Abstract: Devices and methods that allow a rod to be offset in a relatively small amount of space are disclosed herein. In some embodiments, first and second offset rods can be joined by a plate-type connector having a reduced thickness suitable for insertion into a small space, e.g., between adjacent bone anchors. In some embodiments, first and second offset rods can be joined by a curved connector that conforms to adjacent bone anchors and likewise has a reduced thickness.

Abstract: A medical cross connector, a corresponding matching torque wrench, and a corresponding medical product set that includes the medical cross connector in combination with at least one bone implant and/or other matching surgical accessory. The medical cross connector includes a cross strut for connecting two longitudinal rods that can be brought into operative engagement for orientation of vertebrae of a spinal column, and at least one clamping head mounted pivotably on the cross strut in an angular bearing. The clamping head has a rod receptacle and a clamping screw. A clamping tooth applies a clamping force to one of the longitudinal rods when the rod is inserted into the rod receptacle. The clamping tooth is mounted pivotably about a pivot axis via a floating bearing. The floating bearing permits a pivoting movement and a lateral movement of the pivot axis of the clamping tooth.

Abstract: In some embodiments, a connector can be configured to couple a first fixation element (e.g., a first rod) to a second fixation element (e.g., a second rod). One or both of the first and second fixation elements can be included with the connector, or one or both can be separately provided. In some instances, at least one of the fixation elements is previously implanted in a patient. The connector can provide one or more degrees of freedom between the first and second fixation elements. The connector can also include a locking element configured to (1) lock one or more of the fixation elements to the connector, and (2) lock one or more of the degrees of freedom between the fixation elements. The connector can be configured to snap onto or otherwise engage a fixation element in a manner that provides tactile and/or audible feedback to the surgeon.

Abstract: An implant for the stabilization of bones or vertebrae is provided, the implant being a solid body including a longitudinal axis that defines a longitudinal direction and including a flexible section that has a surface and has a length in the longitudinal direction, the flexible section including at least one cavity located near the surface and having a width in the longitudinal direction that is smaller than the length of the flexible section, the at least one cavity being connected to the surface through at least one slit, and a width of the slit in the longitudinal direction being smaller than the width of the cavity.

Abstract: A rod reducer includes a housing, an anvil, a locking anvil configured to engage a locking plug of a bone screw assembly, an arm assembly, a reducing screw extending through the housing and rotatably coupled with the anvil, and a locking screw extending through the housing and rotatably coupled with the locking anvil. The arm assembly includes an arm hingedly coupled to the housing, and first and second grasping members configured to engage the bone screw assembly. The first and second grasping members are hingedly coupled to the housing and extend through the anvil. Rotation of the reducing screw transitions the arm assembly between an open position, in which, distal portions of the arm and the first and second grasping members are radially expanded, and a closed position, in which, the distal portions of the arm and the first and second grasping members are radially contracted.

Abstract: A spinal stabilization system comprises a bone screw including a bone engaging portion and a yoke, the yoke having top surface and bottom surfaces. The yoke has a rod receiving channel defined by a pair of opposed arms, an elongate connecting rod being received within the channel. A head to head cross connector comprises a connecting element having one end in connection with the bone screw and an opposite other end. The one end defines a connecting portion having an opening therethrough and a connecting bar communicating with the opening. The connecting bar, having upper and lower surfaces, resides within the channel, the lower surface contacting the rod. The connecting bar in a non-secured position is movable within the channel in at least two degrees of freedom. A set screw supported by the yoke rigidly secures the connecting bar to the rod and the rod to the yoke.

Abstract: A spinal construct is disclosed. The spinal construct may include a connector having a body including a first implant cavity and a second implant cavity. The first implant cavity being defined, at least partly, by at least two threaded arm portions. The first implant cavity may include a first receiving cavity configured to adjustably orient a first rod in a plane substantially perpendicular to the first axis. The second implant cavity may include a second receiving cavity configured to orient a second rod. In some embodiments, the threaded arm portions may be configured to receive a first set screw such that when the first set screw is fully tightened along the first axis the first rod is fixed relative to the body in a direction extending substantially parallel with the plane. In some embodiments, the body may further include a threaded opening communicating with the second receiving cavity.

Abstract: A bone screw assembly includes an anchor portion and a head portion, such as a rod-receiving portion, movably mounted to the anchor portion to allow for controlled angulation between the anchor portion and the head portion. The anchor portion is pivotable in one or more selected directions about an axis relative to the head portion. A restriction member, which may be a rod seat, prevents the anchor portion from pivoting in one or more different directions about another axis relative to the head portion and/or a spinal fixation element received in the head portion. The restriction member may be inserted in the head portion to control direction that the anchor portion pivots relative to the head portion. The restriction member may also serve as a compression member and/or rod seat for seating a spinal rod coupled to the bone screw assembly.

Abstract: A spinal stabilization system may be formed in a patient. In some embodiments, a minimally invasive procedure may be used to form a spinal stabilization system in a patient Bone fastener assemblies may be coupled to vertebrae Each bone fastener assembly may include a bone fastener and a collar. The collar may be rotated and/or angulated relative to the bone fastener. Detachable members may be coupled to the collar to allow for formation of the spinal stabilization system through a small skin incision. The detachable members may allow for alignment of the collars to facilitate insertion of an elongated member in the collars. An elongated member may be positioned in the collars and a closure member may be used to secure the elongated member to the collars.

Abstract: A cross-connector, sized and dimensioned to stabilize the distance between a pair of rods in the spine. The cross-connector includes a first coupling assembly, a second coupling assembly, and a connecting device, extending therebetween. Each coupling assembly further includes a coupler, which attaches to a tulip head, and a camming assembly. The connecting device further includes a first arm element, a second arm element, and a screw. The arm elements move within the ball joints of the couplers and pivot around the screw, allowing a surgeon to adjust the length of the cross-connector and place the cross-connector above and around features within the body. The camming assemblies lock the tulip heads and the arm elements in place on the couplers. The screw locks the center rotation of the cross-connector.

Abstract: A prosthetic spinous process cross-link implant for the replacement of a posterior vertebral element. The implant includes a cross link body member with a pair of adjustable link arms connected to the cross link body to size the implant to specific anatomical configurations. The implant includes a rod clamp that is spring loaded to a forward position such that capturing a spinal rod on to the adjustable link arms to achieve a snap on effect thereby increasing the ease of installation. A plurality of spinous process cross-link implants can be assembled as a kit wherein the set includes a group of spinous process type yokes and bridge type yokes each group including both fixed and variable sized implants.

Abstract: In an embodiment of the invention, for spinal surgery, there is provided an offset arm system that has angular adjustment capability. In an embodiment, there are provided a hook system that is polyaxially or otherwise movably coupled to a body that receives a spinal rod.

Abstract: A transverse rod connector includes an elongate member having first and second ends and first and second connection members. The first and second connection members are connected with first and second ends, respectively. The first and second connection members are configured for multidirectional positioning with respect to the elongate member. The first and second connection members are each dimensioned to be selectively and releasably secured to a bone anchor. The elongate member is longitudinally adjustable.

Abstract: A cross connector for attachment between two spinal implants comprises a first element having one end and an opposite end configured for engaging one of the two spinal implants, a second element having one end and an opposite end configured for engaging the other of the two spinal implants, an engagement mechanism between the one end of each of the first and second elements, and a locking element for locking the two elements together at the respective one end. The engagement mechanism includes an interface configured to permit relative pivoting between the first element and the second element about at least two non-parallel axes.

Abstract: The present disclosure provides a transverse connector having first and second spinal rod connecting members disposed on opposing ends of a cross member. Each spinal rod connecting member is configured to connect to a spinal rod. The first and second spinal rod connecting members are configured for multidirectional articulation relative to the cross member.

Abstract: A spinal implant includes a first rod, a second rod, and connector. The first rod has a first end configured to be connected to a first bone, a second end opposed to the first end, and a longitudinal axis that passes through the first and second ends. The second rod has a first end configured to be connected to the second bone, a second end opposed to the first end. The second rod is parallel to the longitudinal axis and non-coaxial with the first rod, and at least a portion of the second end of the second rod overlaps the second end of the first rod. The connector connects the second end of the first rod to the second end of the second rod, and is configured to urge the first rod and the second rod in opposed directions that are parallel to the longitudinal axis.

Abstract: An implant support comprises a first member including a first portion and a second portion configured to engage a bone fastener. The second portion extends in a transverse orientation from the first portion. The members define a longitudinal axis. The second member includes a first portion and a second portion configured to engage the bone fastener. The second portion of the second member extends in a transverse orientation from the first portion. At least one of the members is movable relative to the longitudinal axis between a first configuration and a second configuration such that the longitudinal axis is offset relative to an axis of the bone fastener. Systems and methods are disclosed.

Abstract: Devices and methods are disclosed for treating the vertebral column. One embodiment provides a transverse connector for vertebral fixation systems comprising a first connector body comprising a first engaging member for engaging a first elongate member and a first locking member, a second connector body comprising a second engaging member for engaging a second elongate member, and a transverse rod coupled to the first connector body and the second connector body, thereby forming an articulation between a first end of the transverse rod and the first connector body, wherein the first locking member is configured to secure both the articulation and the first elongate member to the first connector body.

Abstract: A clamp for attaching a cross connecting device to a spinal fixation system comprising an outer body and an inner body. The outer body defines an internally threaded bore and an outer body cavity, and the inner body defines an inner body cavity. The inner body is at least partially disposed within the outer body. A pin is provided for connecting the inner and outer bodies to each other, while allowing for a limited amount of movement therebetween. A set screw suitable for being driven into the internally threaded bore is provided for securing the inner body to the spinal fixation system.

Abstract: Various methods and devices are provided for connecting spinal fixation elements, such as spinal rods, implanted in a patient's spinal column. In particular, various spinal cross connectors are provided for connecting to one or more spinal fixation elements implanted in a patient's spine. The cross connectors can have a variety of configurations, including a fixed or adjustable length, as well as various features that allow certain portions of the cross connectors to be angularly oriented.

Abstract: A rod connector for transversely connecting two vertebral column rods has two clamps and a transverse bridge that fixes the clamps to each other. The clamps have a spring device with a spring force that is low enough to allow the clamp to be manually snapped onto the vertebral column rod, to be slid onto the same in the installed state, and to be released from same. An attaching device for the clamp, which is independent of the spring device, generates a retaining force that is high enough to solidly attach the clamp on the vertebral column rod in the installed state. The transverse bridge has a connection part with a frame for receiving a first branch connected to one clamp and with a ball rotatably mounted in the frame and having a second branch pass therethrough that connects to another clamp.

Abstract: A transverse connector system having a first and a second locking head, and a transverse rod that is secured by the first and second locking heads. The first and second locking heads are provided with a first and second pivot arm for engaging and securing first and second elongated rods. The first and second locking heads each simultaneously engage and secure the transverse and elongated rods separately.

Abstract: The invention relates to a sterile barrier (S) for a surgical robot (1) comprising at least one joint (12 . . . 15) with two opposing joint members (40, 42) that rotate relative to one another about a common joint axis (16 . . . 19) and a torque sensor (29) comprising: at least two sterile barrier sections (24 . . . 28) each with an end section (38, 39) for sealed attachment to a respective joint end section (41, 43) of the joint member (40, 42); and a sealing arrangement (30) for producing a sterile and sealed rotating connection of the end sections (38, 39) of the at least two sterile barrier sections (24 . . . 28); and a surgical robot (1).

Abstract: A spinal rod assembly may be formed by attaching an extension portion onto a spinal rod that extends along a longitudinal axis. The extension portion may include a rod coupler that attaches to the spinal rod with a first coupling that includes a first degree of rotational freedom and a first degree of translational freedom in positioning the rod coupler relative to the spinal rod along the longitudinal axis. The extension portion may further include an extender rod including an elongated rod body that may be secured to the rod coupler using a second coupling that includes at least a second degree of rotational freedom in positioning the extender rod relative to the rod coupler about an axis substantially perpendicular to the longitudinal axis. The extension portion may be assembled in situ to a spinal rod that has been previously secured to vertebral bodies in a patient.

Abstract: A multi-axial spinal cross-connector is configured for connection between spinal fixation devices such as spinal fixation rods. The cross-connector has first and second connection members that are joinable at a fixable pivot junction. The pivot junction allows the connection members to assume various positions relative to one another. A clamp is provided on each end of the first and second connection members whose open and closed states are controlled by fixation of a pivot structure which also fixates the positions of the first and second connection members relative to each other. The cross-connector provides single and/or multi-step locking of both end clamps at the pivot joint. The cross-connector also provides easy in situ sizing, positioning and adjustability.

Abstract: A transverse connector for coupling between first and second vertebral anchors of a spinal stabilization system. The transverse connector includes a first coupling assembly proximate a first end, a second coupling assembly proximate a second end, a first fastener having external threading configured to threadably engage an internal threaded portion of a housing of the first vertebral anchor, and a second fastener having external threading configured to threadably engage an internal threaded portion of a housing of the second vertebral anchor. Each of the first and second fasteners includes a spherical upper surface, such as a spherically concave upper surface. A spherical surface of each of the first and second coupling assemblies mates with the spherical upper surface of the respective fastener to provide multi-axial rotation of the transverse connector relative to the housings to permit a desired orientation of the transverse connector.

Abstract: Provided is a novel low profile transverse connector system having a first and second spinal rod connection member disposed at opposing ends of an elongated cross connection device, each connection member having a distal end configured to be capable of connecting to a spinal rod and a proximal end having a multidirectional articulation joint at which a centrally disposed cross connecting assembly is provided to attach the first and second connection members to each other, the first and second spinal rod connection members each defining two opposing compression slots that serve to facilitate a secure connection to spinal rods and to the cross connecting assembly by the tightening of only one locking screw. Also provided is a method of stabilizing vertebrae using the disclosed system.

Abstract: Transconnector devices and methods of use are provided. A transconnector device has the capability of connecting to elongate spinal fixation elements having various cross-sectional dimensions. The transconnector device is adjustable in three degrees of freedom and is curved to ensure that it maintains a minimum distance posterior of the dura when it is fixed to elongate spinal fixation elements.

Abstract: An implant device includes a pair of hook devices and an elongate guide device. The hook devices are configured to be disposed between and engage adjacent vertebral bodies. The elongate guide device is connected to the hook devices and allows for relative movement of at least one of the hook devices to adjust for the geometries of the vertebral surfaces to be engaged by the hook devices.

Abstract: The invention consists of disc replacement implant for the lumbar spine designed for insertion into the disc space via a posterior approach. The implant can be stabilized in the disc space by connection to the vertebra or can be connected to dynamic spinal stabilization device consisting of interconnected bullets nested in a spring nested in a woven sleeve. By controlling the limits of elongation and compression the device prevents movement beyond normal physiological limits. In the midrange of movement flexibility is allowed. A method for using the dynamic spinal stabilization device is also provided.

Abstract: Dynamic posterior stabilization systems and methods of stabilizing vertebrae are described. A dynamic posterior stabilization system may include a first bone fastener configured to couple to a first vertebra, a second bone fastener configured to couple to a second vertebra, and a dampener system attached to the first bone fastener and the second bone fastener. The dampener system may include a first dampener set and a second dampener set. Compression of the first dampener set provides resistance to movement of the first bone fastener towards the second bone fastener. Compression of the first dampener set and the second dampener set provides resistance to movement of the first bone fastener away from the second bone fastener.

Abstract: A cross connecting device suitable for connecting first and second spinal fixation devices comprises a fixable pivot junction, first and second connection members, and first and second clamps. The fixable pivot junction includes a pivotable joint that is pivotable about a pivot point. The fixable pivot junction also includes a collar configured for fixating the pivot junction. The first and second connection members are connected by the fixable pivot junction such that the fixable pivot junction allows the first and second connection members to be repositioned relative to each other. The first and second clamps are connected to respective ones of the first and second connection members at distal ends of the connection members relative to the fixable pivot junction. The first and second clamps allow the cross connecting device to be clamped on to spinal fixation devices, such as pedicle screws or hooks.

Abstract: A transverse crosslink device is presented. The transverse crosslink device has a connecting member, a first rod gripping assembly, and a second rod gripping assembly. The rod gripping assemblies can be pivotly connected to an end of the connecting member, such that the rod gripping assembly can selectively pivot in a direction substantially transverse to the longitudinal axis of the connecting member. The rod gripping assemblies can also be configured to selectively grip a portion of a stabilizer rod.

Abstract: An insert (70) for a clamping element with two jaws to clamp a rod-shaped element comprises an inner cavity (144) to accommodate a rod-shaped element and at least one flange element (153) at one longitudinal end of the insert intended to abut against the clamping element. The flange element (153) comprises clamping members (161) to reduce the available room within the inner cavity (144) for the rod-shaped element to be clamped and to clamp the flange element (153) between the rod-shaped element and an outer clamping surface of the clamping element to prohibit any longitudinal movement of the clamped insert.

Abstract: Various methods and devices are provided for connecting spinal fixation elements, such as spinal rods, implanted in a patient's spinal column. In particular, various spinal cross connectors are provided for connecting to one or more spinal fixation elements implanted in a patient's spine. The cross connectors can have a variety of configurations, including a fixed or adjustable length, as well as various features that allow certain portions of the cross connectors to be angularly oriented.

Abstract: An apparatus comprises a pair of bone attachment devices and a crosslink device for a spinal fixation system or other implant arrangement. The bone attachment devices include a head with socket to receive a spinal rod or other elongate element and the crosslink device includes a pair of bridging members each having an end section for connecting with the bone attachment devices. An interconnection device situated between the bridging members receives the bridging members and allows translational and rotational freedom therebetween while being operable to secure the bridging members in position relative to one another. A pair of engaging members are structured to engage the head of the respective bone attachment device and bear against the respective adjacent end of crosslink device to lock the crosslink and the bone attachment device in a rigid construct are also included.

Abstract: A transconnector for joining adjacent longitudinal spinal rods. The transconnector preferably includes a bridge member and a pair of bone fixation coupling elements, the bridge member is preferably sized and configured to span a distance between the pair of bone fixation coupling elements. The bone fixation coupling elements are preferably sized and configured to engage the bridge member and sized and configured to receive one of the bone fixation elements. The bone fixation coupling elements are preferably sized and configured to engage the body portion of the bone fixation element. The bone fixation coupling elements may include a locking cap having a first set of threads for threadably engaging the bone fixation element.

Abstract: Superior and/or inferior facets of one or more facet joints may be replaced by superior and/or inferior facet joint prostheses. In one embodiment, a kit of superior or inferior prostheses is provided, in which the prostheses have at least two dimensions that vary among members of the kit independently of each other. Each prosthesis may have a bone engaging surface having a surface that is polyaxially rotatable against a corresponding resection of a vertebra. Each prosthesis may also have an articulating surface shaped such that, after attachment to the spine, the replaced or partially replaced facet joints provide a larger medial-lateral range of motion when the spine is flexed than when the spine is extended. Crosslinks may be used to connect left and right prosthesis together in such a manner that they are stabilized in a position in which they are seated directly against the vertebra.

Abstract: A transconnector for use in interconnecting a pair of longitudinal spinal rods in a spinal fixation procedure. The transconnector includes a bridge member and first and second spinal rod engaging members. The bridge member may include first and second members, wherein the first and second members are moveably associated with one another so that the distance between the first and second spinal rod engaging members can be adjusted. The first and second spinal rod engaging members include a rod receiving channel for receiving one of the spinal rods therein. The spinal rod engaging members may be articulating in, for example, the yaw and roll positions or non-articulating with respect to the bridge members. The spinal rod engaging members preferably include a spring, for example, a spring washer, to provide an opposing force so that the spinal rod engaging members can provisionally snap onto the spinal rods.

Abstract: A polyaxial transverse connector for stabilizing a portion of the spine. Connector bodies are coupled to rods attached to either side of the spine. Heads of transverse members are positioned in the connector bodies such that they exhibit polyaxial motion. The transverse members may have curves or offsets to accommodate other components or patient anatomy. A connector connects the transverse members and male threaded inserts are advanced into the connector bodies to inhibit motion of the polyaxial transverse connector.

Abstract: A spinal cross connector is configured for connection between spinal rods and provides allowance or space for spinal extensor muscles once the spinal process has been removed. The cross connector has curved first and second connection members that are adjustable in length and rotation relative to one another. A first clamping member is provided on the first connection member and defines first and second arcuate jaws that are adapted to clamp onto a first spinal rod. A second clamping member is provided on the second connection member and defines first and second arcuate jaws that are adapted to clamp onto a second spinal rod. Both the first and second clamping members are rotatable and thus provide the rotational adjustment. The cross-connector also provides easy in situ sizing and adjustability.

Abstract: This invention relates to interconnection assemblies for use with spinal fixation systems to treat spinal defects. The interconnection assemblies can include various spinal rod connecting members and interconnecting elements to secure the spinal rod connecting members to each other in variable orientations and lengths. The interconnection assemblies can be adjusted to minimize interference with the spinal column, bony processes, and associated neural, muscular, and ligament components of the spine all the while exhibiting a low profile. The interconnecting elements and related components can be provided as a completely assembled unit that does not inadvertently become disassembled prior to or during implantation.

Abstract: A crosslink member for securing spinal rods is disclosed having connector ends that include a brace and a locking member, each having an arcuate face resting on and securing a spinal rod. The locking member is secured by a cam member that rotates relative to the locking member and that cams against the connector to displace the cam member. The crosslink includes a male connector with a cylindrical cross rod received by a cavity in a female connector. The cross rod is secured by a pivotable clamp device in the female connector, and the cross rod connector and female connector may pivot, rotate, and telescope relative to each other. To reduce size without sacrificing pivot sweep, the cross rod has beveled edges, and the cavity of the female connector has windows to provide pivot clearance.

Abstract: A sternal closure device for securing and retaining longitudinally divided halves of a sternum, the device having two sets of anterior and posterior longitudinally extended brace members with brace joining mechanisms extending through the sternal halves to join the anterior brace members to the posterior brace members, such that the sternal halves are compressed between the anterior and posterior brace members, and transverse bridging members that laterally connect the two sets of brace members, with securing mechanisms to retain the two sets of brace members in a contracted configuration with the sternal halves in abutting relation.

Abstract: A cross-connector assembly construct and a method of locking comprises a flexible clip contacting a longitudinal member; a housing component contacting the flexible clip, wherein the housing component comprises a conical ramp towards a bottom end of the housing component; a locking mechanism contacting the housing component and adapted to engage the flexible clip; and a connecting member contacting the housing component. The flexible clip comprises a flexible bias member adapted to retain the longitudinal member. The flexible clip comprises a non-symmetrical socket portion; and a clip portion attached to the non-symmetrical socket portion, the clip portion being adapted to retain the longitudinal member. The locking mechanism comprises a camming pin adapted to be housed within the housing component and engage the flexible clip causing the longitudinal member to become affixed to the flexible clip; and a blocker mechanism operatively connected to the housing component and the connecting member.

Abstract: An assembly and a method of locking a longitudinal member to a cross-connector assembly construct, wherein the assembly comprises a longitudinal member; a flexible clip contacting the longitudinal member; a housing component contacting the flexible clip; a locking mechanism contacting the housing component; and a connecting member contacting the housing component. The flexible clip comprises a flexible bias member adapted to retain the longitudinal member. The flexible clip comprises a socket portion; and a clip portion attached to the socket portion, the clip portion being adapted to retain the longitudinal member, wherein the flexible bias member extends from the clip portion to a bottom region of the socket portion.

Abstract: A transverse connector system for interconnecting two spinal rods includes a connector arranged to span the distance between the rods with a rod receiving recess and a pin receiving bore on each end. A one-piece pin member such as a set screw is disposed within each bore with an enlarged head protruding from the bottom of the connector so that when the set screw is retracted into the bore the head engages a side of the respective rod to clamp the rod within the recess. The connector may comprise two elongated members with a recess and pin receiving bore at one end of each member, a middle coupler which allows three degrees of freedom between the members to accommodate any anticipated spatial orientation between the members and a set screw for securing the other ends of the members together.

Abstract: The present invention relates to a percutaneous vertebral stabilization system. A first anchor is positionable within a body of a patient through a first percutaneous opening and a second anchor is positionable within a body of a patient through a second percutaneous opening. A stabilization member is positionable within the body of a patient through the first percutaneous opening to engage and connect the first and second anchors.

Abstract: A crosslink member for securing spinal rods is disclosed having connector ends that include a brace and a locking member, each having an arcuate face resting on and securing a spinal rod. The locking member is secured by a cam member that rotates relative to the locking member and that cams against the connector to displace the cam member. The crosslink includes a male connector with a cylindrical cross rod received by a cavity in a female connector. The cross rod is secured by a pivotable clamp device in the female connector, and the cross rod connector and female connector may pivot, rotate, and telescope relative to each other. To reduce size without sacrificing pivot sweep, the cross rod has beveled edges, and the cavity of the female connector has windows to provide pivot clearance.

Abstract: A method for providing vertebral disc annular fibrosis tensioning and lengthening that restores the loss of disc height and provides disc regeneration. In one non-limiting embodiment, the method includes inserting pedicle screws into the vertebral bodies of adjacent vertebra and positioning a spring in compression between and in contact with the pedicle screws so that the spring bias forces the pedicle screws apart to provide a distractive force that increases the height of the disc space and promotes the disc regeneration.