System and method for plasma-mediated modification of tissue

What is claimed is: 1. A system for cataract surgery on an eye of a patient, comprising: a. a first laser source configured to deliver a first laser beam in a pulsed form at a first pulse energy of between one-half microjoule and 50 microjoules; b. a second laser source configured to deliver a second laser beam in a pulsed form at a second pulse energy greater than the first pulse energy, the second pulse energy being between 50 microjoules and 5,000 microjoules; c. a scanning optical system, configured to: i. receive the first and second laser beams; and ii. adjust a first focus position of the first laser beam, and a second focus position of the second laser beam, in up to three dimensions to direct the first and second laser beams onto one or more targeted tissue structure portions of the eye of the patient; d. a controller operatively coupled to the scanning optical system and configured to cause the scanning optical system to scan the first focus position of the first laser beam in a first scanning pattern to photodisrupt a first tissue structure portion with a plurality of pulses of the first laser beam to form an incised surface, and, subsequent to scanning the first focus position of the first laser beam in the first scanning pattern, scan the second focus position of the second laser beam in a second scanning pattern that is co-registered to the first scanning pattern to dispose the second focal position on the incised surface for a plurality of pulses of the second laser beam to further photodisrupt the same first tissue structure portion with the second laser beam to further separate segments of the first tissue structure along the incised surface wherein the pulses of the first laser beam scanned in the first scanning pattern have a first pulse duration between 100 femtoseconds and 10 picoseconds, and the pulses of the second laser beam scanned in the second scanning pattern have a second pulse duration between 10 picoseconds and 10 nanoseconds and is longer than the first pulse duration. 2. The system of claim 1 , wherein the first tissue structure portion is a portion of a crystalline lens of the eye. 3. The system of claim 1 , wherein the controller is operatively coupled to the first and second laser sources, and configured to control the first and second pulse energies. 4. The system of claim 1 , wherein the first scanning pattern is configured to divide the lens into two or more discrete segments. 5. The system of claim 1 , wherein the first scanning pattern comprises a three-dimensional pattern wherein two or more pulses are targeted for two or more different depths within the targeted tissue structure portion. 6. The system of claim 1 , wherein the pulses of the first laser beam scanned in the first scanning pattern have a substantially distinct range of pulse energies relative to the pulses of the second laser beam scanned in the second scanning pattern. 7. The system of claim 6 , wherein the pulses of the first laser beam scanned in the first scanning pattern have a pulse energy of 1 microjoule to 20 microjoules and the pulses of the second laser beam scanned in the second scanning pattern have a pulse energy of 100 microjoules to 3 millijoules. 8. The system of claim 7 , wherein the pulses of the first laser beam scanned in the first scanning pattern are directed to a deeper portion of the targeted tissue structure portion than the pulses of the second laser beam scanned in the second scanning pattern. 9. A system for cataract surgery on an eye of a patient, comprising: a. a first laser source configured to deliver a first laser beam in a pulsed form at a first pulse energy of between one-half microjoule and 50 microjoules; b. a second laser source configured to deliver a second laser beam in a pulsed form at a second pulse energy greater than the first pulse energy, the second pulse energy being between 50 microjoules and 5,000 microjoules; c. a scanning optical system configured to receive the first and second laser beams; and direct a focus position of the first laser beam and a focus position of the second laser beam in up to three dimensions within the lens of the patient's eye; d. a controller operatively coupled to the scanning optical system and programmed to cause the scanning optical system to (i) scan the focus position of the first laser in a first pattern so as to photodisrupt tissue with a plurality of pulses of the first laser beam to incise a plurality of intersecting cut planes within the lens; and (ii) subsequent to scanning the focus position of the first laser in the first pattern, scan the focus position of the second laser in a second pattern that is co-registered with the first pattern to dispose the focus position of the second laser on at least one of the cut planes for a plurality of pulses of the second laser beam so as to further photodisrupt tissue along at least one of the cut planes incised by the scanning of the first laser to further separate segments of the tissue along at least one of the cut planes incised by the first laser, wherein the pulses of the first laser beam scanned in the first scanning pattern have a first pulse duration between 100 femtoseconds and 10 picoseconds, and the pulses of the second laser beam scanned in the second scanning pattern have a second pulse duration between 10 picoseconds and 10 nanoseconds that is longer than the first pulse duration. 10. A system for cataract surgery on an eye of a patient, comprising: a. a laser light source configured to deliver a first laser beam in a pulsed form at a first pulse energy of between one-half microjoule and 50 microjoules, and a second laser beam in a pulsed form at a second pulse energy greater than the first pulse energy of between 50 microjoules and 5,000 microjoules; b. a scanning optical system configured to receive the first and second laser beams; and direct a focus position of the first laser beam and a focus position of the second laser beam in up to three dimensions within the lens of the patient's eye; c. a controller operatively coupled to the scanning optical system and programmed to cause the scanning optical system to (i) scan the focus position of the first laser beam in a first pattern so as to photodisrupt tissue with a plurality of pulses of the first laser beam to incise a plurality of intersecting cut planes within the lens; and (ii) subsequent to scanning the focus position of the first laser beam in the first pattern, scan the focus position of the second laser beam, for a plurality of pulses of the second laser beam, in a second pattern that is co-registered with the first pattern so as to further photodisrupt tissue along at least one of the cut planes incised by the scanning of the first laser beam to further separate segments of the tissue along at least one of the cut planes incised by the scanning of the first laser beam, wherein the pulses of the first laser beam scanned in the first scanning pattern have a first pulse duration between 100 femtoseconds and 10 picoseconds, and the pulses of the second laser beam scanned in the second scanning pattern have a second pulse duration between 10 picoseconds and 10 nanoseconds and is longer than the first pulse duration. 11. The system of claim 10 , wherein the laser light source includes a first laser source configured to deliver the first laser beam and a second laser source configured to deliver the second laser beam. 12. The system of claim 1 , wherein the second scanning pattern comprises increased spacing between the focus position of adjacent pulses of the second laser beam relative to spacing between the focus position of adjacent pulses of the first laser beam in the first s