Abstract: Various multiaxial receivers for receiving at least one tether are disclosed. A multiaxial receiver may include a body having a U-shaped cavity configured to receive a longitudinal rod therein and a lower cavity configured to couple to a pedicle screw. The body may include a first aperture extending through a side surface of the body and defining a first passageway configured to permit a tether to pass therethrough in the horizontal direction. In some embodiments, the body may include a second aperture extending through the side surface of the body and defining a second passageway configured to permit the tether to pass therethrough in the horizontal direction. A set screw may be configured to be rotated from an open position in which the tether is permitted to pass through the first passageway and optionally through the second passageway to a closed position in which the tether is immobilized.

Abstract: A surgical injection device includes at least one tubular element defining a passageway. The passageway is configured for disposal of a selected volume of an agent and an evacuator disposed within the passageway. An actuator is engageable with the evacuator to entirely expel the selected volume of the agent from the passageway to a selected site. Spinal constructs, implants, systems and methods are disclosed.

Abstract: Methods, compositions and apparatus for coating bone material particles (e.g., fibers) are provided. The methods, compositions and apparatus comprise providing a container configured to receive a mineral coating liquid and a plurality of bone material particles (e.g., fibers) therein; adding the plurality of bone material particles (e.g., fibers) to the container; and contacting the plurality of bone material particles (e.g., fibers) with the mineral coating liquid in the container so as to coat each individual bone material particle (e.g., fiber) with the mineral coating liquid to form a plurality of coated bone material particles (e.g., fibers).

Abstract: Methods and systems for performing a preliminary registration is provided. Image data corresponding to an image depicting a tracking device and an anatomical element may be received. Robot positional data corresponding to a position of a robot may also be received. The robot and the anatomical element may be located in a common three-dimensional coordinate system based on the image data and the positional data to yield a preliminary registration. A suggested robot position may be determined based on the preliminary registration and a dimensional reach of a robot arm of the robot.

Abstract: A method facilitates the treatment of the spine of a patient by providing simultaneous access through at least a first opening and a second opening formed in the patient. For example, the method can include the acts of positioning the patient on a surgical table, providing the first opening into a posterior portion of the patient, providing the second opening into a lateral portion of the patient, inserting a first device through the first opening into the patient to contact the spine in a first direction that is transverse to the coronal plane of the patient, and inserting a second device through the second opening into the patient to contact the spine in a second direction that is transverse to the sagittal plane of the patient, where the first and second openings are accessible simultaneously, and, when the first and second devises are inserted into the patient, the position of the patient is stationary with respect to a portion of the table.

Abstract: A spinal implant includes a first member having an arcuate portion and a second member having an arcuate portion. The first member is connected with a first portion of vertebrae and the second member is connected with a second portion of vertebrae such that the second portion of vertebrae is disposed at a first angle relative to the first portion of vertebrae in a sagittal plane of the vertebrae. A ratchet is disposed with the members such that the first member is incrementally movable relative to the second member from the first angle to a selected angle of the second portion relative to the first portion in the sagittal plane. Systems, implants and methods are disclosed.

Abstract: A spinal implant includes a receiver having a first arm connected to a first extension and a second arm connected to a second extension. The arms are connected to the extensions via a break away surface. The arms include a proximal most end surface and the receiver includes an implant receiving surface. The proximal most end surface and the implant receiving surface defining an implant cavity. The break away surface is disposed within the implant cavity. In some embodiments, systems, spinal constructs and methods are disclosed.

Abstract: A spinal construct includes a body defining a transverse axis. The body includes a wall disposed between a first implant cavity and a second implant cavity. The body further defines a first opening communicating with the first implant cavity and a second opening communicating with the second implant cavity. The first opening defines a first axis and the second opening defines a second axis. At least one of the first axis and the second axis are disposed in a substantially non-perpendicular orientation relative to the transverse axis. Systems, surgical instruments, implants and methods are disclosed.

Abstract: A bone material dispensing system is provided. The bone material dispensing system comprises a loading device having a perimeter surrounding a base plane and a rim, the perimeter comprising a side wall extending along a longitudinal axis and a bar joining the side wall at a corner of the perimeter and extending in a direction transverse to the longitudinal axis, the base plane comprising a loading surface bordered by the side wall along the longitudinal axis, the loading surface having an end edge extending in a direction transverse to the longitudinal axis such that the side wall, the bar and the end edge form a rim adjacent to the loading surface and the bar. A method of loading bone material with the bone material dispensing system is also provided.

Abstract: Expandable spinal implants, systems and methods are disclosed. An expandable spinal implant may include a first endplate, a second endplate, and a moving mechanism that is operably coupled to the first and second endplates. The moving mechanism may include a wedge, a first sliding frame and a second sliding frame disposed on opposite sides of the wedge, a screw guide housing a rotatable first set screw and a rotatable second set screw opposite the first set screw. The first set screw may be operably coupled to the second sliding frame and the second set screw may be operably coupled to the wedge. The moving mechanism may operably adjust a spacing between the first and second endplates upon simultaneous rotation of the first and second set screws and operably adjust an angle of inclination between the first and second endplates upon translating the first set screw or second set screw.

Abstract: Embodiments of the present disclosure include in-situ formed or in-situ-manufactured expandable cages, expandable implants, and additive-manufacturing systems for printing spinal implants in-situ, and methods for printing the same. Some embodiments may include a robotic subsystem including scanning and imaging equipment configured to scan a patient's anatomy. Some embodiments may further include an armature having a dispensing component configured to dispense at least one printing material and a controller. The controller may be configured to control the scanning and imaging equipment to determine a target alignment of a patient's spine, and develop in-situ-forming instructions including an in-situ relocation plan. In some embodiments, the in-situ-forming instructions may be based on the target alignment of the patient's spine and an interbody access space which may only partially provide access to a disc space between adjacent vertebra of the patients spine.

Abstract: The present disclosure provides for spinal implants deployable between a contracted position and an expanded position. The spinal implant may include an anterior endplate, a superior endplate, and an inferior endplate operably coupled to a moving mechanism. The first endplate and a second endplate each include at least one bone screw relief. The moving mechanism may include first and second trolleys configured to act against corresponding ramps. The moving mechanism may further include a first set screw and a second set screw opposite the first set screw configured to operably adjust a spacing between the first and second endplates upon simultaneous rotation of the first and second set screws along a rotation axis, and may also operably adjust an angle of inclination between the first and second endplates upon rotating either one of the first set screw and second set screw along the rotation axis.

Abstract: Additive-manufacturing systems for forming non-woven fibrous implants are disclosed. Additive-manufacturing systems may include a robotic subsystem having scanning and imaging equipment configured to scan a patient's anatomy, and an armature including at least one dispensing nozzle configured to selectively dispense at least one material. The system may further include a controller apparatus configured to send a control signal to control the scanning and imaging equipment to determine a target alignment of a patient's spine, and develop an additive-manufactured printing plan including an additive-manufactured material selection plan based on the target alignment of the patient's spine. The controller may execute the additive-manufactured printing plan to: dispense the at least one material to form a non-woven fibrous component.

Abstract: A surgical instrument includes a first member defining an axis and a second member having at least one capture element. The at least one capture element being axially translatable relative to the first member such that the at least one capture element is outwardly radially movable relative to the axis and inwardly radially movable relative to the axis to capture a spinal plate. Systems, implants and methods are disclosed.

Abstract: A surgical instrument includes a first member and an actuator disposed with the first member. An assembly is provided that includes a second member engageable with a bone fastener receiver. A third member is rotatable relative to the second member and threadably engageable with the bone fastener receiver to capture the bone fastener receiver. Systems, spinal constructs, implants and methods are disclosed.

Abstract: A method of treating a spine includes implanting at least a portion of a spinal construct in a patient. The method further includes attaching one or more smart implants to the spinal construct. Each of the one or more smart implants includes (a) an attachment portion configured to attach the smart implant to the spinal construct, and (b) at least one sensor configured to measure an aspect of the spinal construct when the smart implant is attached to the spinal construct. The method further includes receiving, from the one or more smart implants, sensor information related to the aspect of the spinal construct and performing at least one intra-operational adjustment to the spinal construct based on the received sensor information.

Abstract: The present disclosure provides for a bone screw that may include a first portion extending from a first end to a second end in a longitudinal direction, for example. The first portion may have a head that defines the first end and a shank that defines the second end. Additionally, the first portion may include a metallic material and/or be formed of a metallic material, for example Titanium. The second portion may be mechanically coupled to the first portion and surround the shank, for example the second portion is screwed to the first portion or the second portion may be directly formed to the first portion by an overmold process. The second portion may have an exposed thread pattern and an exposed leading tip. Additionally, the second portion may include a thermoplastic material and/or be formed of a thermoplastic material such as PEEK.

Abstract: A method for treating a spine comprising the steps of: connecting at least one first fastener that defines an implant cavity with at least one vertebral level of a first portion of vertebrae; connecting at least one second fastener with at least one vertebral level of a second portion of the vertebrae; manipulating the vertebrae; manipulating a spinal rod to a selected configuration; connecting the spinal rod with the at least one first fastener such that the spinal rod is disposed at a selected position with the implant cavity; connecting a tether to a second fastener and the spinal rod; and reducing the spinal rod to a selected position relative to the second fastener with the tether. Systems, spinal constructs and surgical instruments are disclosed.

Abstract: An adjustable surgical frame for supporting a patient to facilitate different surgical approaches to the spine of the patient includes a first end, an opposite second end, and a length extending between the first and second ends thereof. The surgical frame has a longitudinal axis extending between the first and second ends along the length thereof, and includes a first support surface, a second support surface, and a third support surface. The surgical frame also includes an adjustable chest support, an adjustable hip and upper leg support, and an adjustable feet and lower leg support. The surgical frame is moveable between a first position, a second position, and a third position, and the chest support, the hip and upper leg support, and the feet and lower leg support are moveable to accommodate differently sized patients on the surgical frame.

Abstract: A spinal implant includes an attachment portion having an opening configured to capture a longitudinal member therein, wherein the attachment portion is the only attachment means of the spinal implant. The spinal implant further includes a housing integrally connected to the attachment portion and defining a sealed cavity for supporting a microelectronics assembly and a power source therein. The spinal implant further includes at least one antenna in electrical communication with the microelectronics assembly and at least one sensor in electrical communication with the microelectronics assembly, wherein the microelectronics assembly is configured to transmit information received from the at least one sensor to an external device using the at least one antenna.