Title of Invention	A MULTIFOCAL OPHTHALMIC LENSES.
Abstract	A multifocal Ophthalmic lens for a lens wearer, the first lens comprising a birefringent material and a first convex and a first concave surface, the first convex surface comprising an optic zone comprising substantially all of the distance optical power and the first concave surface comprising an optic zone of at least two concentric, annular portions, the power of each of the at least two annular portions substantially equal to that of the distance optical power, and the second lens comprising a birefringent material and a second convex and a second concave surface, the second convex surface comprising an optic zone comprising substantially all of the near optical power and the second concave surface comprising an optic zone of at least two concentric, annular portions, the power of each of the at least two annular portions substantially equal to that of the near optical power.

Title of Invention

A MULTIFOCAL OPHTHALMIC LENSES.

Abstract

A multifocal Ophthalmic lens for a lens wearer, the first lens comprising a birefringent material and a first convex and a first concave surface, the first convex surface comprising an optic zone comprising substantially all of the distance optical power and the first concave surface comprising an optic zone of at least two concentric, annular portions, the power of each of the at least two annular portions substantially equal to that of the distance optical power, and the second lens comprising a birefringent material and a second convex and a second concave surface, the second convex surface comprising an optic zone comprising substantially all of the near optical power and the second concave surface comprising an optic zone of at least two concentric, annular portions, the power of each of the at least two annular portions substantially equal to that of the near optical power.

Full Text	HYBRID REFRACTIVE BIREFRINGENT MULTIFOCAL OPHTHALMIC LENSES Field of the Invention The invention relates to multifocal ophthalmic lenses. In particular, the invention provi0des lenses incorporating both birefringent material and zones of more than one optical power, or focal length. Background of the Invention As an individual ages, the eye is less able to accommodate, or bend the natural lens, to focus on objects that are relatively near to the observer. This condition is known as presbyopia. Similarly, for persons who have had their natural lens removed and an intraocular lens inserted as a replacement, the ability to accommodate is totally absent. Among the methods used to correct for the eye's failure to accommodate are lenses that have more than one optical power. In particular, contact and intraocular lenses have been developed in which zones of distance and near power are provided. These lenses are disadvantageous because they are difficult to manufacture. Additionally, the use of both distance and near power results in some loss of image contrast at each distance producing a less than completely clear image. Another known method is to use diffractive simultaneous vision bifocal lenses which incorporate both diffractive optical elements and refractive elements. These lenses are disadvantageous in that light is lost to higher order diffraction. Additionally, the remaining light is split between distance and near vision resulting in less than clear images. Further, these lenses are extremely difficult to manufacture. Yet another known method is to use birefringent material or a material with two refractive indices. However, the known birefringent lenses are disadvantageous in use in that the image seen through the lens is not entirely clear. Therefore, a need exists for a multifocal lens that overcomes some or all of the disadvantages of the prior art lenses. Detailed Description of the Invention and Preferred Embodiments The invention provides a multifocal lens, and methods for producing the lens, in which concentric, annular zones of differing power are used in combination with a birefringent material. The lenses of the invention provide a multifocal lens capable of providing clear vision at both near and far distances. In one embodiment, the invention provides a lens comprising, consisting essentially of, and consisting of at least two concentric, annular zones of alternating refractive power and a birefringent material. By "lens" is meant a contact, an intraocular lens, a comeal implant lens, an onlay lens, and the like, spectacle lens or combinations thereof. Preferably, the lenses of the invention are contact lenses. The birefringent material may form the lens itself. Alternatively, the concave or convex surface of the lens may be formed from a birefringent material and the remainder of the lens formed from an isotropic material. As yet another alternative, and preferably, a birefringent material may be embedded within a non- birefringent lens material or an isotropic material. By "embedded" is meant that the birefringent material is substantially encased within the lens material. Suitable birefringent materials for lens production are known and include, without limitation, organic polymers and polymers in which birefringence is induced by application of stress or stretching. In embodiments in which an isotropic material is used in combination with a birefringent material, the isotropic materials may be any material useful for forming ophthalmic lenses. Preferably, the materials used are suitable for forming hard or, more preferably, soft contact lenses. Suitable soft contact lens materials include, without limitation, silicone elastomers, silicone-containing macromers including, without limitation, those disclosed in United States Patent Nos. 5,371,147, 5,314,960, and 5,057,578 incorporated herein in their entireties by reference, hydrogels, silicone-containing hydrogels, and the like and combinations thereof. More preferably, the surface of the contact lens is a siloxane, or contains a siloxane functionality, including, without limitation, polydimethyl siloxane macromers. In the lenses in which the birefringent material is embedded within the lens, preferably, the birefringent material is embedded so that h is substantially wholly within the optic zone of the lens. Additionally, the birefringent material preferably is embedded within the bulk of the lens material to ensure wearer comfort. The embedded birefringent material may be introduced into the non-birefringent or isotropic lens material by any convenient method. For example, the birefringent material may be first formed and then surrounded by lens material by inserting it into a contact lens mold half into which lens material is then dispensed, introducing the other mold half, and curing the mold assembly. As another example, lens material may be dispensed into a mold half and partially cured followed by inserting the birefringent material onto the partially cured lens material, dispensing additional lens material, introducing the second mold half, and curing the mold assembly. In the lenses of the invention, at least two, concentric annular zones are provided. In the case of a contact lens, the annular zones will be within the lens' optic zone. One of the annular zones is of a refractive power substantially equal to the distance optical power, or power required to correct the lens wearer's distance vision acuity. The distance optical power zone alternates with a zone of refractive power substantially equal to that of the near optical power, or power required to correct the lens wearer's near vision acuity. In one embodiment of the invention, a pair of lenses is provided in which the central portion of the optic zone of each lens provides optical power substantially equal to the distance optical power. Annular zones or alternating distance and near optical power surround this central zone. Annular rings of alternating near and distance optical power surround this central optical zone. Alternatively, one lens may be as above-described, the other lens having a central zone with power substantially equal to the near optical power and surrounded with alternating near and distance optical power annular zones. In a preferred embodiment, the invention provides a pjir of ophthalmic lenses, one lens to be worn in the dominant eye and one to be worn in the non- dominant eye. By "dominant eye" is meant the eye that predominates for distance vision. The lens worn by the dominant eye has a surface, preferably the convex surface, with a central optic zone with substantially the desired distance optical power, and a surface, preferably the concave surface, that has at least two concentric annular zones in its optic zone. The power of each of the at least two annular zones is substantially equal to that of the distance optical power. Either or both the convex and concave surfaces may have additional annular zones with distance optical power, near optical power, or combinations thereof. Preferably, one surface, more preferably the convex surface, has only the central optical zone and no annular zones, the opposite surface, preferably the concave surface, in this embodiment having at least two annular zones of alternating distance and near optical power. Most preferably, the convex surface has only a central optical zone having the distance optical power, the concave surface having at least two zones of alternating distance and near optical powers. Further in this embodiment, the lens worn by the non-dominant eye has a surface, preferably the convex surface, with a central optic zone with substantially the desired near optical power. The opposite surface, preferably the concave surface, has at least two concentric annular zones in its optic zone. The power of each of the at least two annular zones is substantially equal to that of the near optical power. Either or both the convex and concave surfaces have additional annular zones with distance optical power alternating with those having near optical power. For the various contact lens embodiments, typically, the lens will be constructed with one or both non-optical lenticular and peripheral zones. The ratio of the contact lenses' optic zone to be devoted to distance and near optical power may be determined as disclosed in United States Patent Nos. 5,929,969, 5,835,192, 5,715,031, 5,682,223, 5,485,228, and 5,448,312, incorporated herein in their entireties by reference. In all embodiments of the lenses of the invention, the distance and near optical powers may be aspherical or spherical powers, but preferably are spherical. The lenses may have any of a number of a variety of corrective optical characteristics incorporated onto the surfaces in addition to distance and near optical powers, such as, for example, cylinder power. The annular zone of the lenses of the invention may be formed by any conventional method. For example, contact lenses with the annular zones formed therein may be produced by diamond-turning using alternating radii. The zones may be diamond-turned into the molds that are used to form the lens of the invention. Subsequently, a suitable liquid resin is placed between the molds followed by compression and curing of the resin to form the lenses of the invention. Alternatively, the zones may be diamond-turned into lens buttons. Similarly, spectacle lenses may formed using molds with the zones formed therein. Additional methods for forming lenses are within the ordinary skill of the art of lens manufacture. WE CLAIM: 1. A multifocal Ophthalmic lens for a lens wearer, the first lens comprising a birefringent material and a first convex and a first concave surface, the first convex surface comprising an optic zone comprising substantially all of the distance optical power and the first concave surface comprising an optic zone of at least two concentric, annular portions, the power of each of the at least two annular portions substantially equal to that of the distance optical power, and the second lens comprising a birefringent material and a second convex and a second concave surface, the second convex surface comprising an optic zone comprising substantially all of the near optical power and the second concave surface comprising an optic zone of at least two concentric, annular portions, the power of each of the at least two annular portions substantially equal to that of the near optical power. 2. The multifocal Ophthalmic lenses, the first lens comprising a birefringent material and a first convex and a first concave surface, the first convex surface consisting essentially of an optic zone comprising substantially all of the distance optical power and the first concave surface comprising an optic zone of at least two concentric, annular portions of distance optical power, near optical power, or combinations thereof and the second lens comprising a birefringent material and a second convex and a second concave surface, the second convex surface consisting essentially of an optic zone comprising substantially all of the near optical power and the second concave surface comprising an optic zone of at least two concentric annular portions of distance optical power near optical power, or combinations thereof. 3. The multifocal Ophthalmic lenses as claimed in claim 1, wherein the optic zone of the concave surface of the first lens further comprises one or more annular portions of the near optical power and the optic zone of the concave surface of the second lens further comprises one or more annular portions of the distance optical power. 4. The multifocal Ophthalmic lenses as claimed in claim 1, wherein either or both the convex and concave surfaces of the first lens, second lens, or both lenses further comprise additional annular portions with distance optical power, near optical power, or combinations thereof. 5. The multifocal Ophthalmic lenses as claimed in claims 1, 2, 3, or 4 wherein the concave surface of the first lens, second lens, or both lenses comprising the birefringent material and the remainder of said first lens, said second lens, or both lenses comprise an isotropic material. 6. The multifocal Ophthalmic lenses as claimed in claims 1. 2, 3, or 4 wherein the convex surface of the first lens, second lens, or both lenses comprise the birefringent material and the remainder of said first lens, said second lens, or both lenses comprise an isotropic material. 7. The multifocal Ophthalmic lenses as claimed in claims 1, 2, 3, or 4 wherein the birefringent material is embedded within an isotropic lens material. A multifocal Ophthalmic lens for a lens wearer, the first lens comprising a birefringent material and a first convex and a first concave surface, the first convex surface comprising an optic zone comprising substantially all of the distance optical power and the first concave surface comprising an optic zone of at least two concentric, annular portions, the power of each of the at least two annular portions substantially equal to that of the distance optical power, and the second lens comprising a birefringent material and a second convex and a second concave surface, the second convex surface comprising an optic zone comprising substantially all of the near optical power and the second concave surface comprising an optic zone of at least two concentric, annular portions, the power of each of the at least two annular portions substantially equal to that of the near optical power.

Full Text

HYBRID REFRACTIVE BIREFRINGENT MULTIFOCAL OPHTHALMIC
LENSES
Field of the Invention
The invention relates to multifocal ophthalmic lenses. In particular, the
invention provi0des lenses incorporating both birefringent material and zones of more
than one optical power, or focal length.
Background of the Invention
As an individual ages, the eye is less able to accommodate, or bend the
natural lens, to focus on objects that are relatively near to the observer. This
condition is known as presbyopia. Similarly, for persons who have had their natural
lens removed and an intraocular lens inserted as a replacement, the ability to
accommodate is totally absent.
Among the methods used to correct for the eye's failure to accommodate are
lenses that have more than one optical power. In particular, contact and intraocular
lenses have been developed in which zones of distance and near power are provided.
These lenses are disadvantageous because they are difficult to manufacture.
Additionally, the use of both distance and near power results in some loss of image
contrast at each distance producing a less than completely clear image.
Another known method is to use diffractive simultaneous vision bifocal
lenses which incorporate both diffractive optical elements and refractive elements.
These lenses are disadvantageous in that light is lost to higher order diffraction.
Additionally, the remaining light is split between distance and near vision resulting
in less than clear images. Further, these lenses are extremely difficult to
manufacture.
Yet another known method is to use birefringent material or a material with
two refractive indices. However, the known birefringent lenses are disadvantageous
in use in that the image seen through the lens is not entirely clear.
Therefore, a need exists for a multifocal lens that overcomes some or all of
the disadvantages of the prior art lenses.
Detailed Description of the Invention and Preferred Embodiments
The invention provides a multifocal lens, and methods for producing the
lens, in which concentric, annular zones of differing power are used in combination
with a birefringent material. The lenses of the invention provide a multifocal lens
capable of providing clear vision at both near and far distances.
In one embodiment, the invention provides a lens comprising, consisting
essentially of, and consisting of at least two concentric, annular zones of alternating
refractive power and a birefringent material.
By "lens" is meant a contact, an intraocular lens, a comeal implant lens, an
onlay lens, and the like, spectacle lens or combinations thereof. Preferably, the
lenses of the invention are contact lenses.
The birefringent material may form the lens itself. Alternatively, the
concave or convex surface of the lens may be formed from a birefringent material
and the remainder of the lens formed from an isotropic material. As yet another
alternative, and preferably, a birefringent material may be embedded within a non-
birefringent lens material or an isotropic material. By "embedded" is meant that the
birefringent material is substantially encased within the lens material. Suitable
birefringent materials for lens production are known and include, without limitation,
organic
polymers and polymers in which birefringence is induced by application of stress or
stretching.
In embodiments in which an isotropic material is used in combination with a
birefringent material, the isotropic materials may be any material useful for forming
ophthalmic lenses. Preferably, the materials used are suitable for forming hard or,
more preferably, soft contact lenses. Suitable soft contact lens materials include,
without limitation, silicone elastomers, silicone-containing macromers including,
without limitation, those disclosed in United States Patent Nos. 5,371,147,
5,314,960, and 5,057,578 incorporated herein in their entireties by reference,
hydrogels, silicone-containing hydrogels, and the like and combinations thereof.
More preferably, the surface of the contact lens is a siloxane, or contains a siloxane
functionality, including, without limitation, polydimethyl siloxane macromers.
In the lenses in which the birefringent material is embedded within the lens,
preferably, the birefringent material is embedded so that h is substantially wholly
within the optic zone of the lens. Additionally, the birefringent material preferably
is embedded within the bulk of the lens material to ensure wearer comfort. The
embedded birefringent material may be introduced into the non-birefringent or
isotropic lens material by any convenient method. For example, the birefringent
material may be first formed and then surrounded by lens material by inserting it
into a contact lens mold half into which lens material is then dispensed, introducing
the other mold half, and curing the mold assembly. As another example, lens
material may be dispensed into a mold half and partially cured followed by inserting
the birefringent material onto the partially cured lens material, dispensing additional
lens material, introducing the second mold half, and curing the mold assembly.
In the lenses of the invention, at least two, concentric annular zones are
provided. In the case of a contact lens, the annular zones will be within the lens'
optic zone. One of the annular zones is of a refractive power substantially equal to
the distance optical power, or power required to correct the lens wearer's distance
vision acuity. The distance optical power zone alternates with a zone of refractive
power substantially equal to that of the near optical power, or power required to
correct the lens wearer's near vision acuity.
In one embodiment of the invention, a pair of lenses is provided in which the
central portion of the optic zone of each lens provides optical power substantially
equal to the distance optical power. Annular zones or alternating distance and near
optical power surround this central zone. Annular rings of alternating near and
distance optical power surround this central optical zone. Alternatively, one lens
may be as above-described, the other lens having a central zone with power
substantially equal to the near optical power and surrounded with alternating near
and distance optical power annular zones.
In a preferred embodiment, the invention provides a pjir of ophthalmic
lenses, one lens to be worn in the dominant eye and one to be worn in the non-
dominant eye. By "dominant eye" is meant the eye that predominates for distance
vision. The lens worn by the dominant eye has a surface, preferably the convex
surface, with a central optic zone with substantially the desired distance optical
power, and a surface, preferably the concave surface, that has at least two concentric
annular zones in its optic zone. The power of each of the at least two annular zones
is substantially equal to that of the distance optical power. Either or both the convex
and concave surfaces may have additional annular zones with distance optical
power, near optical power, or combinations thereof. Preferably, one surface, more
preferably the convex surface, has only the central optical zone and no annular
zones, the opposite surface, preferably the concave surface, in this embodiment
having at least two annular zones of alternating distance and near optical power.
Most preferably, the convex surface has only a central optical zone having the
distance optical power, the concave surface having at least two zones of alternating
distance and near optical powers.
Further in this embodiment, the lens worn by the non-dominant eye has a
surface, preferably the convex surface, with a central optic zone with substantially
the desired near optical power. The opposite surface, preferably the concave surface,
has at least two concentric annular zones in its optic zone. The power of each of the
at least two annular zones is substantially equal to that of the near optical power.
Either or both the convex and concave surfaces have additional annular zones with
distance optical power alternating with those having near optical power.
For the various contact lens embodiments, typically, the lens will be
constructed with one or both non-optical lenticular and peripheral zones. The ratio
of the contact lenses' optic zone to be devoted to distance and near optical power
may be determined as disclosed in United States Patent Nos. 5,929,969, 5,835,192,
5,715,031, 5,682,223, 5,485,228, and 5,448,312, incorporated herein in their
entireties by reference.
In all embodiments of the lenses of the invention, the distance and near
optical powers may be aspherical or spherical powers, but preferably are spherical.
The lenses may have any of a number of a variety of corrective optical
characteristics incorporated onto the surfaces in addition to distance and near optical
powers, such as, for example, cylinder power.
The annular zone of the lenses of the invention may be formed by any
conventional method. For example, contact lenses with the annular zones formed
therein may be produced by diamond-turning using alternating radii. The zones may
be diamond-turned into the molds that are used to form the lens of the invention.
Subsequently, a suitable liquid resin is placed between the molds followed by
compression and curing of the resin to form the lenses of the invention.
Alternatively, the zones may be diamond-turned into lens buttons. Similarly,
spectacle lenses may formed using molds with the zones formed therein. Additional
methods for forming lenses are within the ordinary skill of the art of lens
manufacture.
WE CLAIM:
1. A multifocal Ophthalmic lens for a lens wearer, the first lens comprising a
birefringent material and a first convex and a first concave surface, the
first convex surface comprising an optic zone comprising substantially all
of the distance optical power and the first concave surface comprising an
optic zone of at least two concentric, annular portions, the power of each
of the at least two annular portions substantially equal to that of the
distance optical power, and the second lens comprising a birefringent
material and a second convex and a second concave surface, the second
convex surface comprising an optic zone comprising substantially all of
the near optical power and the second concave surface comprising an
optic zone of at least two concentric, annular portions, the power of each
of the at least two annular portions substantially equal to that of the near
optical power.
2. The multifocal Ophthalmic lenses, the first lens comprising a birefringent
material and a first convex and a first concave surface, the first convex
surface consisting essentially of an optic zone comprising substantially all
of the distance optical power and the first concave surface comprising an
optic zone of at least two concentric, annular portions of distance optical
power, near optical power, or combinations thereof and the second lens
comprising a birefringent material and a second convex and a second
concave surface, the second convex surface consisting essentially of an
optic zone comprising substantially all of the near optical power and the
second concave surface comprising an optic zone of at least two
concentric annular portions of distance optical power near optical power,
or combinations thereof.
3. The multifocal Ophthalmic lenses as claimed in claim 1, wherein the optic
zone of the concave surface of the first lens further comprises one or more
annular portions of the near optical power and the optic zone of the
concave surface of the second lens further comprises one or more annular
portions of the distance optical power.
4. The multifocal Ophthalmic lenses as claimed in claim 1, wherein either or
both the convex and concave surfaces of the first lens, second lens, or
both lenses further comprise additional annular portions with distance
optical power, near optical power, or combinations thereof.
5. The multifocal Ophthalmic lenses as claimed in claims 1, 2, 3, or 4 wherein
the concave surface of the first lens, second lens, or both lenses
comprising the birefringent material and the remainder of said first lens,
said second lens, or both lenses comprise an isotropic material.
6. The multifocal Ophthalmic lenses as claimed in claims 1. 2, 3, or 4
wherein the convex surface of the first lens, second lens, or both lenses
comprise the birefringent material and the remainder of said first lens, said
second lens, or both lenses comprise an isotropic material.
7. The multifocal Ophthalmic lenses as claimed in claims 1, 2, 3, or 4 wherein
the birefringent material is embedded within an isotropic lens material.
A multifocal Ophthalmic lens for a lens wearer, the first lens comprising a
birefringent material and a first convex and a first concave surface, the first
convex surface comprising an optic zone comprising substantially all of the
distance optical power and the first concave surface comprising an optic zone of
at least two concentric, annular portions, the power of each of the at least two
annular portions substantially equal to that of the distance optical power, and the
second lens comprising a birefringent material and a second convex and a
second concave surface, the second convex surface comprising an optic zone
comprising substantially all of the near optical power and the second concave
surface comprising an optic zone of at least two concentric, annular portions, the
power of each of the at least two annular portions substantially equal to that of
the near optical power.

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Patent Number

225255

Indian Patent Application Number

IN/PCT/2002/00756/KOL

PG Journal Number

45/2008

Publication Date

07-Nov-2008

Grant Date

05-Nov-2008

Date of Filing

05-Jun-2002

Name of Patentee

JOHNSON & JOHNSON VISION CARE INC ,

Applicant Address

SUITE 100, 7500 CENTURION PARKWAY JACKSONVILLE, FL 32256

Inventors:

#	Inventor's Name	Inventor's Address
1	CHEHAB KHALED	2423 WATTLE TREE ROAD R, JACKSONVILLE, FL 32246
2	ROFFMAN JEFFREY H.	307 EDGEWATER BRANCH DRIVE, JACKSONVILLE, FL 32259

PCT International Classification Number

G02B 1/00

PCT International Application Number

PCT/US00/32683

PCT International Filing date

2000-11-30

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	09/466301	1999-12-15	U.S.A.