1. A method for stabilizing a bone structure of a patient, the method comprising steps of:
identifying a target site for locating an expandable member within a bone structure at a predetermined location,
directing a distal end of a generally straight access cannula into the bone structure near the target site;
providing a guide stylet assembly that comprises
a stylet including memory metal and having a distal pre-set stylet curved; and
an overlying flexible polymeric delivery tube through which the stylet snugly and slidably extends, where the stylet and the delivery tube have sufficient length to extend through and be operable beyond the distal end of the access cannula, and where the stylet pre-set curved portion is held generally longitudinally straight when the stylet is constrained by the access cannula;
directing the stylet and overlying delivery tube simultaneously and coaxially through the access cannula and out the distal end of the access cannula, where the pre-set stylet curved portion, no longer constrained by the access cannula, curves toward and forms a path into the target site as it is extended out of the access cannula distal end;
withdrawing the stylet from the overlying delivery tube; then,
directing an expandable member in a contracted state through the delivery tube into the target site where the delivery tube provides effective protection for the expandable member from damaging contact with the bone structure;
expanding the expandable member to form a cavity at the target site; and, thereafter,
delivering a curable material into the cavity.
2. The method of claim 1, further comprising, as part of the providing the guide stylet assembly step, steps of
determining a desired curvature path between the distal end of the access cannula and the approximate center of the target site;
selecting the guide stylet including a distal preset curved portion corresponding to said curvature path from a plurality of guide stylets each having a distal preset curved portion with a different preset curvature;
inserting the selected stylet through the delivery tube and thereafter executing the step of directing the stylet and overlying delivery tube.
3. The method of claim 1, where the pre-set curved of the stylet is oriented to transit from the distal end of the access cannula to approximately the center of the target site.
4. The method of claim 1, where the cavity formed is generally symmetrical within the target site.
5. The method of claim 1, where the cavity formed is generally symmetrical within the bone structure relative to boundaries of the bone structure.
6. The method of claim 1, further comprising, before the step of delivering curable material, removing the expandable member.
7. The method of claim 1, where the step of delivering curable material into the cavity comprises directing a curved delivery cannula through the access cannula into the cavity and directing curable material through the curved delivery cannula into the cavity.
8. The method of claim 1, further comprising an intermediate step of removing the delivery tube after the step of directing the stylet and overlying delivery tube.
9. The method of claim 1, where the curable material is delivered through the delivery tube.
10. The method of claim 1, where the delivery tube comprises at least one radio-opaque marker.
11. The method of claim 1, further comprising a step of directing, through the delivery tube, a metal needle including a distal curved portion and a distal-most straight portion open at its distal terminus and configured to allow the expandable member to be deployed therefrom.
12. The method of claim 1, where step of directing an expandable member further comprises directing, through the delivery tube, a metal needle including a distal curved portion and a distal terminus end opening through which the expandable member is deployed where the metal needle curve and the stylet curve are about the same when unconstrained and are constrained to a generally straight orientation when constrained during passage through the access cannula.
13. The method of claim 1, further including providing radio-opaque contrast material into the cavity, internal to or external of the expandable member.
14. The method of claim 1, where the stylet includes a distalmost straight portion that is distal of the preset curved portion.
15. A system configured for stabilizing a bone structure of a patient, the system comprising:
an access cannula configured for penetrating into a bone structure;
a guide stylet assembly that comprises
a stylet including memory metal and incorporating a distal pre-set curved stylet portion; and
an overlying flexible polymeric delivery tube through which the stylet coaxially, snugly, and slidably extends, where the stylet and the flexible polymeric delivery tube have sufficient length to extend through and be operable beyond the distal end of the access cannula, and where the pre-set curved stylet portion is held generally longitudinally straight when the stylet is constrained by the access cannula; and
an expandable member dimensioned and operable for passage through and deployment outside a distal end of the flexible polymeric delivery tube in a manner displacing bone material.
16. The system of claim 15, further comprising a curved delivery cannula configured for passage through the access cannula, where the delivery cannula includes a closed distal end terminus and a side-facing opening near the terminus, where the opening is oriented along an outside surface of the curved portion of the delivery cannula near the closed distal end terminus.
17. The system of claim 16, further comprising proximal end indicia showing the direction of curvature of the curved delivery cannula.
18. The system of claim 15, further comprising proximal end indicia showing the direction of curvature of the stylet’s pre-set curved portion and indicating when a distal end terminus of the stylet is aligned with and ready to exit the distal end of the delivery tube.
19. The system of claim 15, where the expandable member is embodied as a fluid-inflatable balloon configured to create a cavity by displacing cancellous bone.
20. The system of claim 15, further comprising a curved delivery cannula configured for passage through the access cannula and including a pre-set curved delivery cannula portion corresponding to the stylet pre-set curved portion, the delivery cannula containing pre-loaded, but not-yet-cured, curable material.
21. A method for stabilizing a bone structure of a patient, the method comprising steps of:
identifying a target site for locating an expandable member within a bone structure at a predetermined location,
directing a distal end of a generally straight access cannula into the bone structure near the target site;
providing a guide stylet assembly that comprises
a stylet including memory metal and incorporating a distal pre-set stylet curve; and
an overlying flexible polymeric delivery tube through which the stylet snugly and slidably extends, where the stylet and the delivery tube have sufficient length to extend through and be operable beyond the distal end of the access cannula, and where the pre-set curve is held generally longitudinally straight when the stylet is constrained by the access cannula;
directing the stylet and overlying delivery tube simultaneously and coaxially through the access cannula and out the distal end of the access cannula, where the pre-set stylet curved, no longer constrained by the access cannula, curves toward and forms a path into the target site as it is extended out of the access cannula distal end;
withdrawing the stylet and the overlying delivery tube; then,
directing an expandable member in a contracted state through the path formed into the target site;
expanding the expandable member to form a cavity at the target site; and, thereafter,
delivering a curable material into the cavity.
22. The method of claim 21, further comprising steps of:
directing an expandable member in a contracted state through the access cannula into the target site;
expanding the expandable member to form a cavity at the target site; and, thereafter,
delivering a curable material into the cavity.
23. The method of claim 22, where the step of delivering a curable material is executed by delivering said curable material via a curved delivery cannula, including a pre-set curved delivery cannula portion, directed through the access cannula.
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
1. A system for predicting optical power for an intraocular lens, comprising:
a first computing device capable of measuring at least one biometric parameter of a first eye;
a second computing device capable of measuring andor processing andor introducing corneal spherical aberration of the eye according to the at least one biometric parameter;
a third computing device capable of applying, by at least one computing processor, a modified regression to the at least one biometric parameter and the corneal spherical aberration to output an optimized one of the optical power to obtain a desired postoperative condition, wherein the modified regression is of the form:
optical power=Regression+constant0*(corneal spherical aberration)
or
optical power=constant1*(biometric parameter)+constant0*(corneal spherical aberration)
wherein constant1 and constant0 comprise an empirically derived factor across other eyes, and wherein the Regression comprises a classical regression and biometric parameter is related to the values of the at least one measured eye’s parameter.
2. The system of claim 1, further comprising a feedback input to said third computing device for modifying the modified regression in accordance with the optimized one of the optical power.
3. The system of claim 1, wherein the at least one biometric parameter comprises at least one of axial length, anterior chamber depth and corneal power, whenever it is needed.
4. The system of claim 1, wherein the desired postoperative condition comprises a postoperative refraction.
5. The system of claim 1, wherein the Regression comprises one selected from at least Hoffer Q regression, Haigis regression, Holladay1 regression, Holladay2 regression, and SRKT regression.
6. The system of claim 1, wherein said second device can comprise a corneal topographer.
7. The system of claim 6, wherein said second device can comprise a ray tracing software.
8. An intraocular lens, comprising:
a selected optic from a plurality of available optics, wherein the selected optic comprises a selection based on an optical power that obeys the equation:
optical power=constant1*Regression+constant0*(corneal spherical aberration)
or
optical power=constant1*(biometric parameter1)+ . . . +constantn*(biometric parametern)+constant0*(corneal spherical aberration),
wherein the constant 0 to constant n comprises an empirically derived constant, and wherein the Regression variable comprises a regression formula selected from at least a Hoffer Q and a Haigis regression, and biometric parameter1 to biometric parameter n comprises the biometric measurements stated at claim 15; and
at least one haptic for physically supporting the selected optic.