Surgical probe with interlocking attachment

The invention claimed is: 1. A method of manufacturing an optical probe for use in ophthalmic procedures, comprising: positioning a cannula around a distal portion of a ferrule, wherein an optical fiber extends at least partially through the ferrule towards an optical element disposed within a distal portion of the cannula; coupling the cannula to the ferrule by applying laser energy to the cannula; and generating engaged deformations in the cannula and the ferrule. 2. The method of claim 1 , further comprising: applying a bonding material to at least one of the cannula and the ferrule. 3. The method of claim 1 , wherein positioning the cannula includes: aligning the optical fiber and the optical element for optical communication. 4. The method of claim 1 , wherein generating engaged deformations includes: generating an interlock feature that restricts longitudinal displacement of the cannula relative to the ferrule. 5. The method of claim 1 , wherein generating engaged deformations includes: generating a recess in the ferrule. 6. The method of claim 5 , wherein generating engaged deformations includes: generating an inward radial protrusion in the cannula. 7. The method of claim 6 , wherein coupling the cannula to the ferrule includes: indirectly engaging the protrusion of the cannula to the recess of the ferrule through a bonding material disposed between the cannula and the ferrule. 8. The method of claim 6 , wherein coupling the cannula to the ferrule includes: directly engaging the protrusion of the cannula to the recess of the ferrule. 9. The method of claim 1 , further comprising: selecting at least one of a wavelength, a power, a power density, a pulse pattern, a peak irradiance, a pulse duration, and a spot size of the laser energy suitable to generate the engaged deformations. 10. The method of claim 1 , wherein coupling the cannula to the ferrule includes: applying the laser energy around a perimeter of the cannula. 11. The method of claim 10 , wherein: the laser energy is applied intermittently around the perimeter of the cannula. 12. The method of claim 10 , wherein: the laser energy is applied continuously around the perimeter of the cannula. 13. An optical probe comprising: a ferrule; a cannula disposed around a distal portion of the ferrule, the cannula and the ferrule coupled together by engaged deformations in the cannula and the ferrule; and an optical fiber positioned at least partially within the optical probe, the optical fiber configured to receive a light from a light source and guide the light to an optical element positioned within a distal portion of the cannula. 14. The optical probe of claim 13 , wherein: the cannula is positioned coaxially relative to the ferrule. 15. The optical probe of claim 13 , further comprising: a bonding material disposed between the ferrule and the cannula, and configured to couple the ferrule and the cannula. 16. The optical probe of claim 13 , wherein: the deformations are laser generated deformations. 17. The optical probe of claim 13 , wherein: the deformations define an interlock feature restricting longitudinal displacement of the cannula relative to the ferrule. 18. The optical probe of claim 13 , wherein: the engaged deformations include a recess in the ferrule. 19. The optical probe of claim 18 , wherein: the engaged deformations include an inward radial protrusion in the cannula. 20. The optical probe of claim 19 , wherein: the inward radial protrusion of the cannula indirectly engages the recess of the ferrule through a bonding material disposed between the cannula and the ferrule. 21. The optical probe of claim 19 , wherein: the inward radial protrusion of the cannula directly engages the recess of the ferrule. 22. The optical probe of claim 19 , wherein: an opening extends from an outer surface of the cannula through the inward radial protrusion. 23. The optical probe of claim 13 , wherein: the engaged deformations are intermittently disposed around a perimeter of the cannula. 24. The optical probe of claim 13 , wherein: the engaged deformations are continuously disposed around a perimeter of the cannula. 25. An ophthalmic surgical system, comprising: a light source configured to generate a light; and an optical probe in optical communication with the light source, the optical probe including: a ferrule; a cannula disposed around a distal portion of the ferrule, the cannula and the ferrule coupled together by engaged deformations in the cannula and the ferrule; and an optical fiber positioned at least partially within the optical probe, the optical fiber configured to receive the light from the light source and guide the light to an optical element positioned within a distal portion of the cannula.