SYSTEM AND METHOD FOR TREATING AN EYE

Abstract

The invention provides a device for delivering electromagnetic radiation to a limbal area of an eye that transforms one or more beams of electromagnetic radiation that are incident on a first side into one or more emitted beams of the electromagnetic radiation where the one or more beams are arrayed in a cylindrical array, an array of one or more beams each beam having a cross sectional shape of a circular arc or an array comprising a beam having an annular cross section. The invention also provides a system for delivering electromagnetic radiation to the limbal area of an eye that includes one or more devices of the invention and a source of electromagnetic radiation. The system may be used in the treatment of glaucoma.

Description

FIELD OF THE INVENTION

This invention relates to medical devices, and in particular to such devices for use in ophthalmology.

BACKGROUND OF THE INVENTION

The following documents are considered to be relevant for an understanding of the background of the invention:

Barkana, Y and Belkin M., Selective Laser Trabeculoplasty, Survey of Ophthalmology 52:634-653, 2007.

U.S. Pat. No. 6,698,886 to Pollack et al.

U.S. Pat. No. 5,479,222 to Volk.

Under normal circumstances, aqueous humor is secreted into the posterior chamber of the eye, and then circulates through the pupil into the anterior chamber where it passes through the trabecular meshwork, before being secreted from the eye. In most forms of glaucoma, the flow of the aqueous humor through the trabecular meshwork is impeded, preventing adequate drainage of the aqueous humor from the eye. This leads to a rise in the intraocular pressure, a state which may cause damage to the eye and lead to progressive blindness. One method to treat or prevent this from occurring is to alter some of the trabecular meshwork in order to improve the flow of aqueous humor through the trabecular meshwork.

A common method of enhancing the flow of aqueous humor through the trabecular meshwork is laser trabeculoplasty (LTP) which consists of the application of laser energy to the trabecular meshwork. There are a several types of LTP, such as selective laser trabeculoplasty (SLT) argon laser trabeculoplasty (ALT), diode laser trabeculoplasty (DLT), micropulse laser trabeculoplasty (MLT), and titanium:sapphire laser trabeculoplasty (TLT). The various types of LTP differ in the wavelength and other characteristics of the laser beam. SLT, for example, utilizes a Q-switched 532 Nd:YAG laser which selectively targets melanin-containing cells within the trabecular meshwork. (Barkana. Y et al) While the entire mechanism of action has not been completely elucidated, it is believed that laser-stimulated melanin-containing cells release cytokines which attract other cell types to the trabecular meshwork that increase its permeability. Unlike older versions of LTP, such as ALT, selective laser trabeculoplasty does not require precise targeting since the wavelength and energy of the light used selectively targets the melanine containing cells within the meshwork. The surrounding cells are not heated or destroyed. Thus, the fluid outflow is improved without damaging the trabecular meshwork. SLT has been used to treat primary open angle glaucoma, intraocular hypertension, normal tension glaucoma, aphakic (glaucoma in patients without a natural lens in their eye), pseudophakic glaucoma (glaucoma in patients without an artificial lens in their eye pigmentary, chronic angle closure glaucoma and juvenile glaucoma. SLT has also been successfully used to treat pressure increases in the eye caused by certain medications.

FIG. 1 shows the treatment of an eye 1 by LTP. Eye drops are first placed in the eye to provide surface anesthesia and to prepare the eye for the procedure. The trabecular meshwork 10 is situated around the angle of the anterior chamber of the eye and is not directly observable because it is obscured by the limbal area 12. A gonioscopic contact lens 2 which includes a mirror 3 is applied to the eye 1 to direct a laser beam 6 through the cornea 5 to the trabecular meshwork 10 underneath the limbal area 12. Typically, between 180° to 360° of the anterior chamber angle is irradiated by rotating the gonioscopic contact lens 12 after each laser pulse. About 100 laser pulses of a few nanoseconds duration and about 0.6 to 200 mJ of energy are delivered to the trabecular meshwork.

U.S. Pat. No. 5,479,222 to Volk discloses a gonioscopic lens system comprising at least two lenses. At least one of the lenses includes an aspheric surface of revolution. The lenses are positioned adjacent one another in a housing, such that the refractive properties of each are combined to converge light from an illumination light source to the entrance pupil of the patient's eye to illuminate the fundus. The lens system is designed for use with an associated ophthalmoscopic lens, enabling selective modification of the optical characteristics of the ophthalmoscopic lens system in a predetermined manner.

U.S. Pat. No. 6,698,886 to Pollack et al discloses an iridotomy and trabeculoplasty goniolaser lens having a contact lens element, a planar mirror offset from the optical axis of the contact lens element and first and second button lenses mounted on the anterior surface of the contact lens element. Magnification, curvature and location of the button lenses are chosen so as to provide the ability to simultaneously deliver laser energy to the iris of a patient's eye along a first optical path offset from the optical axis of the contact lens element and to view the trabecular meshwork around the region where the laser energy was applied.

Irradiating the trabecular meshwork with a laser beam directed through the cornea, as shown in FIG. 1, is often not possible in cases of narrow or closed angle glaucoma which occurs when the iris of the eye approaches the cornea and thus narrows or eliminates the angle between the cornea and the iris. This is the most common type of glaucoma in Chinese and Indian people and hence the commonest form of glaucoma and blindness in the world. In these cases, the laser beam cannot reach the trabeculum meshwork to be irradiated.

SUMMARY OF THE INVENTION

The present invention is based on the novel and unexpected finding that LTP can be performed by irradiating the trabecular meshwork through the limbal area, thus avoiding the need for a gonioscopic contact lens. The inventors have found that irradiating the trabecular meshwork directly through the limbal area can achieve results comparable to those obtained by prior art LTP methods that utilize a gonioscopic contact lens. The inventors have found, for example, that a 532 nm laser beam is capable of penetrating the 1 mm thick limbal area and reaches the trabecular tissue to be treated with an adequate intensity to enhance the flow of aqueous humor through the trabecular meshwork, and to cause a significant decrease in intraocular pressure.

Thus, for example, in one patient suffering from open angle glaucoma with pseudoexfoliation, following irradiation of the limbal area with a 532 nm Nd:YAG laser (total energy delivered to a single eye around 10 J), the intraocular pressure reduced within a day from 24 to 14 mmHg while the patient was using antihypertensive eye drops. In another patient suffering from open angle glaucoma with pseudoexfoliation, the intraocular pressure decreased from 24 mmHg to 12 mmHg a week after treatment with a reduction of antihypertensive eye drops from 3 to 2. In a patient with primary open angle glaucoma the intraocular pressure was reduced from 27 to 18 mm Hg following the treatment.

Thus, in one of its aspects, the present invention provides a device for directing a beam of electromagnetic radiation to one or more regions on the limbal area of an eye. Device of the invention comprises a thin plate having one or more apertures that are arrayed in the plate to overly locations around the limbal area. The apertures may have, for example, a circular cross section or the apertures may have an arched shape. The plate may be rotatable so that each aperture can be positioned over different locations of the sclerlal limbus. The device may be configured to be placed directly onto the eye being treated, or the device may be configured to be held a predetermined distance away from the eye.

In another of its aspects, the invention provides a system for treating an eye. The system of the invention comprises a source of electromagnetic radiation, a device of the invention for directing radiation generated by the source to one or more location on the sclera limbus of an eye. The electromagnetic radiation may have, a wavelength in the visible or near infrared range, between 514 and 810 nm, and may be, for example, a 532 Nd:YAG laser. The system may be configured to generated pulses of the electromagnetic radiation. In this case, the pulses may be between 0.1 to 3 nanosec in duration, and the fluence of a single pulse may be 0.84 to 10,000 J/cm². The total energy delivered to a single eye may be from 4 to 20 J.

The invention also provides an ensemble comprising two or more devices of the invention for delivering electromagnetic radiation to a limbal area of an eye. In the ensemble of the invention, any two or more devices producing a cylindrical array of emitted beams produce a cylindrical array of emitted beams having a different cross-sectional diameter. Similarly, two or more devices producing emitted beams having a cross sectional shape of a circular arc produces emitted beams having a cross sectional shape of a circular arc of a different diameter. Two or more devices producing an emitted beam having an annular cross section produces an emitted beam having an annular cross section of one or both of a different inner diameter or a different outer diameter.

The ensemble of the invention may be used when it is desirable to irradiate the limbal area of an eye in a procedure using a series of irradiations of different geometrical parameters. Thus, for example, the eye may first be irradiated with a either a cylindrical array of beams or beams having a cross sectional shape of a circular arc wherein the cylindrical array or the circular arcs have a relatively small diameter (e.g. 9 mm), and then irradiated one or more additional times, each time increasing the diameter. The final diameter may be around 13 mm. Similarly, the eye may be sequentially irradiated with a series of beams having an annular cross section where one or both of the inner diameter and the outer diameter increases each time.

In still another of its aspects, the present invention provides a method for treating an eye. The method of the invention comprises directing electromagnetic radiation to one or more location on the sclera limbus of an eye. The electromagnetic radiation may have, a wavelength in the visible or near infrared range, between 514 and 810 nm, and may be generated, for example, by a 532 Nd:YAG laser. The electromagnetic radiation may be delivered to the limbal area in pulses. In this case, the pulses may be between 0.1 to 3 nanosecond in duration, and the fluence of a single pulse may be 0.84 to 10,000 J/cm². The total energy delivered to a single eye may be from 4 to 20 J. The method of the invention may be carried out using the system of the invention.

The invention may be used in the treatment of narrow or closed angle glaucoma, since, in accordance with the invention, the beam of electromagnetic radiation is not directed through the angle.

Thus, in one of its aspects, the invention provides a device for delivering electromagnetic radiation to a limbal area of an eye, the device having a first side and a second side, and the device transforming one or more beams of electromagnetic radiation that are incident on the first side into one or more beams of the electromagnetic radiation that are emitted from the second side, wherein the one or more emitted beams are arrayed in an array selected from:

• • (a) an array of two or more emitted beams that are arrayed in a cylindrical array, the cylindrical array having a circular cross section;
  • (b) an array of one or more beams each beam having a cross sectional shape of a circular arc; and
  • (c) an array comprising a beam having an annular cross section.

In the device of the invention, when the emitted radiation comprises two or more emitted beams that are arrayed in a cylindrical array, the cylindrical array may have a circular cross section having a diameter from 9 to 13 mm. When the emitted radiation comprises an array of one or more beams having a cross sectional shape of a circular arc; the circular arc may have a diameter from 9 to 13 mm. When the emitted radiation comprises an array comprising a beam having an annular cross section, the annular cross section may have an inner diameter and an outer diameter, the average of the inner diameter and the outer diameter being from 9 to 13 mm.

When the emitted radiation comprises two or more emitted beams that are arrayed in a cylindrical array, the device may comprise an element opaque to the electromagnetic radiation having therein a circular array of apertures extending from a first face of the opaque element to a second face of the opaque element. The circular array of apertures may comprise, for example, at least 50 apertures. The opaque element may be rotatable about the center of the circular array. When the emitted radiation comprises an array of one or more beams having a cross sectional shape of a circular arc; the device may comprise an element opaque to the electromagnetic radiation having therein a circular array of apertures, each aperture having a cross sectional shape of a circular arc and each aperture extending from a first face of the opaque element to a second face of the opaque element. The opaque element may be rotatable about the center of the circular array. When the emitted radiation comprises two or more emitted beams that are arrayed in a cylindrical array, the device may comprise a cylindrical array of optic fibers. The cylindrical array of optic fibers may be embedded in an opaque element, with the cylindrical array of optic fibers extending from a first face of the opaque element to a second face of the opaque clement. When the emitted radiation comprises a beam having an annular cross section, and the device may comprise a refractive or diffractive optical element. When the emitted radiation comprises a beam having an annular cross section, the device may comprise an ellipsoidal mirror.

The device of the invention may further comprise a concave surface adjacent to the second side of the device. The concave surface may conform to the surface of the eye to promote stabilization of the device on an eye.

In another of its aspects, the invention provides an ensemble comprising two or more devices for delivering electromagnetic radiation from the first source of electromagnetic radiation to a limbal area of an eye, each of the one or more devices having a first side and a second side, and each device transforming one or more beams of electromagnetic radiation that are incident on the first side into one or more beams of the electromagnetic radiation that are emitted from the second side, wherein the one or more emitted beams are arrayed in an array selected from:

• • (i) an array of two or more emitted beams that are arrayed in a cylindrical array, the cylindrical array having a circular cross section, wherein each of the one or more devices producing a cylindrical array of emitted beams produces a cylindrical array of emitted beams having a different cross-sectional diameter;
  • (ii) an array of one or more beams having a cross sectional shape of a circular arc wherein each of the one or more devices producing emitted beams having a cross sectional shape of a circular arc produces emitted beams having a cross sectional shape of a circular arc of a different diameter; and
  • (iii) an array comprising a beam having an annular cross section, wherein each of the one or more devices producing an emitted beam having an annular cross section produces an emitted beam having an annular cross section of one or both of a different inner diameter or a different outer diameter.

The invention also provides a system for delivering electromagnetic radiation to a limbal area of an eye, comprising:

• • (a) a first source of electromagnetic radiation; and
  • (b) one or more devices for delivering electromagnetic radiation from the first source of electromagnetic radiation to a limbal area of an eye the device when the first source is optically coupled to the device, each of the one or more devices having a first side and a second side, and each device transforming one or more beams of electromagnetic radiation from the first source that are incident on the first side into one or more beams of the electromagnetic radiation that are emitted from the second side, wherein the one or more emitted beams are arrayed in an array selected from:
    • (i) an array of two or more emitted beams that are arrayed in a cylindrical array, the cylindrical array having a circular cross section, wherein each of the one or more devices produces a cylindrical array of emitted beams having a different cross-sectional diameter;
    • (ii) an array of one or more beams having a cross sectional shape of a circular arc wherein each of the one or more devices produces emitted beams having a cross sectional shape of a circular arc of a different diameter; and
    • (iii) an array comprising a beam having an annular cross section, wherein each of the one or more devices produces emitted beams having an annular cross section of a different inner diameter or a different outer diameter.

In the system of the invention, the first source may be a laser. The laser may have, for example, a wavelength from 514 810 nm. The laser may be, for example, a 532 Nd:YAG laser.

The system may further comprise a processor configured to execute a predetermined regime of activation of the first source of electromagnetic radiation. The predetermined regime of activation of the source of electromagnetic radiation may comprises a series of pulses. The pulses may be between 0.1 to 3 nanoseconds in duration and the fluence of a single pulse may be from 0.84 to 10,000 J/cm2. The total energy delivered to a single eye may be from 4 to 20 J.

The system may further comprise a second source of electromagnetic radiation that produces a visible light beam, where the second source of radiation is configured to be optically coupled to the device of the system.

The invention also provides a method for delivering electromagnetic radiation to a limbal area of an eye, comprising

• • (a) delivering electromagnetic radiation to the limbal area of the eye wherein the delivered electromagnetic radiation is in the form of one or more beams, the beams being arrayed in an array selected from:
    • (i) an array of two or more emitted beams that are arrayed in a cylindrical array, the cylindrical array having a circular cross section;
    • (ii) an array of one or more beams having a cross sectional shape of a circular arc; and
    • (iii) an array comprising a beam having an annular cross section. The method may be used in the treatment of glaucoma.

BRIEF DESCRIPTION OF DRAWINGS

In order to understand the invention and to see how it may be carried out in practice, embodiments will now be described, by way of non-limiting example only, with reference to the accompanying drawings, in which:

FIG. 1 shows the beam path in SLT using a gonioscopy contact lens;

FIG. 2 shows a device for directing electric magnetic radiation to one or more regions of a limbal area of an eye having a circular array of apertures, in accordance with one embodiment of the invention;

FIG. 3 shows a device for directing electric magnetic radiation to one or more regions of a limbal area of an eye having an array or arc shaped apertures, in accordance with another embodiment of the invention;

FIG. 4 shows a device for directing electric magnetic radiation to one or more regions of a limbal area of an eye having a circular array of apertures, where the array is rotatable;

FIG. 5 shows a a device for directing electric magnetic radiation to one or more regions of a limbal area of an eye that includes oor more optic fibers arranged in a cylinder; and

FIG. 6 shows a system for delivering electromagnetic radiation to a limbal area of an eye in accordance with one embodiment of this aspect of the invention.

DETAILED DESCRIPTION OF EMBODIMENTS

FIG. 2 shows a device 20 for directing electric magnetic radiation to one or more regions of a limbal area of an eye in accordance with one embodiment of the invention. The device 20 comprises a thin plate 21 that may be a circular disk. The plate 2 is provided with a plurality of small apertures 22 that may have a circular cross section. The plate 2 is formed from an opaque material such as metal. The apertures 22 pass through the plate 2 from an upper surface 23 to a bottom surface 25. Thus, electromagnetic radiation directed to the plate will transverse the plate only at the apertures 22. The apertures 22 are arranged in a circular array so as to overly the sclera limbus of an eye being treated. The circular array of apertures may have a diameter in the range from 11 to 13 mm, which is the typical diameter of the sclera limbus. The plate 21 may have as many as 200 apertures equally spaced along the circumference of the disk 21, so that 200 spots in the sclera limbus can be treated simultaneously.

This is where the reduced-energy aiming beam comes into play. It should be aimed as to cover the whole circumference of the limbus. When the operator sees the aiming beam positioned properly, he activates the treatment beam. See first para on page 5 above.

FIG. 3 shows a device 24 for directing electric magnetic radiation to one or more regions of a limbal area of an eye in accordance with another embodiment of the invention. The device 24 comprises a thin plate 26 that may be a circular disk. The plate 2 is provided with a plurality of small apertures 28 having the shape of circular arcs. The plate 26 is formed from an opaque material such as metal. The apertures 28 pass through the plate 26 from an upper surface 27 to a bottom surface 29. Thus, electromagnetic radiation directed to the plate 26 will transverse the plate only at the apertures 28. The apertures 28 are arranged in a circular array so as to overly the sclera limbus of an eye being treated. The circular array of apertures may have a diameter in the range from 11 to 13 mm, which is the typical diameter of the sclera limbus.

FIG. 4 shows a device 30 for directing electric magnetic radiation to one or more regions of a limbal area of an eye in accordance with yet another embodiment of the invention. The device 30 comprises a circular disk 32 that rotates in a circular hole in a thin plate 34. The disk 32 is provided with a plurality of small apertures 36 that may have a circular cross section. The disk 32 is formed from an opaque material such as metal. The apertures 36 pass through the disk 32 from an upper surface 35 to a bottom surface. Thus, electromagnetic radiation directed to the circular disk 32 will transverse the plate only at the apertures 36. The apertures 36 are arranged a long a circle to overly the sclera limbus of an eye being treated. The circular array of apertures may have a diameter in the range from 11 to 13 mm, which is the typical diameter of the sclera limbus. In use, the disk 32 may be rotated between pulses of electric magnetic radiation to deliver the radiation to a number of spots in the sclera limbus that is significantly greater than the number of apertures in the disk.

FIG. 5 shows a device 40 for directing electric magnetic radiation to one or more regions of a limbal area of an eye in accordance with still another embodiment of the invention. The device 40 comprises a block 42 of an opaque material shown in phantom drawing in FIG. 5. The block 32 has a first face 44 and an oppositely situated second face 46. One or more optic fibers 48 extend from the first face 44 to the second face 46. Thus, electromagnetic radiation directed to the first face 44 will transverse the block 42 only along the optic fibers 48. The optic fibers 48 are arranged in a cylinder so that the ends of the optic fibers 48 in the second face 46 overly the sclera limbus of an eye being treated. The cylinder of optic fibers 48 may have a diameter in the range from 11 to 13 mm, which is the typical diameter of the sclera limbus.

In another embodiment of the device of the invention, the device comprises a refractive or diffractive optical element. The refractive or diffractive optical element may be made from glass or plastic having transmitting and refracting or diffractive optics which will create a circular beam or rapidly deliver a number of discrete beams to the limbal area. When electromagnetic radiation is incident on the refractive or optical element, the radiation exits the opposite side of the element as a beam having an annular cross section. This allows radiation of a complete circle around the limbal area by a continuous ring of light. The annulus of light may have, for example, a diameter between 9 and 13 mm, and may be from 0.5 to 2.5 mm in radial width. The lasers involve may be doubled Nd/YAG, argon or any diode emitting radiation in the visible or infra red

In another embodiment of the device of the invention, the optical device includes an ellipsoidal or parabolic mirror that when illuminated by a large spot of light scanning along a large circle will generate a small ring at its focal plane.

The optical device may be a lens. The lens may illuminate a single point of the limbal area, in which case, the system may include a manipulator to allow the laser beam to be directed to a plurality of locations around the limbal area in succession to impact on a plurality of locations of the trabecular meshwork. A first point around the limbal area can be illuminated, after which, the laser beam can be directed towards a second point around the limbus, and so on. This can be done automatically and rapidly. Up to about 200 points can be illuminated simultaneously at the treatment intensity with a single laser.

Turning now to FIG. 6, a system 60 is shown schematically for treating an eye in accordance with one embodiment of this aspect of the invention. The system 60 comprises a source 62 of electromagnetic radiation that generates a beam of electromagnetic radiation 64. The system 60 also includes a device 66 for directing the beam 64 radiation to one or more regions of a limbal area of an eye. The device 66 may be, for example, any one of the devices 20, 24, 30 or 40 described above. Operation of the source 62 is under the control of a processing unit 68 which comprises a CPU 70, a memory 72 and a user input device, such as a keypad 74.

The beam 64 can have a wavelength, for example, between 514 and 810 nm. The source 62 may be a laser in the visible or near infrared range, such as a 532 Nd:NAG laser.

The user input device 74 may be used to input parameters relating to the treatment. For example, a user may input a beam intensity, a number of pulses of electromagnetic radiation that is to be delivered to the eye, and a pulse rate. The parameters may be stored in the memory 72. The memory may also be used to store data relating to the individual being treated, as well as any relevant observations relating to the treatment.

The pulses may be between 0.1 to 3 nanoseconds, and the fluence of a single pulse may be 0.84 to 10,000 J/cm². The total energy delivered to a single eye may be from 4 to 20 J. At this fluence, the beam 64 is not visible. The system 60 may thus include a second source 76 of electromagnetic radiation that produces a visible light beam 78. The source 76 may be temporarily positioned to direct the beam 78 to the device 66 in order to properly position the device 66 over the eye 80 to be treated. The device 66 is properly positioned over the eye when the beam 64 or the beam 78 impinging on the device 66 is delivered only to the limbal area 82 of the eye 80.

In use, the device 66 is positioned over the eye 80. As stated above, the device 66 is properly positioned over the eye when the beam 64 is delivered only to the limbal area 82 of the eye 80. The source 62 is then activated to generate a predetermined sequence of one or more pulses of the beam 64. At any time, the device 66 may be rotated over the eye 80 and another sequence of one or more pulses may be generated. The process may be repeated as required in any treatment.

Claims

1-27. (canceled)

28. A system for delivering electromagnetic radiation to a region of an eye, the system comprising:

(a) at least one source of electromagnetic radiation configured for producing a treatment beam of a first electromagnetic radiation and a second aiming beam of a second electromagnetic radiation of a visual spectral range;

at least one device configured for directing therethrough the first and second beams of the first and second electromagnetic radiations from said at least one source of electromagnetic radiation to one or more regions of an eye, said at least one device being configured in accordance with a circumference of a limbus or a sclera around the limbus and being manipulatable for directing the aiming visible beam onto said circumference thereby enabling visible control of the treatment beam propagation through said device to the one or more regions on said circumference,

each of said at least one devices having a first side and a second side, and transforming each of the treatment and aiming beams from the first and second sources that are incident on the first side of the device into one or more beams of the respective electromagnetic radiation propagating from the second side.

29. The system according to claim 28, wherein said one or more beams of radiation delivered to said circumference region of an eye form illumination of a ring-like annular cross section shape.

30. The system according to claim 28, wherein the at least one device comprises an element opaque to the first and second electromagnetic radiation and having therein a circular array of spaced-apart apertures each aperture extending from a first face of the opaque element to a second face of the opaque element.

31. The system according to claim 28, wherein said first and second beams of the electromagnetic radiations are produced by first and second radiation sources.

32. The system according to claim 28, wherein the at least one device comprises a thin plate having one or more apertures that are arrayed in the plate to overly locations on said circumference.

33. The system according to claim 29, wherein the ring-like annular cross section of the radiation delivered to the circumference region of an eye has an inner diameter of 9 mm and an outer diameter of 13 mm.

34. The system according to claim 28, wherein said at least one source of electromagnetic radiation is automatically operable to direct the treatment beam through said at least one device onto the one or more regions on said circumference of the limbus or sclera around the limbus.

35. The system according to claim 32, wherein said device has at least one of the following configurations: (a) said apertures comprises apertures having a circular cross section; (b) said apertures comprise apertures of an arced shape; and (c) said plate is configured to be rotatable so that each aperture can be positioned over different locations on said circumference.

36. The system according to claim 28, wherein said at least one device has one of the following configurations: (1) comprises a cylindrical array of optic fibers; (2) comprises a refractive or diffractive optical element.

37. The device according to claim 28, wherein said at least one device comprises a cylindrical array of optic fibers embedded in an opaque element and extending from a first face of the opaque element to a second face of the opaque element.

38. The system according to claim 31, wherein the first source is a laser.

39. The system according to claim 38, wherein the electromagnetic radiation has a wavelength in at least one of visible or near infrared range.

40. The system according to claim 39 wherein the laser is a 532 Nd:YAG laser.

41. The system according to claim 28 further comprising a processor configured to execute a predetermined regime of activation of the source of electromagnetic radiation to produce said first treatment beam.

42. The system according to claim 41 wherein the predetermined regime of activation of the source of electromagnetic radiation is a pulse regime comprising generation of a series of pulses.

43. The system according to claim 42 wherein said pulse regime provides at least one of the following: (i) the pulses are between 0.1 to 3 nanoseconds in duration; (ii) the fluence of a single pulse is from 0.84 to 10,000 J/cm2; and (iii) the total energy delivered to a single eye is from 4 to 20 J.

44. A method for delivering electromagnetic radiation to a region of an eye, the method comprising

(b) directing a first treatment beam of first electromagnetic radiation and a second aiming beam of second electromagnetic radiation of a visible spectrum towards the limbal area of the eye;

(c) passing each of said first and second beams of the first and second electromagnetic radiations through a beam shaping device configured in accordance with a circumference of a limbus or a sclera around the limbus and manipulating said beam shaping device for delivering the aiming visible beam onto said circumference thereby enabling visible control of the treatment beam propagation through said device in the form of one or more beams to the one or more regions on said circumference.

45. The method according to claim 44 for use in the treatment of glaucoma.