Bids Are Invited For 1 Spine Implant -1 4.5 Mm Pedical Monoaxial Screws 30 Mm Length Screw Which Is Threaded And The Head Is Rigid Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be , Vadodara-Gujarat

Bids Are Invited For 1 Spine Implant -1 4.5 Mm Pedical Monoaxial Screws 30 Mm Length Screw Which Is Threaded And The Head Is Rigid Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendly Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 2 Spine Implant -2 4.5 Mm Pedical Monoaxial Screws 50 Mm Length Screw Which Is Threaded And The Head Is Rigid Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendl Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 3 Spine Implant -3 4.5 Mm Pedical Polyaxial Screws 50 Mm Length Screw Which Is Threaded And The Head Is Mobile It Swivels Helping To Defray Vertebral Stress Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendl Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 4 Spine Implant -4 4.5 Mm Pedical Polyaxial Screws 40 Mm Length Screw Which Is Threaded And The Head Is Mobile It Swivels Helping To Defray Vertebral Stress Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendl Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 5 Spine Implant -5 5.5 Mm Pedical Monoaxial Screws 25 Mm Length Screw Which Is Threaded And The Head Is Rigid Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendl Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 6 Spine Implant -6 5.5 Mm Pedical Monoaxial Screws 35 Mm Length Screw Which Is Threaded And The Head Is Rigid Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendl Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 7 Spine Implant -7 5.5 Mm Pedical Monoaxial Screws 40 Mm Length Screw Which Is Threaded And The Head Is Rigid Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible & Mri Friendl Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 8 Spine Implant -8 5.5 Mm Pedical Polyaxial Screws 35 Mm Length Screw Which Is Threaded And The Head Is Mobile It Swivels Helping To Defray Vertebral Stress Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible & Mri Friendl Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 9 Spine Implant -9 5.5 Mm Pedical Polyaxial Screws 40 Mm Length Screw Which Is Threaded And The Head Is Mobile It Swivels Helping To Defray Vertebral Stress Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendl Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 10 Spine Implant -10 5.5 Mm Pedical Polyaxial Screws 45 Mm Length Screw Which Is Threaded And The Head Is Mobile It Swivels Helping To Defray Vertebral Stress Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendl Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 11 Spine Implant -11 6.5 Mm Pedical Monoaxial Screws 25 Mm Length Screw Which Is Threaded And The Head Is Rigid Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendl Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 12 Spine Implant -12 6.5 Mm Pedical Monoaxial Screws 40 Mm Length Screw Which Is Threaded And The Head Is Rigid Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendl Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 13 Spine Implant -13 6.5 Mm Pedical Monoaxial Screws 45 Mm Length Screw Which Is Threaded And The Head Is Rigid Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendl Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 14 Spine Implant -14 5.5 Mm Pedical Polyaxial Screws 25 Mm Length Screw Which Is Threaded And The Head Is Mobile It Swivels Helping To Defray Vertebral Stress Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendl Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 15 Spine Implant -15 Cervicle Plate 25 Mm Must Have Additional Locking Mechnism Over The Screw Should Have Compatible With Our Existing Systems 16 Spine Implant -16 Pre Cut Rod 5.5 Mm Rod With Blunt End 80 Mm In Leangth Should Have Bullet Nosed To Allow To Navigate Through Soft Tissue Should Be Fda Approved Made Up Of Medical Grade Titanium 17 Spine Implant -17 Pre Cut Rod 5.5 Mm Rod With Blunt End 90 Mm In Leangth Should Have Bullet Nosed To Allow To Navigate Through Soft Tissue Should Be Fda Approved Made Up Of Medical Grade Titanium 18 Spine Implant -18 Pre Cut Rod 5.5 Mm Rod With Blunt End 100 Mm In Leangth Should Have Bullet Nosed To Allow To Navigate Through Soft Tissue Should Be Fda Approved Made Up Of Medical Grade Titanium 19 Spine Implant -19 Pre Cut Rod 5.5 Mm Rod With Blunt End 120 Mm In Leangth Should Have Bullet Nosed To Allow To Navigate Through Soft Tissue Should Be Fda Approved Made Up Of Medical Grade Titanium 20 Spine Implant -20 Pre Cut Rod 5.5 Mm Rod With Blunt End 140 Mm In Leangth Should Have Bullet Nosed To Allow To Navigate Through Soft Tissue Should Be Fda Approved Made Up Of Medical Grade Titanium 21 Spine Implant -21 Pre Cut Rod 5.5 Mm Rod With Blunt End 160 Mm In Leangth Should Have Bullet Nosed To Allow To Navigate Through Soft Tissue Should Be Fda Approved Made Up Of Medical Grade Titanium 22 Spine Implant -22 Pre Cut Rod 5.5 Mm Rod With Blunt End 180 Mm In Leangth Should Have Bullet Nosed To Allow To Navigate Through Soft Tissue Should Be Fda Approved Made Up Of Medical Grade Titanium 23 Spine Implant -23 Pre Cut Rod 5.5 Mm Rod With Blunt End 200 Mm In Leangth Should Have Bullet Nosed To Allow To Navigate Through Soft Tissue Should Be Fda Approved Made Up Of Medical Grade Titanium 24 Spine Implant -24 Pre Cut Rod 5.5 Mm Rod With Blunt End 250 Mm In Leangth Should Have Bullet Nosed To Allow To Navigate Through Soft Tissue Should Be Fda Approved Made Up Of Medical Grade Titanium 25 Spine Implant -25 Pre Cut Rod 5.5 Mm Rod With Blunt End 300 Mm In Leangth Should Have Bullet Nosed To Allow To Navigate Through Soft Tissue Should Be Fda Approved Made Up Of Medical Grade Titanium 26 Spine Implant -26 Pre Cut Rod 5.5 Mm Rod With Blunt End 500 Mm In Leangth Should Have Bullet Nosed To Allow To Navigate Through Soft Tissue Should Be Fda Approved Made Up Of Medical Grade Titanium 27 Spine Implant -27 Lateral Mass Screw 3.5Mm Size 12Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provides More Control Of The Screw Shank And Head 28 Spine Implant -28 Lateral Mass Screw 3.5Mm Size 14Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 29 Spine Implant -29 Lateral Mass Screw 3.5Mm Size 16 Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 30 Spine Implant -30 Lateral Mass Screw 3.5Mm Size 18 Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 31 Spine Implant -31 Lateral Mass Screw 3.5Mm Size 20 Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 32 Spine Implant -32 Lateral Mass Screw 3.5Mm Size 22 Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 33 Spine Implant -33 Lateral Mass Screw 3.5Mm Size 24 Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 34 Spine Implant -34 Lateral Mass Screw 3.5Mm Size 26 Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 35 Spine Implant -35 Lateral Mass Screw 3.5Mm Size 28 Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 36 Spine Implant -36 Lateral Mass Screw 3.5Mm Size 30 Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 37 Spine Implant -37 Lateral Mass Screw 4.2Mm Size 12 Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 38 Spine Implant -38 Lateral Mass Screw 4.2Mm Size 14Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 39 Spine Implant -39 Lateral Mass Screw 4.2Mm Size 16Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 40 Spine Implant -40 Lateral Mass Screw 4.2Mm Size 18Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 41 Spine Implant -41 Lateral Mass Screw 4.2Mm Size 20Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 42 Spine Implant -42 Lateral Mass Screw 4.2Mm Size 22Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 43 Spine Implant -43 Lateral Mass Screw 4.2Mm Size 24Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 44 Spine Implant -44 Lateral Mass Screw 4.2Mm Size 26Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 45 Spine Implant -45 Lateral Mass Screw 4.2Mm Size 28Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 46 Spine Implant -46 Lateral Mass Screw 4.2Mm Size 30Mm Screws Must Have A 60 Cone Of Angulation With An Additional 15 Bias In One Direction This Biased Angulation Should Allows Optimal Contact With The Posterior Elements The Screw Shank Must Be More Rigid Coupling With The Screw Head Which Must Provide More Control Of The Screw Shank And Head 47 Spine Implant -47 3.5Mm Rod For Lateral Mass Screw Pre Cut Rod With Blunt End 200 Mm In Leangth Should Have Bullet Nosed To Allow To Navigate Through Soft Tissue Should Be Fda Approved Made Up Of Medical Grade Titanium Must Be Compatible With Screws Of Our Existing Systems 48 Spine Implant -48 Tappered Rod 3.5Mm-5.5Mm Spine System Tappered Rod Must Have Dual Different Diameter A Viable Option To Connect Screws To Stabilize Cervicothoracic Junction Must Be Compatible With Screws Of Our Existing Systems 49 Spine Implant -49 Cervical Mess Cage 12Mm Dia H 10Mm Cervical Mess Cage Must Be Made Up Medical Grade Titanium Anatomically Design Should Be Cuttable Band Able Must Having Diagonal Oblong Holes Mess Design 50 Spine Implant -50 Cervical Mess Cage 12Mm Dia H 15Mm Cervical Mess Cage Must Be Made Up Medical Grade Titanium Anatomically Design Should Be Cuttable Band Able Must Having Diagonal Oblong Holes Mess Design 51 Spine Implant -51 Cervical Mess Cage 12Mm Dia H 20Mm Cervical Mess Cage Must Be Made Up Medical Grade Titanium Anatomically Design Should Be Cuttable Band Able Must Having Diagonal Oblong Holes Mess Design 52 Spine Implant -52 Cervical Mess Cage 12Mm Dia H 25Mm Cervical Mess Cage Must Be Made Up Medical Grade Titanium Anatomically Design Should Be Cuttable Band Able Must Having Diagonal Oblong Holes Mess Design 53 Spine Implant -53 Cervical Mess Cage 12Mm Dia H 30Mm Cervical Mess Cage Must Be Made Up Medical Grade Titanium Anatomically Design Should Be Cuttable Band Able Must Having Diagonal Oblong Holes Mess Design 54 Spine Implant -54 Mis Pedicle Screws Reduction Type Threaded Locking Caps Avoid Provides Fixation Irrespective Of Complexity Due To Integrated Streamlined Rod Reduction And A Strong Screw Sleeve Connection Screw And Sleeve Must Be Diffrent No Extra Incision For Road Inster Procedure By Reducing Or Eliminating The Inherent Challenges Faced With Multilevel Surgery Must Be Usfda Approved Ce Certificate From Notified Body Size 5.5 Mm Screw 30Mm 55 Spine Implant -55 Mis Pedicle Screws Reduction Type Threaded Locking Caps Avoid Provides Fixation Irrespective Of Complexity Due To Integrated Streamlined Rod Reduction And A Strong Screw Sleeve Connection Screw And Sleeve Must Be Diffrent No Extra Incision For Road Inster Procedure By Reducing Or Eliminating The Inherent Challenges Faced With Multilevel Surgery Must Be Usfda Approved Ce Certificate From Notified Body Size 5.5 Mm Screw 35 Mm 56 Spine Implant -56 Mis Pedicle Screws Reduction Type Threaded Locking Caps Avoid Provides Fixation Irrespective Of Complexity Due To Integrated Streamlined Rod Reduction And A Strong Screw Sleeve Connection Screw And Sleeve Must Be Diffrent No Extra Incision For Road Inster Procedure By Reducing Or Eliminating The Inherent Challenges Faced With Multilevel Surgery Must Be Usfda Approved Ce Certificate From Notified Body Size 5.5 Mm Screw 40 Mm 57 Spine Implant -57 Mis Pedicle Screws Reduction Type Threaded Locking Caps Avoid Provides Fixation Irrespective Of Complexity Due To Integrated Streamlined Rod Reduction And A Strong Screw Sleeve Connection Screw And Sleeve Must Be Diffrent No Extra Incision For Road Inster Procedure By Reducing Or Eliminating The Inherent Challenges Faced With Multilevel Surgery Must Be Usfda Approved Ce Certificate From Notified Body Size 5.5 Mm Screw 45 Mm 58 Spine Implant -58 Mis Pedicle Screws Reduction Type Threaded Locking Caps Avoid Provides Fixation Irrespective Of Complexity Due To Integrated Streamlined Rod Reduction And A Strong Screw Sleeve Connection Screw And Sleeve Must Be Diffrent No Extra Incision For Road Inster Procedure By Reducing Or Eliminating The Inherent Challenges Faced With Multilevel Surgery Must Be Usfda Approved Ce Certificate From Notified Body Size 5.5 Mm Screw 50 Mm 59 Spine Implant -59 Mis Pedicle Screws Reduction Type Threaded Locking Caps Avoid Provides Fixation Irrespective Of Complexity Due To Integrated Streamlined Rod Reduction And A Strong Screw Sleeve Connection Screw And Sleeve Must Be Diffrent No Extra Incision For Road Inster Procedure By Reducing Or Eliminating The Inherent Challenges Faced With Multilevel Surgery Must Be Usfda Approved Ce Certificate From Notified Body Size 6.5 Mm Screw 35 Mm 60 Spine Implant -60 Mis Pedicle Screws Reduction Type Threaded Locking Caps Avoid Provides Fixation Irrespective Of Complexity Due To Integrated Streamlined Rod Reduction And A Strong Screw Sleeve Connection Screw And Sleeve Must Be Diffrent No Extra Incision For Road Inster Procedure By Reducing Or Eliminating The Inherent Challenges Faced With Multilevel Surgery Must Be Usfda Approved Ce Certificate From Notified Body Size 6.5 Mm Screw 40 Mm 61 Spine Implant -61 Mis Pedicle Screws Reduction Type Threaded Locking Caps Avoid Provides Fixation Irrespective Of Complexity Due To Integrated Streamlined Rod Reduction And A Strong Screw Sleeve Connection Screw And Sleeve Must Be Diffrent No Extra Incision For Road Inster Procedure By Reducing Or Eliminating The Inherent Challenges Faced With Multilevel Surgery Must Be Usfda Approved Ce Certificate From Notified Body Size 6.5 Mm Screw 45 Mm 62 Spine Implant -62 Mis Pedicle Screws Reduction Type Threaded Locking Caps Avoid Provides Fixation Irrespective Of Complexity Due To Integrated Streamlined Rod Reduction And A Strong Screw Sleeve Connection Screw And Sleeve Must Be Diffrent No Extra Incision For Road Inster Procedure By Reducing Or Eliminating The Inherent Challenges Faced With Multilevel Surgery Must Be Usfda Approved Ce Certificate From Notified Body Size 6.5 Mm Screw 50 Mm 63 Spine Implant -63 Mis Rod Pre Curved 5.5 Mm Compitiable With Above Screw Size 50 Mm 64 Spine Implant -64 Mis Rod Pre Curved 5.5 Mm Compitiable With Above Screw Size 60 Mm 65 Spine Implant -65 Mis Rod Pre Curved 5.5 Mm Compitiable With Above Screw Size 70 Mm 66 Spine Implant -66 Mis Rod Pre Curved 5.5 Mm Compitiable With Above Screw Size 80 Mm 67 Spine Implant -67 Mis Rod Pre Curved 5.5 Mm Compitiable With Above Screw Size 90 Mm 68 Spine Implant -68 Mis Rod Pre Curved 5.5 Mm Compitiable With Above Screw Size 100 Mm 69 Spine Implant -69 Mis Rod Pre Curved 5.5 Mm Compitiable With Above Screw Size 120Mm 70 Spine Implant -70 Bullet Cage 0 Degree 8Mmbullet Cage Must Be Made Up Medical Grade Titanium Anatomically Design Must Be Avilable In Different Degree Of Angluation With Different Hight Options 71 Spine Implant -71 Bullet Cage 0 Degree 9Mmbullet Cage Must Be Made Up Medical Grade Titanium Anatomically Design Must Be Avilable In Different Degree Of Angluation With Different Hight Options 72 Spine Implant -72 Bullet Cage 0 Degree 10Mmbullet Cage Must Be Made Up Medical Grade Titanium Anatomically Design Must Be Avilable In Different Degree Of Angluation With Different Hight Options 73 Spine Implant -73 Bullet Cage 0 Degree 11Mmbullet Cage Must Be Made Up Medical Grade Titanium Anatomically Design Must Be Avilable In Different Degree Of Angluation With Different Hight Options 74 Spine Implant -74 Bullet Cage 0 Degree 12Mmbullet Cage Must Be Made Up Medical Grade Titanium Anatomically Design Must Be Avilable In Different Degree Of Angluation With Different Hight Options 75 Spine Implant -75 Bullet Cage 0 Degree 13Mmbullet Cage Must Be Made Up Medical Grade Titanium Anatomically Design Must Be Avilable In Different Degree Of Angluation With Different Hight Options 76 Spine Implant -76 Bullet Cage 4 Degree 8Mmbullet Cage Must Be Made Up Medical Grade Titanium Anatomically Design Must Be Avilable In Different Degree Of Angluation With Different Hight Options 77 Spine Implant -77 Bullet Cage 4 Degree 9Mmbullet Cage Must Be Made Up Medical Grade Titanium Anatomically Design Must Be Avilable In Different Degree Of Angluation With Different Hight Options 78 Spine Implant -78 Bullet Cage 4 Degree 10Mmbullet Cage Must Be Made Up Medical Grade Titanium Anatomically Design Must Be Avilable In Different Degree Of Angluation With Different Hight Options 79 Spine Implant -79 Bullet Cage 4 Degree 11Mmbulletcage Must Be Made Up Medical Grade Titanium Anatomically Design Must Be Avilable In Different Degree Of Angluation With Different Hight Options 80 Spine Implant -80 Pedicle Screw For Iliac Wing 7.5 Mm Dia Poly 55 Mm Length With Domino Connector Screw Which Is Threaded And The Head Is Multiaxil Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendly Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 81 Spine Implant -81 Pedicle Screw For Iliac Wing 7.5 Mm Dia Poly 60 Mm Length With Domino Connector Screw Which Is Threaded And The Head Is Multiaxil Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendly Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 82 Spine Implant -82 Pedicle Screw For Iliac Wing 7.5 Mm Dia Poly 65 Mmlength With Domino Connector Screw Which Is Threaded And The Head Is Multiaxil Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendly Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 83 Spine Implant -83 Pedicle Screw For Iliac Wing 7.5 Mm Dia Poly 70 Mm Length With Domino Connector Screw Which Is Threaded And The Head Is Multiaxil Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendly Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 84 Spine Implant -84 Pedicle Screw For Iliac Wing 7.5 Mm Dia Poly 75 Mmlength With Domino Connector Screw Which Is Threaded And The Head Is Multiaxil Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendly Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 85 Spine Implant -85 Pedicle Screw For Iliac Wing 7.5 Mm Dia Poly 80 Mm Length With Domino Connector Screw Which Is Threaded And The Head Is Multiaxil Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendly Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 86 Spine Implant -86 Pedicle Reduction Screw For Listhesis Correction Dia 5.5 Rod System Length 35 Mm Breakable Wings And The Head Is Multiaxil Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendly Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 87 Spine Implant -87 Pedicle Reduction Screw For Listhesis Correction Dia 5.5 Rod System Length 40 Mm Breakable Wings And The Head Is Multiaxil Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendly Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 88 Spine Implant -88 Pedicle Reduction Screw For Listhesis Correction Dia 5.5 Rod System Length 45 Mm Breakable Wings And The Head Is Multiaxil Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendly Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 89 Spine Implant -89 Pedicle Reduction Screw For Listhesis Correction Dia 6.5 Rod System Length 35 Mm Breakable Wings And The Head Is Multiaxil Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendly Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 90 Spine Implant -90 Pedicle Reduction Screw For Listhesis Correction Dia 6.5 Rod System Length 40 Mm Breakable Wings And The Head Is Multiaxil Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendly Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 91 Spine Implant -91 Pedicle Reduction Screw For Listhesis Correction Dia 6.5 Rod System Length 45 Mm Breakable Wings And The Head Is Multiaxil Head Design Should Be Tapered Tulip Type To Minimize Facet Impingement Its Should Accommodate 5.5 Mm Rod System Should Be Bio Compatible Mri Friendly Screw Must Have Dual Thread Starting Cancellous Self Tapping Threads Inni Screw Design In Such A Way To Prevent Rod Migration Should Have Compatible With Our Existing Systems 92 Spine Implant -92 Highly Porous Titanium Alloy On Top And Bottom Of Implant And All Sides Of Internal Graft Window Tlif Cages 7 Mm 20 Mm Smooth Wedge Nose To Facilitate Insertion Thin Layer Of Solid Aterial To Provide Smooth Surface During Insertion And Reduce Potential To Catch Soft Tissue Should Have Compatible With Our Existing Systems 93 Spine Implant -93 Highly Porous Titanium Alloy On Top And Bottom Of Implant And All Sides Of Internal Graft Window Tlif Cages 8 Mm 20 Mm Smooth Wedge Nose To Facilitate Insertion Thin Layer Of Solid Material To Provide Smooth Surface During Insertion And Reduce Potential To Catch Soft Tissue Should Have Compatible With Our Existing Systems 94 Spine Implant -94 Highly Porous Titanium Alloy On Top And Bottom Of Implant And All Sides Of Internal Graft Window Tlif Cages 9 Mm 20 Mm Smooth Wedge Nose To Facilitate Insertion Thin Layer Of Solid Material To Provide Smooth Surface During Insertion And Reduce Potential To Catch Soft Tissue Should Have Compatible With Our Existing Systems 95 Spine Implant -95 Highly Porous Titanium Alloy On Top And Bottom Of Implant And All Sides Of Internal Graft Window Tlif Cages 10Mm 20 Mm Smooth Wedge Nose To Facilitate Insertion Thin Layer Of Solid Material To Provide Smooth Surface During Insertion And Reduce Potential To Catch Soft Tissue Should Have Compatible With Our Existing Systems 96 Spine Implant -96 Highly Porous Titanium Alloy On Top And Bottom Of Implant And All Sides Of Internal Graft Window Tlif Cages 11 Mm 20 Mmsmooth Wedge Nose To Facilitate Insertion Thin Layer Of Solid Material To Provide Smooth Surface During Insertion And Reduce Potential To Catch Soft Tissue Should Have Compatible With Our Existing Systems 97 Spine Implant -97 Highly Porous Titanium Alloy On Top And Bottom Of Implant And All Sides Of Internal Graft Window Tlif Cages 12 Mm 20 Mm Smooth Wedge Nose To Facilitate Insertion Thin Layer Of Solid Material To Provide Smooth Surface During Insertion And Reduce Potential To Catch Soft Tissue Should Have Compatible With Our Existing Systems 98 Spine Implant -98 Highly Porous Titanium Alloy On Top And Bottom Of Implant And All Sides Of Internal Graft Window Tlif Cages 13 Mm 20 Mm Smooth Wedge Nose To Facilitate Insertion Thin Layer Of Solid Material To Provide Smooth Surface During Insertion And Reduce Potential To Catch Soft Tissue Should Have Compatible With Our Existing Systems 99 Spine Implant -99 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 12Mm Dia 25X25 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 100 Spine Implant -100 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 12Mm Dia 25X35 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 101 Spine Implant -101 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 12Mm Dia 35X55 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 102 Spine Implant -102 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 12Mm Dia 55X77 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 103 Spine Implant -103 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 14Mm Dia 25X25 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 104 Spine Implant -104 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 14Mm Dia 25X35 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 105 Spine Implant -105 Expandable Cagestitanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 14Mm Dia 35X55 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 106 Spine Implant -106 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 14Mm Dia 55X77 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 107 Spine Implant -107 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 16Mm Dia 25X25 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 108 Spine Implant -108 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 16Mm Dia 25X35 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 109 Spine Implant -109 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 16Mm Dia 35X55 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 110 Spine Implant -110 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 16Mm Dia 55X77 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 111 Spine Implant -111 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 18Mm Dia 25X25 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 112 Spine Implant -112 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 18Mm Dia 25X35 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 113 Spine Implant -113 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 18Mm Dia 35X55 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 114 Spine Implant -114 Expandable Cages Titanium Metal Endplates Easily Identifiable Radiographic Markers Expandable Cage 18Mm Dia 55X77 Load Sharing Strain Limiting Design Side Strut Design Large Graft Cavity With Fenestrated Endplates One Instrument For Both Insertion And Expansion Should Have Compatible With Our Existing Systems 115 Spine Implant -115 Titanium Mesh Cages With Holderimplants Are Designed To Restore Normal Spinal Alignment And Improve The Bone To Implant Interface 12 Mm Dia Height 15 20 25 30 35 40 45 50 Mm 116 Spine Implant -116 Titanium Mesh Cages With Holder Implants Are Designed To Restore Normal Spinal Alignment And Improve The Bone To Implant Interface 14 Mm Dia Height 15 20 25 30 35 40 45 50 Mm 117 Spine Implant -117 Titanium Mesh Cages With Holder Implants Are Designed To Restore Normal Spinal Alignment And Improve The Bone To Implant Interface 16 Mm Dia Height 15 20 25 30 35 40 45 50 Mm 118 Spine Implant -118 Titanium Mesh Cages With Holder Implants Are Designed To Restore Normal Spinal Alignment And Improve The Bone To Implant Interface 18 Mm Dia Height 15 20 25 30 35 40 45 50 Mm 119 Spine Implant -119 Dynamic Cervical Implants For Cervicle Disk Replacement 120 Spine Implant -120 Stand Alone Cages For Cervical Spine Integrated Plate And Spacer Is Designed To Preserve The Natural Anatomical Profile Of The Spine System Streamlines The Entire Acdf Procedure And Facilitates A Less Invasive Approach Through A Small Incision With Less Retraction For Biomechanical Strength Of A Traditional Acdf With Two Self Drilling Screw Size 5Mm 13Mm 121 Spine Implant -121 Stand Alone Cages For Cervical Spine Integrated Plate And Spacer Is Designed To Preserve The Natural Anatomical Profile Of The Spine System Streamlines The Entire Acdf Procedure And Facilitates A Less Invasive Approach Through A Small Incision With Less Retraction For Biomechanical Strength Of A Traditional Acdf With Two Self Drilling Screw Size 6Mm 13Mm 122 Spine Implant -122 Stand Alone Cages For Cervical Spine Integrated Plate And Spacer Is Designed To Preserve The Natural Anatomical Profile Of The Spine System Streamlines The Entire Acdf Procedure And Facilitates A Less Invasive Approach Through A Small Incision With Less Retraction For Biomechanical Strength Of A Traditional Acdf With Two Self Drilling Screw Size 7Mm 13Mm 123 Spine Implant -123 Stand Alone Cages For Cervical Spine Integrated Plate And Spacer Is Designed To Preserve The Natural Anatomical Profile Of The Spine System Streamlines The Entire Acdf Procedure And Facilitates A Less Invasive Approach Through A Small Incision With Less Retraction For Biomechanical Strength Of A Traditional Acdf With Two Self Drilling Screw Size 8Mm 13Mm 124 Spine Implant -124 Stand Alone Cages For Cervical Spine Integrated Plate And Spacer Is Designed To Preserve The Natural Anatomical Profile Of The Spine System Streamlines The Entire Acdf Procedure And Facilitates A Less Invasive Approach Through A Small Incision With Less Retraction For Biomechanical Strength Of A Traditional Acdf With Two Self Drilling Screw Size 9Mm 13Mm 125 Spine Implant -125 Bone Cement Vertibroplasty Multiple Level Vertebroplasties And Vertebral Augmentations Bone Cement Maintains To Fill Cavity 126 Spine Implant -126 Needles Are Packaged Sterile With A Universal Cap Probe And Probe Guide Centimeter Depth Markings Along The Outer Cannula Help Guide Needle Penetration Through The Cortical Layer And Marrow Two Piece Handle Provides Tactile Feedback And Helps Increase Control During Needle Insertion 127 Spine Implant -127 Dura Patch Effective Onlay Grafts For The Restoration And Repair Of Dura Mater Moist Surfaces Of The Brain And Spinal Cord Rapidly Supporting The Formation Of A Biological Seal To Protect Against Csf Leakage Size 2.5 Cm 2.5 Cm Product 128 Spine Implant -128 Dura Patch Effective Onlay Grafts For The Restoration And Repair Of Dura Mater Moist Surfaces Of The Brain And Spinal Cord Rapidly Supporting The Formation Of A Biological Seal To Protect Against Csf Leakage Size 2.5 Cm 7.5 Cm Product 129 Spine Implant -129 Dura Patch Effective Onlay Grafts For The Restoration And Repair Of Dura Mater Moist Surfaces Of The Brain And Spinal Cord Rapidly Supporting The Formation Of A Biological Seal To Protect Against Csf Leakage Size 5 Cm 5 Cm Product 130 Spine Implant -130 Biocompatibility Resistance To Corrosion And Weight Bearing Strength It Is Also Mri Compatible Acdf Rescue Screws For Standalon Cage 4Mm 12 Mm 14Mm 16Mm 18Mm 20Mm

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