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.
A system for assessing spinal implants includes at least one processor, and a memory storing instructions for execution by the at least one processor that, when executed, cause the at least one processor to receive first image data of a spinal column of a patient, determine, based on the first image data, a property of first bony anatomy in at least a first portion of the spinal column, determine, based on the property of the first bony anatomy, an initial screw trajectory for inserting a screw into the spinal column, virtually insert the screw along the initial screw trajectory using the first image data to generate modified first image data, perform an initial loading simulation for the virtually inserted screw using the modified first image data, and determine, based on the initial loading simulation, a suitability of the initial screw trajectory for implanting the screw into the spinal column.
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.
An orthopedic trialing instrument may include a shaft extending from a first end to a second end, a handle coupled to the shaft, and a first interbody trial disposed on the first end. In various embodiments, the first interbody trial may include a first bone screw indicator configured to visually represent a corresponding bone screw trajectory. In some embodiments, a double-sided orthopedic trialing instrument may include a first interbody trial on a first end and a second interbody trial on a second end. In various embodiments, each of the first interbody trial and second interbody trial may have at least one bone screw protrusion configured to visually represent a corresponding bone screw trajectory. In some embodiments, a plurality of orthopedic trialing instruments having differently sized interbody trials may be provided as a kit.
A bone screw comprises a shaft defining a longitudinal axis and a minor diameter. The shaft including a core having an angled surface relative to the axis. The angled surface extending from the minor diameter adjacent a proximal portion of the shaft to a distal portion of the shaft, and a wall disposed about the angled surface. The wall including at least one thread having an external thread form. In some embodiments, systems, spinal constructs, surgical instruments and methods are disclosed.
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.
A system for assessing spinal implants includes at least one processor, and a memory storing instructions for execution by the at least one processor that, when executed, cause the at least one processor to receive first image data of a spinal column of a patient, determine, based on the first image data, a property of first bony anatomy in at least a first portion of the spinal column, determine, based on the property of the first bony anatomy, an initial screw trajectory for inserting a screw into the spinal column, virtually insert the screw along the initial screw trajectory using the first image data to generate modified first image data, perform an initial loading simulation for the virtually inserted screw using the modified first image data, and determine, based on the initial loading simulation, a suitability of the initial screw trajectory for implanting the screw into the spinal column.
A method for growing a channeled spinal implant in situ, using a surgical additive-manufacturing system having a dispensing component, and implants formed thereby. The method can include positioning the dispensing component at least partially within an interbody space, between a first patient vertebra and a second patient vertebra, and maneuvering, in an applying step, the dispensing component within the interbody space and depositing, by the dispensing component, printing material on or adjacent the first vertebra. The applying step includes maneuvering the dispensing component and applying the printing material selectively to form an outer surface of the implant having a channel opening and to form an interior of the implant having at least one elongate channel extending to the opening.
B33Y 30/00 - ADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING - Details thereof or accessories therefor
B33Y 80/00 - Products made by additive manufacturing
9.
HEAD SUPPORT AND METHOD FOR USE OF THE HEAD SUPPORT FOR POSITIONING A PATIENT RELATIVE TO A SURGICAL FRAME
A lift, a head support, and methods for use thereof for use with a surgical frame are provided. The lift and the head support can be used with the surgical frame that is capable of reconfiguration before, during, or after surgery. The surgical frame can include a main beam that can be rotated, raised/lowered, and tilted upwardly/downwardly to afford positioning and repositioning of a patient supported thereon, and the lift and the head support can be used in lifting the patient from a table/gurney and positioning the patient with respect to the main beam.
A surgical draping system includes an under-draping, an over-draping, and a connecting draping connected by the under-draping and the over-draping. The surgical draping system is used to establish and maintain a surgical corridor to a surgical site or sites on a patient supported by a surgical table. The surgical draping system can accommodate rotation of the patient on the surgical table, such that the sterile surgical corridor is maintained even during such rotation. The sterile surgical corridor extends through an aperture formed in the over-draping, through an enclosed passageway formed through the connecting draping, and through an aperture formed in the under-draping.
A surgical positioning frame for supporting a patient includes a main beam having an axis of rotation relative to support structures. The main beam rotates the patient between a prone position and a lateral position. The main beam including a conforming main beam portion extending between the first and second support arms. The conforming main beam is preferably configured to allow a surgeon access to one lateral side of the patient and a surgical assistant access to the other lateral side of the patient with limited interference thereby.
A spinal implant comprises a collar, and a collet including an outer surface and an inner surface. The collet is connectable with a shaft. A crown includes a surface configured for disposal of a spinal rod. The collet is disposed with the collar such that the inner surface frictionally engages the spinal rod to capture the spinal rod with the crown. In some embodiments, implants, systems, instruments and methods are disclosed.
A system for forming an operative corridor with a dilator, a first blade, and a second blade is disclosed. The dilator may include a hollow body having an interior surface and an exterior neuromonitoring surface and the interior surface may define an interior passageway and the exterior surface may defined a first working surface and a first attachment surface. The first working surface may be configured to contact patient skin and the attachment surface may be configured to directly couple to the first blade and the second blade. The operative corridor of the system may be defined by the first working surface of the dilator, the second working surface of the first blade, and the third working surface of the second blade. Additionally, the system may be configured for use with a tissue retractor and the dilator, first blade, and second blade may be simultaneously insert within patient tissue.
A pellet delivery system is provided that comprises a needle having an inner surface defining a passageway. The needle has a first portion that extends along a longitudinal axis and a curved second portion comprising an opening that is in communication with the passageway. The second portion extends transverse to the longitudinal axis. A pellet is positioned in the passageway. A plunger is slidably positioned in the passageway. The plunger comprises a shaft having a rounded tip configured to push the pellet through the first and second portions and out of the opening without the pellet becoming stuck within the passageway or the opening. Implants, systems, constructs, instruments and methods are disclosed.
A surgical platform system facilitating manipulation of a patient support thereby is provided. The surgical platform system can include a support supporting a linkage portion, a first platform portion, and a second platform portion relative to the ground. The linkage portion can include a base pivotally attached to the support, a first connector pivotally supported by the base, and a first support portion and a second support portion pivotally supported by the first connector. The first platform portion can be supported by the first support portion and the second support portion, and the second platform can be supported by the base. Pivotal movement of the first platform portion relative to the base via pivotal movement of the connector, and pivotal movement of the second platform portion relative to the support via pivotal movement of the base can serve to separately articulate the first platform portion and the second platform portion relative to one another.
A surgical platform system facilitating manipulation of a patient support thereby is provided. The surgical platform system can include a support supporting a linkage portion, a first platform portion, and a second platform portion relative to the ground. The linkage portion can include a base pivotally attached to the support, a first connector pivotally supported by the base, and a first support portion and a second support portion pivotally supported by the first connector. The first platform portion can be supported by the first support portion and the second support portion, and the second platform can be supported by the base. Pivotal movement of the first platform portion relative to the base via pivotal movement of the connector, and pivotal movement of the second platform portion relative to the support via pivotal movement of the base can serve to separately articulate the first platform portion and the second platform portion relative to one another.
A system for forming an operative corridor with a dilator, a first blade, and a second blade is disclosed. The dilator may include a hollow body having an interior surface and an exterior neuromonitoring surface and the interior surface may define an interior passageway and the exterior surface may defined a first working surface and a first attachment surface. The first working surface may be configured to contact patient skin and the attachment surface may be configured to directly couple to the first blade and the second blade. The operative corridor of the system may be defined by the first working surface of the dilator, the second working surface of the first blade, and the third working surface of the second blade. Additionally, the system may be configured for use with a tissue retractor and the dilator, first blade, and second blade may be simultaneously insert within patient tissue.
A spinal construct includes a first member. The first member includes a proximal portion defining a first cavity and a distal portion defining a second cavity disposed at an angle relative to the first cavity. The distal portion is configured for connecting with a second member. The second member is configured for fixation with vertebral tissue. A crown defines a first opening aligned with the first cavity and a second opening aligned with the second cavity. Implants, systems, instruments and methods are disclosed.
A device is provided for supplying electrical current to an intervertebral disc. The device comprises a cannula having a proximal end and a distal end and a longitudinal axis therebetween. The distal end comprises a beveled tip for contacting a region of the intervertebral disc, and an electrode disposed within or on a surface of the cannula adjacent to the distal end. The electrode is configured to discharge electrical current to the region of the intervertebral disc. Methods of diagnosing and/or treating discogenic back pain are also provided.
A61B 18/20 - Surgical instruments, devices or methods for transferring non-mechanical forms of energy to or from the body by applying electromagnetic radiation, e.g. microwaves using laser
A61N 1/05 - Electrodes for implantation or insertion into the body, e.g. heart electrode
The present disclosure provides for spinal implants configured for lateral insertion techniques deployable between a contracted position and an expanded position. The spinal implant may include a first endplate and a second endplate, each having a plurality of guide walls and inclined ramps. The spinal implant may further include a moving mechanism having first and second trolleys configured to act against the first and second plurality of ramps. The moving mechanism may further include a first set screw and a second set screw opposite the first set screw. The moving mechanism may be 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 the first set screw or second set screw along the rotation axis.
A spinal implant comprises a collar, and a collet including an outer surface and an inner surface. The collet is connectable with a shaft. A crown includes a surface configured for disposal of a spinal rod. The collet is disposed with the collar such that the inner surface frictionally engages the spinal rod to capture the spinal rod with the crown. In some embodiments, implants, systems, instruments and methods are disclosed.
A lift, a head support, and methods for use thereof for use with a surgical frame are provided. The lift and the head support can be used with the surgical frame that is capable of reconfiguration before, during, or after surgery. The surgical frame can include a main beam that can be rotated, raised/lowered, and tilted upwardly/downwardly to afford positioning and repositioning of a patient supported thereon, and the lift and the head support can be used in lifting the patient from a table/gurney and positioning the patient with respect to the main beam.
A surgical guide is provided comprising a body defining a first cavity that is configured for disposal of a surgical instrument and an opening. A connector is disposable with the opening and is engageable with a surgical robot. At least one insert is disposable in the first cavity. The at least one insert defines a second cavity configured for disposal of an alternate surgical instrument. Systems, methods, spinal constructs, implants and surgical instruments are disclosed.
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.
Interbody implants may be formed by a product by process in which a first metallic frame component having an interconnected superior endplate and an interconnected inferior endplate are formed. In some embodiments, the endplates are interconnected by flexible struts and in others they are interconnected by translating struts. In various embodiments, a polymeric body may be infilled between the superior endplate and inferior endplate by a molding process, e.g., an injection molding process or an overmolding process. In various embodiments, the metallic frame may have a first compressive stiffness, the polymeric body may have a second compressive stiffness, and the first compressive stiffness of the metallic frame m ay be about 20% to about 80% of the second stiffness of the body. In various embodiments, a sum of the first compressive stiffness of the metallic frame and the second stiffness of the body is about 33,500 M/mm to about 11,500 N/mm.
Interbody implants may be formed by a product by process in which a first metallic frame component having an interconnected superior endplate and an interconnected inferior endplate are formed. In some embodiments, the endplates are interconnected by flexible struts and in others they are interconnected by translating struts. In various embodiments, a polymeric body may be infilled between the superior endplate and inferior endplate by a molding process, e.g., an injection molding process or an overmolding process. In various embodiments, the metallic frame may have a first compressive stiffness, the polymeric body may have a second compressive stiffness, and the first compressive stiffness of the metallic frame may be about 20% to about 80% of the second stiffness of the body. In various embodiments, a sum of the first compressive stiffness of the metallic frame and the second stiffness of the body is about 33,500 N/mm to about 11,500 N/mm.
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 multiaxial receiver may include a first passageway configured to permit a tether to pass therethrough in the vertical direction. In some embodiments, the multiaxial receiver may also include a second passageway configured to permit a tether to pass therethrough in the horizontal direction. An immobilization assembly including a set screw and a wedge may immobilize the tether. The immobilization assembly may be configured to be rotated from an open position in which the tether is permitted to pass through the first passageway to a closed position in which the tether is immobilized within the first passageway or second passageway by pining the tether against a bearing surface of the first passageway.
Various bone cement guides are disclosed that may connect directly to a fenestrated bone screw or connect to a spinal construct that is coupled to a fenestrated bone screw. In various embodiments, cement guides may include a three-part assembly including a hollow outer sleeve and a hollow inner sleeve with a removable inner rod. In various embodiments, the hollow inner sleeve may be movable between a retracted position and an extended position and in the extended position a distal end of the inner sleeve may splay outward and capture the head portion of a fenestrated bone screw. In other embodiments, a distal end of the outer sleeve may surround and capture tabs of an extended tulip head connector while the inner sleeve couples to an inside surface of the extended tulip head connector.
Various bone cement guides are disclosed that may connect directly to a fenestrated bone screw or connect to a spinal construct that is coupled to a fenestrated bone screw. In various embodiments, cement guides may include a three-part assembly including a hollow outer sleeve (30) and a hollow inner sleeve (20) with a removable inner rod (10). In various embodiments, the hollow inner sleeve may be movable between a retracted position and an extended position and in the extended position a distal end of the inner sleeve may splay outward and capture the head portion of a fenestrated bone screw. In other embodiments, a distal end of the outer sleeve may surround and capture tabs of an extended tulip head connector while the inner sleeve couples to an inside surface of the extended tulip head connector.
A61B 90/00 - Instruments, implements or accessories specially adapted for surgery or diagnosis and not covered by any of the groups , e.g. for luxation treatment or for protecting wound edges
30.
EXPANDABLE SPINAL IMPLANT SYSTEM WITH A BIASED TIP AND METHOD OF USING SAME
An expandable spinal implant includes a distal projection extending from only one side of the implant, ending in an anterior tip, the anterior portion and anterior tip defining an elongated distal end hook, which is wider than the proximal end. The distal end hook rotates around the spinal cord, aligning the implant with a desired pathway, then inserts into place in the disc space between the vertebrae. The elongated widened distal end hook provides a TLIF approach, distributes loads, provides anterior rim engagement, and creates lordosis.
A spinal implant system includes a spinal implant template configured to provide three dimensional coordinates of a selected implant configuration. An implant bending device includes work surfaces engageable with a spinal implant to manipulate the spinal implant to the selected implant configuration and an implant contact sensor. Surgical instruments, spinal constructs, implants and methods are disclosed.
A surgical system (100) for adjusting a segment of a spine includes a rack arm (29) extending in a longitudinal direction from a first end (29A) to a second end (29B), and a sliding body portion (30) including a ratcheting mechanism (31) selectively engageable with a spline portion (29S) of the rack arm. The system includes a first actuator (32) for translating the sliding body along the rack arm in the longitudinal direction. The system includes a first and second connection tower (10) extending along a first and second axis, respectively, that are each transverse to the longitudinal direction. The system further includes a second actuator (40) including a threaded screw for adjusting the first connection tower along a first axis. In some embodiments, the second actuator is configured to raise and lower the first connection tower in a sagittal plane.
A spinal implant includes a post with a receiver having a first mating surface and a stop. A connector defines an implant cavity. The connector includes a base having a second mating surface being positionable with the first mating surface to attach the connector with the receiver. The base defines a transverse passageway. A securing element is disposable in the passageway and engageable with the stop. In some embodiments, systems, surgical instruments, implants and methods are disclosed.
A spinal implant includes a post with a receiver having a first mating surface and a stop. A connector defines an implant cavity. The connector includes a base having a second mating surface being positionable with the first mating surface to attach the connector with the receiver. The base defines a transverse passageway. A securing element is disposable in the passageway and engageable with the stop, in some embodiments, systems, surgical instruments, implants and methods are disclosed.
An interface for moveably interconnecting a surgical table with a stationary gantry supporting a surgical robotic system is provided. The interface includes a collar portion, an actuator portion, and a locking portion. The collar portion is attached relative to a longitudinal cross-member of the surgical table via receipt of a portion of the longitudinal cross-member through the collar portion. The actuator portion is one of attached to the collar portion and attached to and/or supported by the gantry, and includes gearing operatively engaged to gearing attached to the longitudinal cross member. The locking portion is attached to and/or supported relative to the gantry, and includes a shoulder portion configured to contact an exterior surface of the collar portion, and at least one engagement portion moveable between a disengaged position and an engaged position. After the exterior surface is contacted to the shoulder portion, the locking portion can be moved from the disengaged position to the engaged position to maintain the position of the collar portion relative to the stationary gantry. And, after the collar portion is maintained in position relative to the stationary gantry, actuation of the actuator portion drives interaction of the gearing that moves portions of cross member into and out of the collar portion in a first linear direction and a second linear direction.
A surgical instrument comprises a member being engageable to a spinal implant configured for connection to a bone fastener shaft. An actuator is connected to the member. A latch is connected to the actuator and the connection is configured to change between at least one non-locked orientation such that the actuator is movable relative to the member and a locked orientation such that the actuator is fixed relative to the member. Systems, spinal constructs, implants and methods are disclosed.
An interface for moveably interconnecting a surgical table with a stationary gantry supporting a surgical robotic system is provided. The interface includes a collar portion, an actuator portion, and a locking portion. The collar portion is attached relative to a longitudinal cross-member of the surgical table via receipt of a portion of the longitudinal cross-member through the collar portion. The actuator portion is one of attached to the collar portion and attached to and/or supported by the gantry, and includes gearing operatively engaged to gearing attached to the longitudinal cross member. The locking portion is attached to and/or supported relative to the gantry, and includes a shoulder portion configured to contact an exterior surface of the collar portion, and at least one engagement portion moveable between a disengaged position and an engaged position. After the exterior surface is contacted to the shoulder portion, the locking portion can be moved from the disengaged position to the engaged position to maintain the position of the collar portion relative to the stationary gantry. And, after the collar portion is maintained in position relative to the stationary gantry, actuation of the actuator portion drives interaction of the gearing that moves portions of cross member into and out of the collar portion in a first linear direction and a second linear direction.
A spinal construct includes a bone fastener including a post and a shaft portion engageable with vertebral tissue. The post being movable in one or more axes relative to the shaft portion. A receiver defines a first cavity configured for disposal of the bone fastener and a second open cavity configured for disposal of a spinal rod. A band is disposable in the first cavity. The band being contractible and defining an inner surface that is directly engageable with the post. A nut includes an inner surface being slidably engageable over the post and an end surface engageable with the band such that the band contracts to engage the post. Systems, surgical instruments, implants and methods are disclosed.
A shoulder hold-down is provided for use in securing at least a shoulder of a patient in position relative to a surgical frame. The shoulder hold-down includes a locking mechanism that is adjustable to afford positioning of a shoulder engaging portion for contacting the patient.
Methods and apparatus for coating bone particles are provided. The methods and apparatus comprise providing a first mesh having a first set of openings to allow coating liquid and bone particles of a select size therethrough and bone particles larger than the select size to remain on the first mesh, the first mesh having a bottom portion; adding bone particles to the first mesh; and contacting the bone particles with coating liquid so as to allow bone particles larger than the first set of openings to remain on the first mesh so as to coat the bone particles.
An implantable mesh including demineralized bone fibers mechanically entangled into a biodegradable or permanent implantable mesh is provided. A method of preparing the implantable mesh is also provided. The method of preparing the implantable mesh includes mechanically entangling demineralized bone fibers with non-bone fibers to form the implantable mesh. The mechanical entanglement of the bone fibers into the implantable mesh is achieved by applying needle punching with barbed needles, spun lacing, entanglement with water jets or air jets or ultrasonic entanglement with ultrasonic waves. A method of implanting an implantable mesh at a target bone tissue site is also provided.
A method according to at least one embodiment of the present disclosure includes receiving a plurality of images, the plurality of images depicting a navigation probe contacting a plurality of divots on a medical instrument; receiving information about the medical instrument; and determining, based on the plurality of images and the information, a pose of the medical instrument.
G16H 20/40 - ICT specially adapted for therapies or health-improving plans, e.g. for handling prescriptions, for steering therapy or for monitoring patient compliance relating to mechanical, radiation or invasive therapies, e.g. surgery, laser therapy, dialysis or acupuncture
43.
SPINOUS PROCESS CLAMP REGISTRATION AND METHODS FOR USING THE SAME
A method according to at least one embodiment of the present disclosure includes receiving a plurality of images, the plurality of images depicting a navigation probe contacting a plurality of divots on a medical instrument; receiving information about the medical instrument; and determining, based on the plurality of images and the information, a pose of the medical instrument.
A61B 90/00 - Instruments, implements or accessories specially adapted for surgery or diagnosis and not covered by any of the groups , e.g. for luxation treatment or for protecting wound edges
A61B 34/10 - Computer-aided planning, simulation or modelling of surgical operations
44.
METHODS AND APPARATUS FOR COATING BONE PARTICLES USING A MESH
Methods and apparatus for coating bone particles are provided. The methods and apparatus comprise providing a first mesh having a first set of openings to allow coating liquid and bone particles of a select size therethrough and bone particles larger than the select size to remain on the first mesh, the first mesh having a bottom portion; adding bone particles to the first mesh; and contacting the bone particles with coating liquid so as to allow bone particles larger than the first set of openings to remain on the first mesh so as to coat the bone particles.
A geared cam expandable spinal implant. Rotational motion of a rotating portion is translated into linear motion of a yoke, which moves geared cams at the distal end of the implant to mate with, and walk along, teeth of corresponding racks. The walking of the gear cam teeth along the rack teeth creates a regular rate of implant expansion, reduces initial excessive expansion force applied to the implant, and provides fine adjustment of the expansion rate and force.
An expandable spinal implant is provided having first and second endplates hinged along one end and an expansion mechanism disposed therebetween configured to expand the first and second endplates from each other to provide a lordotic angle of up to 60 degrees. Various implants, systems and methods are disclosed.
A surgical platform system including a first platform portion, a second platform portion, and a support portion is provided. The support platform supports the first platform portion, and can be moveable relative to a surgical robotic system supporting the second platform portion. With the support portion and the first platform portion positioned relative to the surgical robotic system, the first platform portion supporting a first portion of the patient and the second platform portion supporting a second portion of the patient can be adjusted relative to one another to correspondingly adjust positions/orientations of the first portion and the second portion of the patient. To illustrate, using an end portion supporting the first platform portion, the first platform portion can be rotated about a vertical axis and moved side to side to adjust the position/orientation thereof relative to the second platform portion.
A surgical table including a first platform portion and a second platform portion that are independently moveable relative to one another is provided. A first portion of a patient can be supported by the first platform portion and a second portion of the patient can be supported by the second platform portion, and the first platform portion and the second platform portion can be adjusted relative to one another to correspondingly adjust positions/orientations of the first portion and the second portion of the patient. To illustrate, using a first end portion supporting the first platform portion, the first platform portion can be rotated about a vertical axis and moved side to side to adjust the position/orientation thereof relative to the second platform portion, and using a second end portion supporting the second platform portion, the second platform portion can be moved toward and away from first platform portion.
A spinal construct includes a first member. The first member includes a proximal portion defining a first cavity and a distal portion defining a second cavity disposed at an angle relative to the first cavity. The distal portion is configured for connecting with a second member. The second member is configured for fixation with vertebral tissue. A crown defines a first opening aligned with the first cavity and a second opening aligned with the second cavity. Implants, systems, instruments and methods are disclosed.
A spinal implant system includes a first bone fastener including a first head and a first shaft. The first head including a medial rod receiver offset from the first shaft. A second bone fastener is provided including a second head and a second shaft. The second head including a lateral rod receiver offset from the second shaft. The shafts are configured for fixation with vertebral tissue in alignment along a selected trajectory of the vertebral tissue. Surgical instruments, implants and methods are disclosed.
A surgical platform system including a first platform portion, a second platform portion, and a support portion is provided. The support platform supports the first platform portion, and can be moveable relative to a surgical robotic system supporting the second platform portion. With the support portion and the first platform portion positioned relative to the surgical robotic system, the first platform portion supporting a first portion of the patient and the second platform portion supporting a second portion of the patient can be adjusted relative to one another to correspondingly adjust positions/orientations of the first portion and the second portion of the patient. To illustrate, using an end portion supporting the first platform portion, the first platform portion can be rotated about a vertical axis and moved side to side to adjust the position/orientation thereof relative to the second platform portion.
A61G 13/04 - Adjustable operating tables; Controls therefor tiltable around transverse or longitudinal axis
A61G 13/06 - Adjustable operating tables; Controls therefor raising or lowering of the whole table surface
A61G 13/08 - Adjustable operating tables; Controls therefor the table being divided into different adjustable sections
A61G 7/008 - Beds specially adapted for nursing; Devices for lifting patients or disabled persons having adjustable mattress frame tiltable around longitudinal axis, e.g. for rolling
A surgical platform system including a first platform portion, a second platform portion, and a support portion is provided. The support platform supports the first platform portion, and can be moveable relative to a surgical robotic system supporting the second platform portion. With the support portion and the first platform portion positioned relative to the surgical robotic system, the first platform portion supporting a first portion of the patient and the second platform portion supporting a second portion of the patient can be adjusted relative to one another to correspondingly adjust positions/orientations of the first portion and the second portion of the patient.
A61G 13/04 - Adjustable operating tables; Controls therefor tiltable around transverse or longitudinal axis
A61G 13/06 - Adjustable operating tables; Controls therefor raising or lowering of the whole table surface
A61G 13/08 - Adjustable operating tables; Controls therefor the table being divided into different adjustable sections
A61G 7/008 - Beds specially adapted for nursing; Devices for lifting patients or disabled persons having adjustable mattress frame tiltable around longitudinal axis, e.g. for rolling
A surgical table including a first platform portion and a second platform portion that are independently moveable relative to one another is provided. A first portion of a patient can be supported by the first platform portion and a second portion of the patient can be supported by the second platform portion, and the first platform portion and the second platform portion can be adjusted relative to one another to correspondingly adjust positions/orientations of the first portion and the second portion of the patient. To illustrate, using a first end portion supporting the first platform portion, the first platform portion can be rotated about a vertical axis and moved side to side to adjust the position/orientation thereof relative to the second platform portion, and using a second end portion supporting the second platform portion, the second platform portion can be moved toward and away from first platform portion.
A61G 13/04 - Adjustable operating tables; Controls therefor tiltable around transverse or longitudinal axis
A61G 13/06 - Adjustable operating tables; Controls therefor raising or lowering of the whole table surface
A61G 13/08 - Adjustable operating tables; Controls therefor the table being divided into different adjustable sections
A61G 7/008 - Beds specially adapted for nursing; Devices for lifting patients or disabled persons having adjustable mattress frame tiltable around longitudinal axis, e.g. for rolling
A surgical platform system including a first platform portion, a second platform portion, and a support portion is provided. The support platform supports the first platform portion, and can be moveable relative to a surgical robotic system supporting the second platform portion. With the support portion and the first platform portion positioned relative to the surgical robotic system, the first platform portion supporting a first portion of the patient and the second platform portion supporting a second portion of the patient can be adjusted relative to one another to correspondingly adjust positions/orientations of the first portion and the second portion of the patient.
A patient support apparatus for supporting a patient in a prone position during a surgical procedure is provided, including an open fixed frame suspended above a floor and a pair of spaced opposed radially sliding joints cooperating with the frame, each joint including a virtual pivot point and an arc of motion spaced from the virtual pivot point, the joints being movable along the arc providing a pivot ship mechanism for a pair of pelvic pads attached to the joints. A base for supporting and suspending a patient support structure above the floor, for supporting a patient during a surgical procedure, the base including a pair of spaced opposed vertical translation subassemblies reversibly attachable to a patient support structure, a cross-bar, and a rotation subassembly having two degrees of rotational freedom; wherein a location of each vertical translation subassembly is substantially constant during operation of the patient support structure.
A61B 5/00 - Measuring for diagnostic purposes ; Identification of persons
A61G 7/00 - Beds specially adapted for nursing; Devices for lifting patients or disabled persons
A61G 7/005 - Beds specially adapted for nursing; Devices for lifting patients or disabled persons having adjustable mattress frame tiltable around transverse horizontal axis, e.g. for Trendelenburg position
A61G 7/008 - Beds specially adapted for nursing; Devices for lifting patients or disabled persons having adjustable mattress frame tiltable around longitudinal axis, e.g. for rolling
A61G 7/012 - Beds specially adapted for nursing; Devices for lifting patients or disabled persons having adjustable mattress frame raising or lowering of the whole mattress frame
A61G 7/015 - Beds specially adapted for nursing; Devices for lifting patients or disabled persons having adjustable mattress frame divided into different adjustable sections, e.g. for Gatch position
G06F 3/04842 - Selection of displayed objects or displayed text elements
A61G 13/06 - Adjustable operating tables; Controls therefor raising or lowering of the whole table surface
G16H 20/40 - ICT specially adapted for therapies or health-improving plans, e.g. for handling prescriptions, for steering therapy or for monitoring patient compliance relating to mechanical, radiation or invasive therapies, e.g. surgery, laser therapy, dialysis or acupuncture
G16H 40/63 - ICT specially adapted for the management or administration of healthcare resources or facilities; ICT specially adapted for the management or operation of medical equipment or devices for the operation of medical equipment or devices for local operation
56.
CONTINUOUS FIBER BONE SCREW AND METHOD OF MANUFACTURE
The present disclosure provides for a bone screw formed of continuous fibers, for example. The bone screw may include a first portion having a cylindrical shape and extending in a longitudinal direction from a first end to a second end, for example. In various embodiments, the first portion may include a thermoplastic material and/or be substantially formed of a thermoplastic material. In various embodiments, the bone screw may include a second portion coupled to the first portion and surrounding the first portion, at least partly, for example. In various embodiments, the second portion may include a plurality of layers, each layer comprising a continuous fiber material, for example. In various embodiments, the continuous fibers may be oriented longitudinally, diagonally, helically, radially, etc. In various embodiments, the second portion may define an exposed thread pattern and a leading tip.
A surgical instrument comprises a first member extending between a proximal end and a distal end configured for fixation with tissue. A second member defines a longitudinal passageway and is connected with a navigation component such that the distal end is disposable with the passageway at a selected distance from the navigation component. The navigation component is positioned relative to a sensor to communicate a signal representative of an orientation of the first member. A third member extends between a proximal end and a distal end. The third member is mountable with the first member along the orientation such that the distal end of the third member is engageable with the tissue. Systems, spinal implants, constructs and methods are disclosed.
A bone fastener includes a head including a first receiver defining an implant cavity and a distal portion defining a plurality of adjacent grooves. The head further includes a second receiver defining an implant cavity. A first resilient member is configured for disposal within the plurality of adjacent grooves and a second resilient member is configured for disposal within the plurality of adjacent grooves. A shaft is aligned with the first receiver and is configured to engage tissue. Systems, surgical instruments, spinal constructs, implants and methods are disclosed.
A coordinate locating device comprising a support structure removably connectable to a wearable sensor device being worn by an individual. The support structure comprising a planar surface. The device includes a plurality of different fiducial marker components connected to the planar surface. The plurality of different fiducial marker components includes a set of fiducial markers connected to the planar surface in a non-collinear configuration relative to each other to define a three-dimensional (3D) space of pixels in an image. The plurality of different fiducial marker components includes a distance calibration fiducial marker connected to the planar surface and being configured to define a distance calibration length of pixels in the image, the distance calibration fiducial marker being perpendicular to the planar surface and defining a calibration length to locate a point of origin of motion sensing by the wearable sensor device. A system and method are also provided.
A61B 5/0205 - Simultaneously evaluating both cardiovascular conditions and different types of body conditions, e.g. heart and respiratory condition
A61B 5/11 - Measuring movement of the entire body or parts thereof, e.g. head or hand tremor or mobility of a limb
A61B 5/316 - Modalities, i.e. specific diagnostic methods
A61B 90/00 - Instruments, implements or accessories specially adapted for surgery or diagnosis and not covered by any of the groups , e.g. for luxation treatment or for protecting wound edges
61.
SURGICAL FRAME HAVING TRANSLATING LOWER BEAM AND MOVEABLE LINKAGE OR SURGICAL EQUIPMENT ATTACHED THERETO AND METHOD FOR USE THEREOF
A surgical frame and method for use thereof is provided. The surgical frame is capable of reconfiguration before, during, or after surgery using a moveable main beam supporting a patient thereon. The surgical frame includes a translating lower beam that is moveable between at least a first lateral position and a second lateral position, and a linkage and/or surgical equipment supportively and moveably attached to the translating lower beam or interconnected with the translating lower beam via the linkage. The linkage and/or the surgical equipment are moveable between a first position at or adjacent a first end of the translating lower beam and a second position at or adjacent a second end of the translating lower beam. The translating lower beam is used to join a first support portion and a second support portion of the surgical frame to one another, and movement of the translating lower beam affords access to a patient receiving area. A linear movement mechanism can be used to facilitate movement of the linkage and/or the surgical equipment along the translating lower beam to avoid interference with the main beam or the translating lower beam.
A method for surgically treating a spine comprising the steps of: pre-operatively imaging vertebral tissue; displaying a first image of a surgical treatment configuration for the vertebral tissue from a mixed reality display and/or a second image of a surgical strategy for implementing the surgical treatment configuration with the vertebral tissue from the mixed reality display; determining a surgical plan for implementing the surgical strategy; and intra-operatively displaying a third image of the surgical plan with the vertebral tissue from the mixed reality display. Systems, spinal constructs, implants and surgical instruments are disclosed.
A load sensing assembly for a medical implant is disclosed. The medical implant may include an upper surface, a side surface, a bottom surface, and a cavity housing various sensors and microelectronics. In other embodiments, the medical implant may include a port that is accessible through at least one of the bottom surface, side surface, and the upper surface. The port may be configured to receive an electronics assembly, package, or hermetically sealed enclosure. The electronics package may have a size and shape generally corresponding to the port. In various embodiments, electronic components and sensors may be powered by a local power source. In various embodiments, sensors may be chosen from: accelerometers, gyroscope, strain gauge, pressure sensor, pH sensor, impedance sensor, optical sensor, and/or a temperature sensor. In various embodiments, the medical implant may be chosen from: an interbody spinal implant, a pedicle screw, a connector, and/or a cross-link.
Load sensing spinal implants having at least one sensor and an antenna are disclosed. An example implant may include an interbody cage extending in a longitudinal direction from a proximal end to a distal end and in a widthwise direction from a first lateral end to a second lateral end; and an electronics portion including a housing defining a sealed cavity for supporting an electronics assembly and a battery therein. The implant may include at least one antenna in electrical communication with the electronics assembly; and at least one strain gauge configured to detect a localized force experienced by the interbody cage. The at least one antenna may be configured to transmit information received from the at least one strain gauge to an external device. The electronics assembly may be disposed on the side of the cage, a distal end of the cage, or inside a window of the cage.
A61B 17/00 - Surgical instruments, devices or methods, e.g. tourniquets
A61F 2/00 - Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
65.
SPINAL ROD CONNECTING COMPONENTS WITH ACTIVE SENSING CAPABILITIES
A digital pedicle screw assembly may be installed inside of the body of a patient and be configured to sense various attributes of the assembly and the patient. Embodiments may include a receiver having a U-shaped cavity for supporting a longitudinal rod and set screw therein. The receiver may include a lower cavity configured to couple to a pedicle screw and a side portion integrally connected to the receiver and including a housing defining a sealed cavity for supporting a microelectronics assembly and a battery therein. Embodiments may include at least one antenna attached to an outside of the housing and being in electrical communication with the microelectronics assembly, and at least one strain gauge configured to detect a localized force experienced by the receiver and being in electrical communication with the microelectronics assembly.
A digital pedicle screw assembly may be installed inside of the body of a patient and be configured to sense various attributes of the assembly and the patient. Embodiments may include a receiver having a U-shaped cavity for supporting a longitudinal rod and set screw therein. The receiver may include a lower cavity configured to couple to a pedicle screw and a side portion integrally connected to the receiver and including a housing defining a sealed cavity for supporting a microelectronics assembly and a battery therein. Embodiments may include at least one antenna attached to an outside of the housing and being in electrical communication with the microelectronics assembly, and at least one strain gauge configured to detect a localized force experienced by the receiver and being in electrical communication with the microelectronics assembly.
Load sensing spinal implants having at least one sensor and an antenna are disclosed. An example implant may include an interbody cage extending in a longitudinal direction from a proximal end to a distal end and in a widthwise direction from a first lateral end to a second lateral end; and an electronics portion including a housing defining a sealed cavity for supporting an electronics assembly and a battery therein. The implant may include at least one antenna in electrical communication with the electronics assembly; and at least one strain gauge configured to detect a localized force experienced by the interbody cage. The at least one antenna may be configured to transmit information received from the at least one strain gauge to an external device. The electronics assembly may be disposed on the side of the cage, a distal end of the cage, or inside a window of the cage.
A surgical frame and method for use thereof is provided. The surgical frame is capable of reconfiguration before, during, or after surgery. The surgical frame includes a main beam that can be rotated, raised/lowered, and tilted upwardly/downwardly to afford positioning and repositioning of a patient supported thereon. The surgical frame also includes a reconfigurable upper leg support for supporting portions of the upper legs, the hips, and the lower back of the patient to facilitate positioning and repositioning there during surgery. The upper leg support via reconfiguration thereof can accommodate patients of different sizes, can provide flexure of the patient's lumbar spine to facilitate surgical access thereto, and can prevent unwanted torsion of a patient's spine during such reconfiguration.
A spinal implant includes an electronics portion with a housing defining a sealed cavity for supporting an electronics assembly and a battery therein. The spinal implant further includes at least one antenna in electrical communication with the electronics assembly and at least one sensor in electrical communication with the electronics assembly, wherein the at least one antenna is located external to the housing and is configured to transmit information received from the at least one sensor to an external device.
A bone fastener includes a screw shaft having a proximal portion and a distal portion. The proximal portion is formed by a first manufacturing method and defines a distal face. The distal portion is formed onto the distal face by a second manufacturing method. In some embodiments, systems, spinal constructs, surgical instruments and methods are disclosed.
B33Y 50/00 - Data acquisition or data processing for additive manufacturing
B33Y 80/00 - Products made by additive manufacturing
B29C 64/153 - Processes of additive manufacturing using only solid materials using layers of powder being selectively joined, e.g. by selective laser sintering or melting
B29C 64/386 - Data acquisition or data processing for additive manufacturing
B33Y 30/00 - ADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING - Details thereof or accessories therefor
B33Y 50/02 - Data acquisition or data processing for additive manufacturing for controlling or regulating additive manufacturing processes
A modular retractor may include a first body portion that houses a distraction mechanism for opening and closing a first arm and a second arm. A first pivoting member may be coupled to a distal end of the first arm and a second pivoting member may be coupled to a distal end of the second arm, for example. A first pin receiving cannula may be coupled to the first pivoting member and a second pin receiving cannula may be coupled to the second pivoting member. The first and second pin receiving cannulas may receive a threaded pin therein and be independently inclinable. Various embodiments may include at least one quick connect coupler. During use, a first pin and a second pin may be secured to a first and second vertebrae for distracting and/or adjusting an angle of inclination of the first and second vertebrae.
A surgical instrument comprises a member defining a longitudinal axis and being connectable with a spinal implant. A handle is connected with the member. An image guide is connected with the member for orientation relative to a sensor to communicate a signal representative of a position of the spinal implant. The image guide is rotatable about the axis relative to the member and is disposable in at least one fixed position with the member. Systems, implants, spinal constructs and methods are disclosed.
Systems, instruments, and methods for surgical navigation with verification feedback are provided. The systems, instruments, and methods may be used to verify a trajectory of a surgical tool during a procedure. The systems, instruments, and methods may receive one or more captured images of an anatomical portion of a patient; execute a surgical plan to insert the surgical tool into the anatomical portion; receive sensor data collected from one or more sensors being inserted into the anatomical portion; determine whether the sensor data corresponds to the surgical plan; and send, in response to determining that the sensor data does not correspond to the surgical plan, an alert indicating that the surgical tool is not being inserted according to the surgical plan. The one or more sensors may be attached to the surgical tool.
A61B 90/00 - Instruments, implements or accessories specially adapted for surgery or diagnosis and not covered by any of the groups , e.g. for luxation treatment or for protecting wound edges
A61B 17/16 - Osteoclasts; Drills or chisels for bones; Trepans
An interbody system including an implant and a tool for inserting and expanding the medical implant and locking the implant in place is disclosed. The medical implant may include an expandable body defined by a superior endplate and an inferior endplate that are hingedly coupled and may be expanded and lordosed. The superior and inferior endplate may include gripping protrusions that mate and/or directly engage with recessed jaws of disclosed surgical tool. The surgical tool may include a vertically movable jaw to expand and contract the implant when engaged with the gripping protrusions of the implant. The surgical tool may also include a drive portion that engages the drive feature of the lock screw with the drive end of the surgical tool lock the implant while in an expanded position.
Computer implemented methods of producing a bone graft are provided. These methods include obtaining a 3-D image of an intended bone graft site; generating a 3-D digital model of the bone graft based on the 3-D image of the intended bone graft site, the 3-D digital model of the bone graft being configured to fit within a 3-D digital model of the intended bone graft site; storing the 3-D digital model on a database coupled to a processor, the processor having instructions for retrieving the stored 3-D digital model of the bone graft and for combining a carrier material with, in or on a bone material based on the stored 3-D digital model and for instructing a 3-D printer to produce the bone graft. A layered 3-D printed bone graft prepared by the computer implemented method is also provided.
A surgical system for adjusting a segment of a spine is disclosed. The system may include a rack arm extending in a longitudinal direction from a first end to a second end, and a sliding body portion including a ratcheting mechanism selectively engageable with a spline portion of the rack arm. The system may include a first actuator for translating the sliding body along the rack arm in the longitudinal direction. The system may include a first and second connection tower extending along a first and second axis, respectively, that are each transverse to the longitudinal direction. The system may further include a second actuator including a threaded screw for adjusting the first connection tower along a first axis. In some embodiments, the second actuator is configured to raise and lower the first connection tower in a sagittal plane.
A surgical instrument includes a first member defining an axis and including a cutting surface. A second member includes a cutting surface that is rotatable relative to the first member. A third member includes an outer surface. The cutting surface of the second member is rotatable relative to the outer surface to transfer the cut tissue along the axis. Systems and methods are disclosed.
Disclosed herein are systems and methods for graft delivery with accurate dispensing. For example, a device for delivering graft material to a target site includes an actuation mechanism and a tube. The tube defines a lumen and an open end and is configured to receive graft material through the open end. The tube includes a pressure relief opening and a dosage window. The pressure relief opening is disposed in a wall of the tube, defining a pressure chamber between the open end and the pressure relief opening. The device further includes a plunger positioned within the lumen of the tube and coupled to the actuation mechanism such that at least a portion of the plunger (or the actuation mechanism) is visible through the dosage window. The actuation mechanism is configured to advance the plunger toward the open end to deliver graft material through the open end.
Disclosed herein are systems and methods for graft delivery with accurate dispensing. For example, a device (100) for delivering graft material to a target site includes an actuation mechanism (18) and a tube (200). The tube defines a lumen (40) and an open end (50) and is configured to receive graft material through the open end. The tube includes a pressure relief opening (44) and a dosage window (46). The pressure relief opening is disposed in a wall of the tube, defining a pressure chamber (47) between the open end and the pressure relief opening. The device further includes a plunger (210) positioned within the lumen of the tube and coupled to the actuation mechanism such that at least a portion of the plunger (or the actuation mechanism) is visible through the dosage window. The actuation mechanism is configured to advance the plunger toward the open end to deliver graft material through the open end.
In some embodiments, a bone implant for percutaneous use is provided. The bone implant comprises a head, a body adjacent to the head and a tip opposite the head. At least the head, body or tip is configured to contact bone. An expandable member contacts at least one of the head, tip or body and is movable from an unexpanded configuration to an expanded configuration when deployed at a bone implant site. In some embodiments, a system for percutaneous bone harvesting is provided.
In some embodiments, a bone implant for percutaneous use is provided. The bone implant comprises a head, a body adjacent to the head and a tip opposite the head. At least the head, body or tip is configured to contact bone. An expandable member contacts at least one of the head, tip or body and is movable from an unexpanded configuration to an expanded configuration when deployed at a bone implant site. In some embodiments, a system for percutaneous bone harvesting is provided.
A surgical system includes a plurality of alternate engaging surfaces. A first member is connectable with an engaging surface such that the first member is interchangeable with the plurality of engaging surfaces. A second member is connectable with an engaging surface such that the second member is interchangeable with the plurality of engaging surfaces. The members are relatively movable to distract and/or compress vertebral tissue. Surgical instruments, constructs, implants and methods are disclosed.
A spinal implant system is provided for bridging an intervertebral space between vertebral bodies bordering the intervertebral space. The spinal implant system includes at least one adjustable end cap and a spinal implant. The end cap can be used with additional end caps and/or the spinal implant. Multiple end caps can be stacked on top of one another, and one end cap can be attached to a first end of the spinal implant, and another end cap can be attached to a second end of the spinal implant. Thus, one or more of the end caps can be attached to either end of the spinal implant.
A surgical frame and method for use thereof is provided. The surgical frame is capable of reconfiguration before, during, or after surgery. The surgical frame includes a main beam that can be rotated, raised/lowered, and tilted upwardly/downwardly to afford positioning and repositioning of a patient supported thereon. The main beam is capable of be reconfigured between a left configuration and a right configuration to support the patient in different positions thereon.
F02M 31/18 - Other apparatus for heating fuel to vaporise fuel
A61G 13/04 - Adjustable operating tables; Controls therefor tiltable around transverse or longitudinal axis
A61G 13/08 - Adjustable operating tables; Controls therefor the table being divided into different adjustable sections
F02M 31/08 - Apparatus for thermally treating combustion-air, fuel, or fuel-air mixture for heating combustion-air or fuel-air mixture by hot gases, e.g. by mixing cold and hot air the gases being exhaust gases
F02M 31/087 - Heat-exchange arrangements between the air intake and exhaust gas passages, e.g. by means of contact between the passages
A surgical instrument includes a first member defining an axis and having a scraping surface configured to scrape tissue. A second member includes a cutting surface that is rotatable relative to the first member. The second member has a maximum length defined by opposite end surfaces of the second member. The end surfaces are each disposed within the first member. A third member includes an outer surface defining at least a portion of a passageway configured for disposal of the scraped tissue. The third member is fixed with the first member. The cutting surface is rotatable relative to the third member to transfer the scraped tissue along the axis. Systems and methods are disclosed.
A method of delivering a therapeutic agent to a nucleus pulposus of an intervertebral disc is provided. The method comprises inserting a delivery tool containing the therapeutic agent through an anterior portion, a lateral portion, or an anterolateral portion of an annulus fibrosus and into the nucleus pulposus of the intervertebral disc; and delivering the therapeutic agent to the nucleus pulposus of the intervertebral disc. Devices and kits are also provided.
A61M 5/32 - Syringes - Details - Details of needles pertaining to their connection with syringe or hub; Accessories for bringing the needle into, or holding the needle on, the body; Devices for protection of needles
A61M 25/06 - Body-piercing guide needles or the like
An expandable implant may include a superior endplate and an inferior endplate. The superior endplate may have at least one track extending in a proximal-to-distal direction and an inferior endplate may have at least one track extending in the proximal-to-distal direction. An adjusting shim may be disposed within the at least one track to adjust a spacing and angle of inclination of the implant. Some embodiments may include a plurality of tracks for adjusting a spacing and an angle of inclination between the superior endplate and the inferior endplate. Some embodiments may be configured to adjust an orientation of the implant relative to a disc space in both the sagittal plane and the coronal plane. Various embodiments disclosed herein may be used in an Anterior lumbar interbody fusion (ALIF), Transforaminal lumbar interbody fusion (TLIF), or a lateral Lumbar Interbody Fusion (LLIF) procedure, for example.
A robotic surgical imaging system (100,200,300) includes a first imaging device (202) and a second imaging device (204,302). The first imaging device (202) may be used to capture a first image of a target environment, where the first image includes an object in the target environment (502,602,702). Subsequently, coordinates of interest may be selected in the first image that are associated with at least a portion of the object (504). Real-world coordinates may then be generated that correspond to the coordinates of interest and the portion of the object (506,606), and the second imaging device (204) may be placed at a location based on the real-world coordinates (508,608). After verifying the location of the second imaging device (204) corresponds to the coordinates of interest (e.g., with any needed adjustments to the location made), the second imaging device (204) may be used to capture a second image of the portion of the object (510,610,710).
A method comprises the steps of: fixing a distal end of a first member of a surgical instrument with tissue, the surgical instrument including a second member having a longitudinal passageway configured for disposal of the first member and being connected with a navigation component such that the distal end is disposable with the passageway at a selected distance from the navigation component, the navigation component being positioned relative to a sensor to communicate a signal representative of an orientation of the first member; removing the second member from the first member; and connecting a third member with the first member along the orientation such that a distal end of the third member is fixed with the tissue. Systems, spinal implants, constructs and instruments are disclosed.
A positioning frame for supporting a patient to facilitate different surgical approaches to the spine includes a main support beam, first and second support structures, a torso-lift support, and a pelvic-tilt support. The main support beam has a first end, a second end, and a length extending between the first and second ends. The main support beam defines an axis of rotation relative to at least a first support structure and a second support structure, and the axis of rotation substantially corresponds to a cranial-caudal axis of the patient when the patient is supported on the positioning frame. The first and second support structures support the main support beam, and space the main support beam from the ground. The torso-lift support is attached to the main support beam, and is configured to pivot a chest support plate between at least a first position and a second position to move the torso of the patient between an unlifted position and a lifted position. The pelvic-tilt support is attached to the main support beam, and is configured to support the thighs and the lower legs of the patient. Portions of the pelvic-tilt support are pivotal with respect to one another to facilitate adjustment of the hips of the patient.
A spinal implant comprises a first member, a second member and an actuator defining a transverse pivot axis. A first link is connected to the first member and the actuator adjacent the pivot axis. The first link includes an inner surface defining a cavity. A second link is connected to the second member and the actuator adjacent the pivot axis. The actuator is rotatable for translating the pivot axis such that the second link is movable within the cavity to move the members between a contracted configuration and an expanded configuration. Systems and methods of use are disclosed.
BUILD-PLATE USED IN FORMING DEVICES AND LOCATING FEATURES FORMED ON THE BUILD-PLATE TO FACILITATE USE OF ADDITIVE AND SUBTRACTIVE MANUFACTURING PROCESSES AND METHOD FOR USE THEREOF
A build-plate with integrally-formed spinal implant constructs and a method used in forming spinal implant constructs on the build-plate and machining the spinal implant constructs formed on the build-plate to manufacture spinal implants is provided. The spinal implant constructs can be formed via additive manufacturing processes by adding material to an upper surface of the build-plate, and then the spinal implant constructs can be subjected to subtractive manufacturing processes to form the spinal implants.
B33Y 30/00 - ADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING - Details thereof or accessories therefor
A61F 2/44 - Joints for the spine, e.g. vertebrae, spinal discs
A surgical instrument comprises a first member including a drive engageable with a first mating surface of a bone fastener. A second member is rotatable relative to the first member and includes an element engageable with a second mating surface of the bone fastener. An actuator is connected with the second member and includes visual indicia of engagement of the element with the second mating surface. Systems, spinal implants and methods are disclosed.
A61B 34/20 - Surgical navigation systems; Devices for tracking or guiding surgical instruments, e.g. for frameless stereotaxis
A61B 90/00 - Instruments, implements or accessories specially adapted for surgery or diagnosis and not covered by any of the groups , e.g. for luxation treatment or for protecting wound edges
A bone screw comprising a shaft having a wall, the wall including a minor diameter and at least one thread having an external thread form. The thread form including a first portion comprising a crest of the thread form and a second portion extends between a minor diameter of the thread form and the first portion. The first portion having a solid configuration relative to the second portion. In some embodiments, systems, spinal constructs, surgical instruments and methods are disclosed.
A bone implant holding and shaping tray is provided. The tray includes a first segment having a distal end and a first surface sized to hold and shape at least a portion of the bone implant with bone material. The tray includes a second segment having a second surface sized to hold and shape at least a portion of the bone implant with bone material, the second segment having a proximal end configured to be coupled to the distal end of the first segment so as to extend the first surface to hold and shape the bone implant. Methods of making and using the bone implant holding and shaping tray are also provided.
A61F 2/46 - Special tools for implanting artificial joints
A61F 2/00 - Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
97.
EXPANDABLE INTER-BODY DEVICE, EXPANDABLE PLATE SYSTEM, AND ASSOCIATED METHODS
The present disclosure provides for spinal implants and plates including, for example, expandable plates deployable between a contracted position and an expanded position. The expandable plate may include an expandable body including a first portion and a second portion. The first portion may include a receiving cavity facing the proximal end, and a first through aperture extending in the proximal-to-distal direction. The second portion may include a lower end having a size and shape that corresponds to the receiving cavity, and a second through aperture extending in the proximal-to-distal direction. The expandable plate may include a locking screw and a nut. In at least some embodiments, in a locked position, the locking screw extends through the first through aperture and second through aperture, and is secured to the nut. In various embodiments, in an expanded position the first portion and second portion are farther away from one another relative to a contracted position.
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.
Provided is a compression resistant implant configured to fit at or near a bone defect to promote bone growth. The compression resistant implant comprises a biodegradable polymer in an amount of about 0.1 wt % to about 20 wt % of the implant and a freeze-dried oxysterol in an amount of about 5 wt % to about 90 wt % of the implant. Methods of making and use are further provided.
The present disclosure provides for a bone screw formed of continuous fibers, for example. The bone screw may include a first portion having a cylindrical shape and extending in a longitudinal direction from a first end to a second end, for example. In various embodiments, the first portion may include a thermoplastic material and/or be substantially formed of a thermoplastic material. In various embodiments, the bone screw may include a second portion coupled to the first portion and surrounding the first portion, at least partly, for example. In various embodiments, the second portion may include a plurality of layers, each layer comprising a continuous fiber material, for example. In various embodiments, the continuous fibers may be oriented longitudinally, diagonally, helically, radially, etc. In various embodiments, the second portion may define an exposed thread pattern and a leading tip.
