Vitrectomy probe with an optical fiber scanner

What is claimed is: 1. A vitrectomy probe for treating an eye of a patient, the probe comprising: a body arranged for grasping by a surgeon; and a photodisruption element extending from the body, the photodisruption element including: a needle having a main lumen extending from the body, the needle comprising a port in a side wall of the needle, wherein the needle is closed at a distal-most end of the needle, wherein the port has a bottom and an opposing top, wherein the bottom of the port is adjacent the distal-most end of the needle and wherein a distance between the bottom and the top forms a height of the port, and the port has a first side and an opposing second side that are located between the top and bottom such that a distance between the first and second sides forms a width of the port; a fiber cannula within the main lumen, the fiber cannula having a fiber lumen and the fiber lumen having a longitudinal axis; and an optical fiber within the fiber lumen, the fiber lumen being positioned in the needle to direct a laser beam from the optical fiber across the port in the side wall of the needle; a motor coupled to the optical fiber, wherein the motor agitates the optical fiber within the fiber lumen to scan the laser beam in a direction transverse to the longitudinal axis, repeatedly across the port in the side wall between the first side and the second side, at a frequency within a range of 10 hertz (Hz) to 10 kHz, such that vitreous humor entering the port in the side wall is severed by the scanning laser beam. 2. The probe of claim 1 , wherein the optical fiber comprises a rounded tip configured as a lens of the optical fiber. 3. The probe of claim 1 , wherein the optical fiber comprises a bearing at a tip of the optical fiber. 4. The probe of claim 3 , wherein the fiber lumen comprises a lens at a distal end of the fiber lumen, the lens shaped to fit the bearing such that agitation of the optical fiber causes the bearing to rotate within the lens. 5. The probe of claim 4 , wherein a distal surface of the optical fiber is directed such that mechanical agitation of the optical fiber causes a beam being projected from the distal surface to scan the port. 6. The probe of claim 4 , further comprising, wherein the main lumen is an aspiration lumen for extracting the vitreous humor that is severed by the laser beam projected from the optical fiber. 7. The probe of claim 4 , wherein the optical fiber is configured to emit the laser beam that converges across the port. 8. The probe of claim 4 , wherein the photodisruption element is curved. 9. An ophthalmic surgical system comprising: a probe comprising: a body arranged for grasping by a surgeon; a photodisruption element extending from the body, the photodisruption element including: a needle having a main lumen, the needle comprising a port in a side wall of the needle, wherein the needle is closed at a distal-most end of the needle, wherein the port has a bottom and an opposing top, wherein the bottom of the port is adjacent the distal-most end of the needle and wherein a distance between the bottom and the top forms a height of the port, and the port has a first side and an opposing second side that are located between the top and bottom such that a distance between the first and second sides forms a width of the port; a fiber cannula having a fiber lumen, wherein the fiber lumen has a longitudinal axis; and an optical fiber within the fiber lumen, the fiber lumen being positioned in the needle to project a laser beam from the optical fiber across the port in the side wall of the needle; and a motor coupled to the optical fiber to move the optical fiber in an elliptical motion within the fiber lumen such that the laser beam projecting from the optical fiber results in a travel path corresponding to an elliptical shape as the laser beam scans repeatedly, in a direction transverse to the longitudinal axis, at a frequency within a range of 10 hertz (Hz) to 10 kHz, across the port in the side wall, between the first side and the second side, of the needle such that vitreous humor entering the port in the side wall is severed by the scanning laser beam. 10. The system of claim 9 , further comprising, a console connected to the probe through at least one cable, wherein the console comprises: a power source in connection with the motor; and a vacuum source in fluid connection with the probe; and a laser light source in optical connection with the optical fiber. 11. The system of claim 9 , wherein the main lumen and the fiber lumen have a curved shape. 12. A method for operating a vitrectomy probe, the method comprising: projecting a laser beam from a surface of an optical fiber, the laser beam being projected across a port within a side wall of a needle of the vitrectomy probe having a closed distal end, the optical fiber being housed within a fiber cannula that is within the needle, the fiber cannula having a fiber lumen, wherein the fiber lumen has a longitudinal axis, and wherein the port has a bottom and an opposing top, wherein the bottom of the port is adjacent the closed distal end of the needle and wherein a distance between the bottom and the top forms a height of the port, and the port has a first side and an opposing second side that are located between the top and bottom such that a distance between the first and second sides forms a width of the port; and mechanically agitating the optical fiber within the fiber lumen such that the laser beam scans repeatedly, in a direction transverse to the longitudinal axis, at a frequency within a range of 10 hertz (Hz) to 10 kHz, across the port in the side wall of the needle between the first side and the second side, such that vitreous humor entering the port in the side wall is severed by the laser beam scanning the port. 13. The method of claim 12 , wherein the laser beam is a pulsed laser beam. 14. The method of claim 13 , wherein a pulse of the laser beam has a width within a range of 10-1000 femtoseconds (fs). 15. The method of claim 12 , wherein an energy of the laser beam is within a range of 1 micro-joule (0) to 10 milli-joules (mJ). 16. The vitrectomy probe of claim 12 , wherein mechanically agitating the optical fiber causes the laser beam to move back and forth in a linear pattern across the port such that, when at one end of the pattern, the laser beam is projected across the first side of the port, and wherein the laser beam, when at an opposing end of the pattern, is projected across the second side of the port. 17. The vitrectomy probe of claim 16 , wherein a laser beam path traverses the port from the first side of the port to the second side of the port to cover a port opening on both sides of the longitudinal axis such that the vitreous humor entering the port opening is severed by the scanning laser beam. 18. The vitrectomy probe of claim 12 , wherein mechanically agitating the optical fiber causes the laser beam to move in a random pattern between the first side and the second side of the port. 19. The vitrectomy probe of claim 4 , wherein a width of the laser beam is substantially smaller than the width of the port and wherein scanning the laser beam between the first side and the second side of the port allows the laser beam to traverse the width of the port to sever the vitreous humor entering the port. 20. The vitrectomy probe of claim 9 , wherein a width of the laser beam is substantially smaller than the width of the port and wherein scanning the laser beam between the fir