US2008084534A1PendingUtilityA1

Lens having an optically controlled peripheral portion and a method for designing and manufacturing the lens

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Assignee: LINDACHER JOSEPH MICHAELPriority: Oct 10, 2006Filed: Oct 9, 2007Published: Apr 10, 2008
Est. expiryOct 10, 2026(~0.2 yrs left)· nominal 20-yr term from priority
A61F 2/1613A61F 2/1602G02C 2202/24G02C 7/041G02C 7/04G02C 7/028
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Claims

Abstract

A contact lens or phakic IOC lens is provided with a peripheral portion that has a power profile that provides optical control of peripheral vision images. Typically, the central portion of the lens is also provided with optical control. The power profile of the lens at the boundary of the central and peripheral portions meets certain boundary conditions that ensure that the lens provides a desired or selected vision correction. Because the peripheral portion of the lens provides optical control that defocuses the peripheral vision image relative to the retina, the lens can be used to prevent or inhibit growth of the eye, thereby preventing or inhibiting myopia or the effects of myopia.

Claims

exact text as granted — not AI-modified
1 . A lens for controlling a location at which a peripheral vision image is focused relative to a retina of an eye, the lens comprising:
 a central portion having at least one optical zone that provides optical control over light rays passing through the central portion, the central portion having a power profile that optically controls a location at which a center vision image is focused relative to a retina of an eye:   a peripheral portion having at least one optical zone that provides optical control over light rays passing through the peripheral portion, the peripheral portion having a power profile that optically controls a location at which a peripheral vision image is focused relative to a retina of an eye.   
   
   
       2 . The lens of  claim 1 , wherein the central portion extends a radial distance from a center of the lens outwardly toward a periphery of the central portion that is between about 3.5 millimeters (mm) and about 4.0 mm, and wherein the peripheral portion extends a radial distance from a boundary where the periphery of the central portion meets the peripheral portion to a periphery of the peripheral portion of about 3.5 mm to about 4.0 mm. 
   
   
       3 . The lens of  claim 2 , wherein the power profile of the peripheral portion is defined by a mathematical function that is continuous at the boundary where the periphery of the central portion meets the peripheral portion such that it is possible to take a first derivative of the function. 
   
   
       4 . The lens of  claim 3 , wherein the mathematical function is a polynomial. 
   
   
       5 . The lens of  claim 2 , wherein the power profile of the peripheral portion is defined by a mathematical function that is discontinuous at the boundary where the periphery of the central portion meets the peripheral portion such that it a first derivative of the function is not obtainable, and wherein the optical power provided by the power profile of the central portion at the boundary and the optical power provided by the power profile of the peripheral portion at the boundary differ by no more than about 8.0 Diopters. 
   
   
       6 . The lens of  claim 5 , wherein the optical power provided by the power profile of the central portion at the boundary and the optical power provided by the power profile of the peripheral portion at the boundary differ by no more than about 3.0 Diopters. 
   
   
       7 . The lens of  claim 5 , wherein the mathematical function is a piecewise function. 
   
   
       8 . The lens of  claim 2 , wherein the power profile of the peripheral portion is defined by a mathematical function that is continuous at the boundary where the periphery of the central portion meets the peripheral portion and that is not differentiable in a first derivative at the boundary, and wherein the optical power provided by the power profile of the central portion at the boundary and the optical power provided by the power profile of the peripheral portion at the boundary differ by no more than about 8.0 Diopters. 
   
   
       9 . The lens of  claim 8 , wherein the optical power provided by the power profile of the central portion at the boundary and the optical power provided by the power profile of the peripheral portion at the boundary differ by no more than about 3.0 Diopters. 
   
   
       10 . The lens of  claim 8 , wherein the mathematical function is a spline. 
   
   
       11 . The lens of  claim 1 , wherein the lens is a soft contact lens. 
   
   
       12 . The lens of  claim 1 , wherein the lens is a hard contact lens. 
   
   
       13 . The lens of  claim 1 , wherein the lens is a phakic intraocular (IOC) lens. 
   
   
       14 . The lens of  claim 1 , wherein the lens, when worn on a person's eye, provides myopic defocus of the peripheral vision image that helps prevent or inhibit growth of the eye. 
   
   
       15 . The lens of  claim 1 , wherein the lens, when worn on a person's eye, ameliorates effects of myopia. 
   
   
       16 . A method for providing a lens to be worn on a person's eye that prevents or inhibits myopia by preventing or inhibiting eye growth, the method comprising:
 selecting a power profile for a peripheral portion of a lens to be designed, the power profile of the peripheral portion optically controlling a location at which a peripheral vision image is focused relative to a retina of an eye, the lens having a central portion, the central portion having a power profile that optically controls a location at which a center vision image is focused relative to a retina of an eye; and   producing a design of a lens having the central portion and the peripheral portion, the peripheral portion having the selected power profile.   
   
   
       17 . The method of  claim 16 , further comprising:
 manufacturing a lens or a plurality of lenses having the lens design.   
   
   
       18 . The method of  claim 16 , wherein the central portion extends a radial distance from a center of the lens outwardly toward a periphery of the central portion that is between about 3.5 millimeters (mm) and about 4.0 mm, and wherein the peripheral portion extends a radial distance from a boundary where the periphery of the central portion meets the peripheral portion to a periphery of the peripheral portion of about 3.5 mm to about 4.0 mm. 
   
   
       19 . The method of  claim 18 , wherein the power profile of the peripheral portion is defined by a mathematical function that is continuous at the boundary where the periphery of the central portion meets the peripheral portion such that it is possible to take a first derivative of the function. 
   
   
       20 . The method of  claim 18 , wherein the power profile of the peripheral portion is defined by a mathematical function that is discontinuous at the boundary where the periphery of the central portion meets the peripheral portion such that a first derivative of the function is not obtainable, and wherein the optical power provided by the power profile of the central portion at the boundary and the optical power provided by the power profile of the peripheral portion at the boundary differ by no more than about 8.0 Diopters. 
   
   
       21 . The method of  claim 20 , wherein the optical power provided by the power profile of the central portion at the boundary and the optical power provided by the power profile of the peripheral portion at the boundary differ by no more than about 3.0 Diopters. 
   
   
       22 . The method of  claim 18 , wherein the power profile of the peripheral portion is defined by a mathematical function that is continuous at the boundary where the periphery of the central portion meets the peripheral portion and that is not differentiable in a first derivative at the boundary, and wherein the optical power provided by the power profile of the central portion at the boundary and the optical power provided by the power profile of the peripheral portion at the boundary differ by no more than about 8.0 Diopters. 
   
   
       23 . The method of  claim 22 , wherein the optical power provided by the power profile of the central portion at the boundary and the optical power provided by the power profile of the peripheral portion at the boundary differ by no more than about 3.0 Diopters.

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