.
- MSOL Multifocal Sector Ophthalmic Lens
- Figure 1 a cross section of a human eye
- Figure 2 a cross section of a human eye with an IOL
- Figure 3 a front view of an embodiment of an MSIOL with an optical central part and a recessed part
- Figure 4 a side view of the MSIOL according to Figure 3;
- Figure 5 a cross sectional view over line IV of the MSIOL according to Figure 3;
- Figure 6 a detail of the cross section according to Fig 5;
- Figure 7 a perspective front side view of the MSIOL according to Fig 3;
- Figure 8 a perspective back side view of the MSIOL according to Fig 3;
- Figure 9 a front view of another embodiment of an MSIOL with a recessed part subdivided in three meridianally divided optical sectors and one central optical sector;
- Figure 10 a side view of the MSIOL according to Figure 9;
- Figure 11 a perspective front side view of the MSIOL according to Figure 9;
- Figure 12 a front view of a further variant of the MSIOL with a recessed diffractive semi-meridian sector element
- Figure 13 a side view of the MSIOL according to Figure 12;
- Figure 14 a cross sectional view over line XIV of the MSIOL according to Figure 12;
- Figure 15 a detail of the cross section according to Fig 14;
- Figure 16 a perspective front side view of the MSIOL according to Fig 12;
- Figure 17 a comparison between a optimised transition trajectory and cosine trajectory of a transition or blend zone or part, illustrating that in the same time with the optimised profile a larger displacement is possible;
- Figure 19 the experienced or effective acceleration (second derivative) during the sigmoid transition
- Figure 20 the reduction of the transition zone width by calculating the needed transition time and distance according the method described in this document locally, the transition zone width is zero near the centre;
- Figures 21-26 graphs showing the energy distribution in various parts of several embodiments of ophthalmic lenses
- Figures 27-29 measured data of ophthalmic lenses
- Figures 33 and 34 test results showing the LogCS against the spatial frequency
- Figure 35 showing a surface model of one of the embodiments
- Figure 36 a schematic setup of measuring instrument PMTF.
- anterior optical sectors are preferably concentric with the geometric centre of the posterior surface
- a “vertical meridian” refers to an imaginary line running vertically from the top, through the centre, to the bottom of the anterior surface of an MSIOL when said MSIOL is maintained at a predetermined orientation into the eye
- a “horizontal meridian” refers to an imaginary line running horizontally from the left side, through the centre, to the right side of the anterior surface of an MSIOL when said MSIOL is maintained at a predetermined orientation into the eye.
- the horizontal and vertical meridians are perpendicular to each other.
- “Surface patches” refer to combinations of curvatures and lines that are continuous in first derivative, preferably in second derivative, from each other.
- a “semi-meridian” refers to an imaginary line running radially from the geometric centre of the anterior surface of an MSIOL to the edge of the lens.
- the "upper portion of the vertical meridian” refers to one half vertical meridian that is above the geometric centre of the anterior surface of an MSIOL, when said lens is maintained at a predetermined orientation inside an eye.
- the "lower portion of the vertical meridian” refers to one half vertical meridian that is below the geometric centre of the anterior surface of an MSIOL, when said lens is maintained at a predetermined orientation inside an eye.
- a “continuous transition”, in reference to two or more sector, means that the slope of these sectors are continuous at least in first derivative, preferably in second derivative.
- a “vertical meridian plane” refers to a plane that cuts through the optical axis of an MSIOL and a vertical meridian on the anterior surface of the MSIOL.
- Baseline Power As used herein in reference to the sectors or parts of an MSIOL the terms “Baseline Power”, “optical power” , “Add Power” and “Dioptre power” refer to the effective optical or Dioptre power of a sector when the lens is part of an ocular lens system such as for instance a cornea, a MSIOL, a retina and the material surrounding these components. This definition may include the effects of the divergence or angle of light rays intersecting the MSIOL surface caused by power of the cornea. In certain instances, an algorithm for calculating the Dioptre power may begin with a ray-tracing model of the human eye incorporating a subdivided sector MSIOL.
- Snell's law may be applied to calculate the angle of the light ray following the refraction.
- the optical path length of the distance between a point on the surface and the optical axis (axis of symmetry) may be used to define the local radius of curvature of the local wave front.
- the Dioptre power is equal to the difference in indices of refraction divide by this local radius of curvature.
- the present invention aims to improve ophthalmic lenses, and in one aspect relates to an novel Multifocal Sector Intra Ocular Lens (MSIOL) with at least two semi-meridian optical sectors where at least one of the semi-meridian optical sectors is radial or angular subdivided and could comprise an inner sector, an intermediate sector, and an outer sector, located within the (imaginary) boundary of the distance part.
- the inner sector has a first optical power
- the intermediate sector adjacent to the first optical power has a second optical power.
- the outer sector adjacent to the second optical power has a third optical power whereas the step height between the boundaries of the semi-meridian sectors are joint by means of a optimised transition profile to maximize light energy directed to the macula and to reduce blur and halo's at bigger pupil size.
- the ophthalmic lens semi-meridian sectors could have a continuous power profile or the discrete optical sub circle sectors blend together or combinations thereof.
- the subdivided sector(s) will provide a clear vision at reading and intermediate distances. Whereas the distance vision and contrast sensitivity remain comparable with an mono focal ophthalmic lens with reduced blur and halo's at bigger pupil size.
- the present invention may also be configured to perform well across eyes with different corneal aberrations (e.g., different asphericities), including the spherical aberration, over a range of decentration.
- the ophthalmic lens may be designed to have a nominal optical power for distance vision, defined as "Baseline Power", usually of the main lens part, an "Add power” added on top of the nominal optical power or Baseline power, and intended for the reading vision. Often, also an intermediate optical power is defined suited for the particular environment in which it is to be used. In case of an MSIOL, is anticipated that the nominal optical power or baseline power of an MSIOL will generally within a range of about -20 Dioptre to at least about +35 Dioptre. The "Add power" will generally be in a range of about +1 Dioptres to at least about +5 Dioptre.
- the nominal optical power of the MSIOL is between about 10 Dioptres to at least about 30 Dioptre, the "Add power" will be between about +1.50 and +4.00 Dioptre.
- the nominal optical power of the MSIOL is approximately +20 Dioptre, and the Add power about +3.00 Dioptre, which is a typical optical power necessary to replace the natural crystalline lens in a human eye.
- FIG 1 a schematic view of a human eye 100 with its natural lens 106 is shown.
- the eye has a vitreous body 101 and cornea 102.
- the eye has an anterior chamber 103, iris 104 and ciliary muscle 105 which hold the lens.
- the eye has a posterior chamber 107.
- the eye 100 is shown with an intra ocular lens 1 replacing the original lens 106.
- an embodiment of an intra ocular lens (IOL) 1 which has haptics 2 and a lens zone or lens part 3.
- the lens part 3 is the actual optically active part of the IOL 1.
- the haptics 2 can have a different shape.
- lens part 3 has a central part 6 which is usually substantially circular. It may deviate a little from an absolute circle, but in most embodiments it is as round or circular as possible in the specific further lens design.
- the lens part 3 further has a meridian part in a recess area. This recess is below the surface of the curved surface of the remaining lens part 4 of lens part 3.
- the curved surface of the remaining lens part 4 has a radius of curvature Rv, and the recess of the meridian part lies on or within the curvature radius Rv (see figure 4).
- curved surface of the lens part can be non-spherical or aspheric.
- the curved surface can be as described in for instance US-7.004.585 in columns 6, 7 and 8.
- the Zernike polynomials can be used to describe any curved surface of an ophthalmic lens.
- the meridian part is divides into two concentric sub-zones 7 and 8.
- the various parts i.e. the central part 6, inner meridian part 7 And outer meridian part 8, each have a have an angle of refraction or power which differs from the remaining lens part 4.
- the central part 6 can also be defined as bounded by a first line of latitude.
- sub-zone 7 can be defined as bounded by two meridians, the first line of latitude and a second line of latitude.
- sub-zone 8 can be defined as bounded by the two meridians, the second line of latitude and a third line of latitude.
- the meridian part in cartography an area of this shape is also referred to as "longitudinal zone" is referred to as a "reading part".
- the MSIOL comprises a near part or reading part which is bounded on or within the lens zone 3 whereas the transition between those parts is performed with a cosine function or sigmoid function, but desirably joined with the optimized transition function discussed below.
- these general transitions curves are referred to as S-shaped curves. These transitions have a width and are referred to as blending zone or transition zone.
- the near or reading part in an embodiment has an included angle ⁇ between about 160 and 200 degrees. In a further embodiment, the included angle is between about 175 and 195 degrees.
- the reading part can optically be sub divided into at least two imaginary circle sectors 7 and 8, forming a continuous transition surface radial about the optical axis or geometric axis.
- the required shape (and curvature of the recessed surface) of those circle sectors 7, 8 can be calculated using ray tracing to control at least the amount of spherical aberration and further to avoid image jumps.
- the reference lines in the lens part 3 are imaginary and for dimensional reference purpose. They are, however, not visible in the real product.
- the lens part 3 in this embodiment has an outer diameter between about 5.5 and about 7 mm. In a preferred embodiment, it is about 5.8-6.2 mm.
- the central part or inner sector 6 has a optical power at least equal to the baseline power. Desirably, the optical power of the inner circle sector or central part 6 is between 0% and 100% of the Add power.
- the central part 6 in an embodiment has a diameter of between about 0.2 mm and 2.0 mm. In an embodiment, the diameter of the central part 6 is between about 0.60 and 1.20 mm. In case the central part 6 is not absolutely round, it is a circumscribing circle having the diameter range mentioned here. Circle Sector or central part 6 has a optical power at least equal to the baseline power. In this embodiment, the recessed part has two indicated subzones, a first subzone 7 near the central part 6. This inner subzone has a latitude radius of between about 1.5 and 2.3 mm. In an embodiment, it is between about 1.8 and 2.1 mm. The outer subzone 8 has an optical power equal or greater than the baseline power. In an embodiment, the optical power is between 0 and 100% of the Add power.
- the latitude radius of outer subzone 8 has a dimension between about 2.2 and 2.7 mm. In an embodiment, it can be between about 2.3 and 2.6 mm. In this embodiment, the main lens part almost continues at part 9.
- the outer limit radius where the lens main lens part 4 continues can have a latitude radius of between about 2.6 and 2.8 mm.
- several concentric subzones can be provided in order for the recessed part to disturb or influence the central part for distance vision as little as possible.
- the IOL 1 has two semi meridian blending zones or blending parts 10 bounding the recessed part 7, 8. These semi meridians bounding blending parts 10 have an angle ⁇ . In an embodiment, the angle will be less than 35°. In an embodiment, it will be less than 17°. In particular, the angle ⁇ will be less than 5°. Usually, it will be more than about 1°.
- the recessed part in this embodiment further has a blending zone 11 which is concentric with respect to the optical axis R.
- Main lens part 4 continues in the concentric region indicated with reference number 9.
- FIG. 9-11 several view of another example of an ophthalmic lens is shown, as an Intra ocular lens.
- the recessed part is divided into subzones.
- the two outer subzones 7 are angularly arranged at both sides of a central subzone 8'.
- the MSIOL comprises a main lens part 4 with a recessed part with a total included angle ⁇ between 160 and 200 degrees, desirably between 175 and 195 degrees.
- the included angle of the outer subzones 7 is between about 10 and 30 degrees. In an embodiment, it is between about 15 and 25 degrees.
- the included angle ⁇ of the central subzone 8' is between about 80 and 120 degrees. In an embodiment, the central subzone 8' is between 85 and 100 degrees.
- the total included angle of the subzones 7, 8' for near and intermediate vision are bounded by the main lens part 4.
- the transitions or blend zones between the various parts follow a cosine function or sigmoid function. In an embodiment, they follow an optimized transition function described below. Due to this optimized transition profile at least one of those imaginary transition lines will be curved.
- the subzones 7 and 8' are radial arranged around the geometric axis.
- the optical shape of those circle parts are ray traced to control the amount of spherical aberration and further to avoid image jumps.
- the reference lines in the lens parts are imaginary and for dimensional reference purpose only and are not visible in the real product.
- the lens part has a outer diameter dimension between 5.5 and 7 mm. In an embodiment, the diameter is about 6 mm.
- the central part 6 has a optical power at least equal to the baseline power of the main lens part.
- the diameter of central part has a diameter of between about 0.2 mm and 2.0 mm. In an embodiment, the diameter is between about 0.40 and 1.20 mm.
- the recessed part can have a radial width of between about 1.5 and 2.3 mm.
- the width is between about 1.8 and 2.1 mm.
- the outer subzones 7 have a optical power of about 30 to 60 % of the Add power, i.e. about 30-60 % of the relative dioptre of the central part 8'.
- the MSIOL as shown in figures 3-8 may also be used in conjunction with another optical device such as a Diffractive Optical Element (DOE) 20.
- DOE Diffractive Optical Element
- That MSIOL comprises a recessed lens part 7 shaped as a refractive semi-meridian part having a first optical power.
- the total included angle ⁇ of the recessed part can be between about 160 - 200 degrees.
- the enclosed angle is between about 175 - 195 degrees.
- the diffractive optical element 20 is superposed on the surface of the recessed part 7. It is shown in an exaggerated way with larger scaled features. In practice, the features of the diffractive optical element 20 can be around about 0.5-2 micron in size.
- the diffractive optical element 20 can be provided in the outer radial part of the recessed part 7.
- the central part 6 can have the same optical power or differ only up to about 1 dioptre with respect to the main lens part 4.
- the first subzone of the recessed part 7 can differ 0.5-2 dioptre with respect to the central part 6.
- the refractive reading part as described in figures 3-8 may have an additional DOE element to correct for chromatic aberration or to further improve the distance and reading performance of the MSIOL. This is depicted in figures 12-16.
- the DOE part 20 may be ray traced to control the amount of spherical aberration and further to reduce halo's and glare.
- the lens zone 3 also has a outer diameter of between about 5.5 to 7 mm. In an embodiment, it is about 5.8-6.2 mm.
- the central part 6 has a optical power at least equal to the baseline optical power of remaining lens part 4. Desirably, the optical power of the inner circle sector 7 is between 0% and 100% of the Add power.
- the embedded semi-meridian circle sector used as the refractive base for the DOE 20 has a optical power 10% and 100% of the Add power.
- the recessed part has a width (from the end of the central zone to blending past 11) between 1.5 and 2.3 mm. In an embodiment, it is between 1.8 and 2.1 mm.
- the DOE 20 may be configured for the baseline power and the intermediate Add power.
- transition zones or blend zones 10 bounding the recessed part of the embodiments described in figures 3-16 can follow a cosine function or a sigmoid function.
- the transition zones 10 follow an optimized transition function described below.
- PMTF Proliferative Deformation Detection Tube
- This instrument is available from Lambda-X SA, Rue de l'industrie 37, 1400 Nivelles, BELGIUM.
- An ISO eye model 384 holding the IOL in a cuvette, a microscope 385 on a translation table 386 and a CCD camera 387 mounted on said microscope 385.
- the eye model has a 4 mm diameter aperture for simulating the pupil.
- the measurement procedure and data handling were as follow.
- the order of measurements of the IOLs can be reversed.
- an IOL with only one optical zone is measured, and the same IOL but with an optical zone according to the invention is measured using the same procedure.
- the measurements are performed according to the normal use of the PMFT.
- a reference IOL without recessed part was measured.
- the light within an image of the aperture was measured by integrating the calibrated intensity on the CCD sensor.
- an IOL with recessed part was measured.
- the intensity was measured in the focal planes of the IOLs.
- the light in two focal planes was measured. From the light measurements on the CCD camera, the light in the focal planes was added and compared to the light in the focal plane of the reference IOL. The measured values for light loss corresponded very well with theoretically calculated light loss.
- Embodiment 1 figure 24 Sector Angle Distance 182 Sector Angle Near 170 Sector Angle Transitions 8 each recess 4 degrees transition Sector Radius Central 0.57
- Embodiment 2 figure 25 Sector Angle Distance 170 Sector Angle Near 160 Sector Angle Transitions 30 each recess 15 degrees transition Sector Radius Central 0.57
- the IOL was also available without recessed part. This IOL was used as reference lens. It has a dioptre of +20 for the main lens part.
- the lens of the invention was further identical, except that it had a recessed part with a relative dioptre of +3 with respect to the main lens part.
- the measurement procedure above using the PMTF was used. In the table, results using a spatially "large” circular source of 600 mu diameter and a "small” source of 200 mu diameter are shown.
- Embodiment 3 figure 26 Sector Angle Distance 182 Sector Angle Near 170 Sector Angle Transitions 8 each recess 4 degrees transition Sector Radius Central 0.25
- Embodiment 4 figure 23 Sector Angle Distance 145 Sector Angle Near 145 Sector Angle Transitions 70 each recess 35 degrees transition Sector Radius Central
- Embodiment 5 figure 22 Sector Angle Distance 145 Sector Angle Near 145 Sector Angle Transitions 70 each recess 35 degrees transition Sector Radius Central 0.00
- measurements were made in an Optocraft optical bench according to ISO 11979-2.
- FIG-29 measurements are shown of devices having a main lens part with an optical power of +22 (figure 27), +29 (figure 28) and +15 (figure 29).
- the recessed part has a near vision part having a relative optical power (with respect to the main part) of +3.0. All the examples relate to an IOL with varying optical power of the main part.
- the half right below is recessed.
- the recessed part is upper- left, in figure 29, the recess is the left side.
- transition zone 10, 13, 13' separates the recessed part(s) from the main lens part 4. It should be clear that the dimensions of this transition zone should be as small as possible. It was found that the best results are provided if the transition zones are as small or narrow and thus as steep as possible.
- the cutting tool and the lens should be moved towards each other and away from each other as fast as possible. Often, the tool will move with respect to the lens. Fast displacement implies the tool should be moved with the fastest acceleration allowed by the manufacturer of the cutting tool or capable by the cutting tool.
- the method of the present invention calculates the optimal transition profile to move the cutting tool from position 1 at rest to position 2 at rest. Position 1 corresponds to the z position of the cutting tool when processing the distance part, and position 2 corresponds to the position of the cutting tool when processing the reading part or vice versa.
- the minimum time needed to make a displacement As is: This time is the theoretical minimal time to make a displacement As with the cutting tool that is limited to a maximum acceleration. All other transition profiles subjected to the same limitation regarding the maximum acceleration require a larger time to make the same displacement As .
- the height difference between the reading part and distance part decrease when moving from the periphery toward the centre of the optical zone.
- Another important advantage is that the transition is made as steep as possible this way. A steep transition can be advantageous, reflections at the transition zone are in such a way they are less or not perceived as disturbing by the patient. From this it can be concluded that with the optimised transition profile a larger displacement can be achieved for the same size of the transition profile. Or otherwise when certain amount of displacement is needed to change from distance part to reading part with the optimised transition profile this can be achieved in a faster way resulting in a smaller transition zone.
- optimised transition profile A further application for the described optimised transition profile is this.
- the minimum acceleration needed to achieve a displacement As in a time ⁇ can be calculated with:
- ⁇ is the transition time and a is the maximum acceleration or a specified acceleration for the most controlled transition.
- the above described transition starts with a horizontal slope and ends with a horizontal slope.
- both near and reading part zone are rotational symmetric surfaces both zones have horizontal slopes in the tangential or tool direction.
- the zones can be connected by the transition profile in a smooth way with no discontinuity in the first derivative.
- one or both zones has or have for example non rational symmetric surfaces such as a toric surface or a decentred spherical surface, the slope will generally not be horizontal in the tool direction.
- the transition can be made by removing some part of the beginning or the end of the transition profile in such a way that both zones and transition zone become tangent at their point of connection. See Figure 17. It's also not difficult to do the same analysis as above in a more generally way. That is the assumption that the tool is at rest in position 1 and in position 2 is dropped. Instead, the tool is allowed to start with a specified velocity vl before the transition and remains at a speed v2 after the transition. The last resulting in transition profile that does optional not start or end with a horizontal slope. Of course if one chooses it's also possible to start the transition without being tangent with one or both optical zones.
- the achieved displacement for the fast tool is substantially less than the described optimal transition profile in this document.
- a cosine transition is calculated with the same transition time and maximum acceleration as used in the example above with the optimised transition profile (figure 17).
- the angular frequency ⁇ can be calculated from the transition time :
- the sigmoid function can be scaled and translated to model the required transition. In the same way as shown with the cosine transition it can be easily shown that a transition that is described by a sigmoid function is less optimal. That is when limited to a maximum acceleration during the transition:
- the shape and slope (first derivative) of the blending zone can be measured with high accuracy, using for instance a 3D Optical Profiler or Form talysurf, commercial available from Taylor Hobson, the United Kingdom.
- Figure 35 shows a surface map of a lens according to the invention.
- contrast sensitivity was measured in 23 patients who had bilateral implantation of the AcrySof ReSTOR SN60D3 IOL and 23 patients who had bilateral implantation of the ReZoom IOL.
- the number of subjects in our study was 24 and therefore direct comparable with the outcome of this study. It shows a mean contrast sensitivity improvement of at least 25% compared with a state of the art concentric refractive multifocal lens.
- the inventive lens configuration will give a mean contrast sensitivity for healthy eyes (1.677) at 3 cpd, (2.07) at 6 cpd, (1.831) at 12 cpd and (1.437) at 18 cpd.
- the results are indicated when compared to the performance of an average population, for several age groups (Pop. Norm klllll//ww.w : ⁇ the performance of the test group before surgery (pre-op), and the performance with an MIOL indicated as LS 312-MF. These results were found consistent at 6 months post operative, i.e., 6 months after surgery.
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Abstract
Description
Claims
Priority Applications (14)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US13/201,800 US8696746B2 (en) | 2009-02-17 | 2010-02-17 | Ophthalmic lens with optical sectors |
AU2010216510A AU2010216510B2 (en) | 2009-02-17 | 2010-02-17 | Ophthalmic lens with optical sectors |
KR1020117021806A KR101752309B1 (en) | 2009-02-17 | 2010-02-17 | Ophthalmic lens with optical sectors |
RU2011138159/28A RU2532240C2 (en) | 2009-02-17 | 2010-02-17 | Eye lens with optical sectors |
KR1020177005293A KR101864609B1 (en) | 2009-02-17 | 2010-02-17 | Ophthalmic lens with optical sectors |
CN201080017472.8A CN102395917B (en) | 2009-02-17 | 2010-02-17 | Ophthalmic lens with optical sectors |
MX2011008696A MX2011008696A (en) | 2009-02-17 | 2010-02-17 | Ophthalmic lens with optical sectors. |
JP2011551025A JP5663496B2 (en) | 2009-02-17 | 2010-02-17 | Ophthalmic lens with optical sector |
GB1011911.3A GB2483843A (en) | 2009-02-17 | 2010-02-17 | Ophthalmic lens with optical sectors |
BRPI1008719-2A BRPI1008719B1 (en) | 2009-02-17 | 2010-02-17 | OPHTHALMIC LENS, INTRAOCULAR INSERTION LENS, AND METHODS FOR THE PRODUCTION OF AN OPHTHALMIC LENS |
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EP4076280A4 (en) * | 2019-12-17 | 2024-01-03 | Onpoint Vision, Inc. | Intraocular pseudophakic contact lens with mechanism for securing by anterior leaflet of capsular wall and related system and method |
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