Abstract: One or more connectors insertable into a surgical incision to couple rods together. The connector may include one or more bushings or joints to displace the one or more rods in one or more directions to a variety of orientations. One or more fasteners and/or bushings may be used to engage the one or more rods.

Abstract: An expandable implant (100, 150, 160, 200, 250, 300, 400) has a base (10) and a displaceable element (12) hingedly interconnected at one end. At the other end, the base and the displaceable element are formed with complementary jaws (24, 26) which provide continuous overlap of facing surfaces over a range of angular positions of the displaceable element relative to said base. In some cases, the first end portion (16) of the displaceable element (12) is formed with projecting teeth (28) forming a partial gear centered on an axis (18) of the hinged interconnection with the base (12) for engaging a worm gear. In certain embodiments, the base is formed with a socket (30) for removably receiving a worm gear tool (32) for engaging the teeth (28) and displacing said displaceable element. After expansion, the worm-gear tool (32) can be removed.

Abstract: A bone anchor insertion device for delivering one or more bone anchor components into bone is provided. The insertion device improves surgical control in bone anchor location, placement and insertion into target bone. The bone anchor insertion device also improves efficiency in placing the bone anchor. The surgical instrument provides improved control of stylet location and orientation, including directional control for precise bone anchor component insertion. Methods to use the bone anchor insertion device in surgical procedures are also provided.

Abstract: A device (10) which serves as a stiff guide wire for surgical procedures includes a tube (12) having an internal channel, and a central rod (14) in close-fitting sliding engagement within the tube. The tips of the tube and the central rod are in rigid mechanical engagement or interconnection. A region of the tube (112) is longitudinally slotted to form deflectable strips (18) so that advancing of the tube (12) relative to central the rod (14) causes outward deflection of the strips (18) to form an anchoring configuration. The central rod (14) and the tube (12) together define a stiff guide wire preferably having a length-to-width ratio in excess of 100:1.

Abstract: An implant (500, 600) includes first and second arms (14a, 14b) hinged to a base (12) at spaced-apart locations. An actuator (18, 22a, 22b, 602, 604, 606) is deployed to rotate the arms from an initial position in opposing angular motion towards a final position. A rigid bridging element (28) bridges between the arms so that deployment of the arms towards the final position displaces the bridging element away from the base. Engagement between the bridging element and at least one of the arms is via a double pin-in-slot engagement in which two non-collinear pins (30, 40) are engaged in respective non-parallel slots (32, 42).

Abstract: An implant (100, 200, 300, 400) includes a base (10), and a sequence of at least two segments including a first segment (12) and a last segment (14). The first segment (12) is pivotally linked to base (10). Adjacent segments are interconnected at pivotal connections (18). A bolt (20) has a threaded shaft (22) and a head (24). The threaded shaft (22) is engaged in a threaded channel (26) of the base (10) so that rotation of the bolt (20) about a central axis of the threaded shaft (22) varies a degree of overlap between the base (10) and the bolt (20). The last segment (14) and the head (24) define therebetween a spherical bearing (28). Rotation of bolt (20) thus varies a distance between spherical hearing (28) and hinge pin (16), thereby causing deflection of the sequence of segments.

Abstract: An adjustable implant includes a telescopic body with first and second portions in sliding engagement, and a deflectable linkage formed from a first linking segment, an intermediate segment and a second linking segment pivotally interconnected so that adjustment of a length of the telescopic body causes a corresponding deflection of the deflectable linkage. The first linking segment and the second linking segment are formed with projecting features that provide a partial gear engagement between the first and second linking segments such that, during adjustment of a length of the telescopic body and corresponding deflection of the deflectable linkage, pivotal motion of the first and second linking segments relative to the intermediate segment about the first and second pivot axes occurs in a fixed ratio defined by the partial gear engagement.

Abstract: A spinal alignment system can include a rod and a plurality of uniplanar screw assemblies that include a screw, a cap, and a housing. The screw and cap can be configured such that the relative angular displacement between the screw and the cap is limited to a first limit angle in a first plane and to a second limit angle in a second plane that is perpendicular to the first plane, the second limit angle being larger than the first limit angle. The housing can be coupled to the cap and configured to maintain the cap in proximity with the head of the screw. The housing can have two elongated elements forming a U-shaped saddle. The alignment system can also include a plurality of locking cap assemblies that capture the rod within the U-shaped saddle and are tightened to fixedly couple the rod to the respective uniplanar screw assemblies.

Abstract: A device (10) which serves as a stiff guide wire for surgical procedures includes a tube (12) having an internal channel, and a central rod (14) in close-fitting sliding engagement within the tube. The tips of the tube and the central rod are in rigid mechanical engagement or interconnection. A region of the tube (12) is longitudinally slotted to form deflectable strips (18) so that advancing of the tube (12) relative to central the rod (14) causes outward deflection of the strips (18) to form an anchoring configuration. The central rod (14) and the tube (12) together define a stiff guide wire preferably having a length-to-width ratio in excess of 100:1.

Abstract: An implant (100, 200, 300, 400) includes a base (10), and a sequence of at least two segments including a first segment (12) and a last segment (14). The first segment (12) is pivotally linked to base (10). Adjacent segments are interconnected at pivotal connections (18). A bolt (20) has a threaded shaft (22) and a head (24). The threaded shaft (22) is engaged in a threaded channel (26) of the base (10) so that rotation of the bolt (20) about a central axis of the threaded shaft (22) varies a degree of overlap between the base (10) and the bolt (20). The last segment (14) and the head (24) define therebetween a spherical bearing (28). Rotation of bolt (20) thus varies a distance between spherical bearing (28) and hinge pin (16), thereby causing deflection of the sequence of segments.

Abstract: An expandable implant (100, 150, 160, 200, 250, 300, 400) has a base (10) and a displaceable element (12) hingedly interconnected at one end. At the other end, the base and the displaceable element are formed with complementary jaws (24, 26) which provide continuous overlap of facing surfaces over a range of angular positions of the displaceable element relative to said base. In some cases, the first end portion (16) of the displaceable element (12) is formed with projecting teeth (28) forming a partial gear centered on an axis (18) of the hinged interconnection with the base (12) for engaging a worm gear. In certain embodiments, the base is formed with a socket (30) for removably receiving a worm gear tool (32) for engaging the teeth (28) and displacing said displaceable element. After expansion, the worm-gear tool (32) can be removed.

Abstract: A laterally deflectable asymmetric implant for implanting into a body may comprise a deflectable piece having distal and proximal ends and assuming a straightened insertion state. The backbone may abut or interconnect with said deflectable piece at the distal end of the deflectable piece. In a fully deflected state the implant may define an asymmetric shape, e.g. a D-shaped loop, defining an at least partially enclosed volume. The deflectable piece may comprise a sequence of segments interconnected at effective hinges. Longitudinal pressure applied to the proximal end of the deflectable piece (or applied to the backbone in an opposite direction) may cause relative longitudinal movement between the backbone and the proximal end of the deflectable piece and may generate outward horizontal movement of the deflectable piece away from the backbone. In one embodiment, the implant is implanted using lateral access into an anterior zone of a vertebra and deployed posteriorly.

Abstract: An implant (500, 600) includes first and second arms (14a, 14b) hinged to a base (12) at spaced-apart locations. An actuator (18, 22a, 22b, 602, 604, 606) is deployed to rotate the arms from an initial position in opposing angular motion towards a final position. A rigid bridging element (28) bridges between the arms so that deployment of the arms towards the final position displaces the bridging element away from the base. Engagement between the bridging element and at least one of the arms is via a double pin-in-slot engagement in which two non-collinear pins (30, 40) are engaged in respective non-parallel slots (32, 42).

Abstract: An adjustable implant includes a telescopic body with first and second portions in sliding engagement, and a deflectable linkage formed from a first linking segment, an intermediate segment and a second linking segment pivotally interconnected so that adjustment of a length of the telescopic body causes a corresponding deflection of the deflectable linkage. The first linking segment and the second linking segment are formed with projecting features that provide a partial gear engagement between the first and second linking segments such that, during adjustment of a length of the telescopic body and corresponding deflection of the deflectable linkage, pivotal motion of the first and second linking segments relative to the intermediate segment about the first and second pivot axes occurs in a fixed ratio defined by the partial gear engagement.

Abstract: An expanding implant (10, 10?, 10?) includes a base (12) having a contact surface (14) for contacting a first region of tissue and a displaceable portion. (24) having a contact surface (26) for contacting a second region of tissue. The base (12) has a proximal portion (16) in sliding engagement with, a distal portion (18) so as to define an arcuate path of relative motion between the proximal and distal portions. The base assumes an initial state with a first arcuate extent and is adjustable towards a second State by changing an: extent of overlap between the proximal and distal portions to vary an. arcuate extent of the base. First and second rigid linking segments (20, 22) are in articulating connection with the distal and proximal portions of the base, and with the displaceable portion such that adjustment of the base from the initial state towards the second state causes an increase in a distance between the contact surfaces of the base and the displaceable portion.

Abstract: An implant having a base with a first contact surface and a hinged element, hingedly interconnected with a first portion of the base, providing a second contact surface. The first portion of the base is displaceable relative to a second portion so that the base can be shortened from an initial length towards a second length. A linking segment is hingedly connected to both the second portion of the base and to the hinged element so that shortening of the base causes the linking segment to push a region of the hinged element away from the base, thereby changing an angle of the second contact surface relative to the first contact surface.

Abstract: A spinal alignment system can include a rod and a plurality of uniplanar screw assemblies that include a screw, a cap, and a housing. The screw and cap can be configured such that the relative angular displacement between the screw and the cap is limited to a first limit angle in a first plane and to a second limit angle in a second plane that is perpendicular to the first plane, the second limit angle being larger than the first limit angle. The housing can be coupled to the cap and configured to maintain the cap in proximity with the head of the screw. The housing can have two elongated elements forming a U-shaped saddle. The alignment system can also include a plurality of locking cap assemblies that capture the rod within the U-shaped saddle and are tightened to fixedly couple the rod to the respective uniplanar screw assemblies.

Abstract: A device for immobilizing adjacent spinous processes can comprise a first element, a second element, and a spacer element. The first element can have a side configured to grip first sides of the adjacent spinous processes and a first separation bar that extends between the adjacent spinous processes when the first element and the spinous processes are engaged. The spacer element can have an adjustment bar and a second separation bar. The second element can have a side configured to grip second sides of the adjacent spinous processes and a clamping feature configured to selectably lock the first separation bar and the adjustment bar in place. The second separation bar can extend between the adjacent spinous processes when the second element and the adjacent spinous processes are engaged.

Abstract: A spinal alignment system is disclosed that includes a rod and a plurality of uniplanar screw assemblies that include a screw, a cap, and a housing. The screw and cap are configured such that the relative angular displacement between the screw and the cap is limited to a first limit angle in a first plane and to a second limit angle in a second plane that is perpendicular to the first plane, the second limit angle being larger than the first limit angle. The housing is coupled to the cap and configured to maintain the cap in proximity with the head of the screw. The housing has two elongated elements forming a U-shaped saddle. The alignment system also includes a plurality of locking cap assemblies that capture the rod within the U-shaped saddle and are tightened to fixedly couple the rod to the respective uniplanar screw assemblies.

Abstract: Disclosed is an apparatus and a method for surgical dilation and retraction of tissues during a medical procedure, for example a spinal surgery. The apparatus includes a dilator assembly that includes a plurality of slidingly engaging dilators, wherein at least one dilator includes an outer wall shape different from its inner wall shape. At least one of the dilators may include an eccentrically positioned circular channel, a generally oblong outer wall shape, and a longitudinal gap in a wall. The dilator system may be used in a method that provides off center differential dilation of tissues in one or more preferred directions. A retractor system that may be used with the dilator system is also disclosed.