titanium bone screws Search Results


90
fhc inc titanium-made screw bone anchors
Titanium Made Screw Bone Anchors, supplied by fhc inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/titanium+bone+screws/pmc11505023-70-10-18?v=fhc+inc
Average 90 stars, based on 1 article reviews
titanium-made screw bone anchors - by Bioz Stars, 2026-07
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90
Renovis Inc bone screws manufactured from titanium alloy (ti 6 al 4 v)
Bone Screws Manufactured From Titanium Alloy (Ti 6 Al 4 V), supplied by Renovis Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/titanium+bone+screws/pmc06330582-8-34-0?v=Renovis+Inc
Average 90 stars, based on 1 article reviews
bone screws manufactured from titanium alloy (ti 6 al 4 v) - by Bioz Stars, 2026-07
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90
SI-BONE Inc titanium alloy trauma screws
Titanium Alloy Trauma Screws, supplied by SI-BONE Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/titanium+bone+screws/pmc10613391-132-33-37?v=SI-BONE+Inc
Average 90 stars, based on 1 article reviews
titanium alloy trauma screws - by Bioz Stars, 2026-07
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90
Howmedica titanium alloy 4.5-mm-diameter cortical bone screws
Titanium Alloy 4.5 Mm Diameter Cortical Bone Screws, supplied by Howmedica, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/titanium+bone+screws/pm17495293-51-6-12?v=Howmedica
Average 90 stars, based on 1 article reviews
titanium alloy 4.5-mm-diameter cortical bone screws - by Bioz Stars, 2026-07
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90
CIRS Inc custom phantom with replaceable bone or titanium screws in l5
Custom Phantom With Replaceable Bone Or Titanium Screws In L5, supplied by CIRS Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/titanium+bone+screws/pm37311147-17332-10-16?v=CIRS+Inc
Average 90 stars, based on 1 article reviews
custom phantom with replaceable bone or titanium screws in l5 - by Bioz Stars, 2026-07
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90
fhc inc titanium-made screw bone anchors type waypoint
Titanium Made Screw Bone Anchors Type Waypoint, supplied by fhc inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/titanium+bone+screws/pmc11505023-70-11-18?v=fhc+inc
Average 90 stars, based on 1 article reviews
titanium-made screw bone anchors type waypoint - by Bioz Stars, 2026-07
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90
Straumann GmbH titanium-based bone graft fixation screws
(a, b) View of subnasal depression. (c–e) The PMMA block was fixed with two titanium-based <t>bone</t> <t>graft</t> <t>fixation</t> <t>screws.</t> (f) The gingival flap was repositioned with vertical mattress sutures.
Titanium Based Bone Graft Fixation Screws, supplied by Straumann GmbH, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/titanium+bone+screws/pmc08714327-44-11-23?v=Straumann+GmbH
Average 90 stars, based on 1 article reviews
titanium-based bone graft fixation screws - by Bioz Stars, 2026-07
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90
Straumann GmbH titanium screw-type bone-level implants
(a, b) View of subnasal depression. (c–e) The PMMA block was fixed with two titanium-based <t>bone</t> <t>graft</t> <t>fixation</t> <t>screws.</t> (f) The gingival flap was repositioned with vertical mattress sutures.
Titanium Screw Type Bone Level Implants, supplied by Straumann GmbH, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/titanium+bone+screws/pmc10088209-100-16-22?v=Straumann+GmbH
Average 90 stars, based on 1 article reviews
titanium screw-type bone-level implants - by Bioz Stars, 2026-07
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90
Thomas RECORDING titanium reference bone screw
Description of the implantation procedure (A) Situate the animal in a stereotaxic frame using hollow ear bars. (B) After contact sterilization, create an incision down midline to reveal cranial sutures. Create a craniectomy above MGB (−6 mm A.P., −3.5 mm M.L.). Place 4 <t>bone</t> screws equidistant around the MGB craniectomy. One bone <t>screw</t> (shown in gold) is a <t>titanium</t> bone screw to serve as recording electrode ground and <t>reference.</t> (C) Reflect the temporalis muscle over the cranial ridge and off the side of the skull. Care should be taken to prevent blunt dissection of the muscle. Accidental dissection of the muscle runs the risk of severing the supraorbital nerve, leading to inability to close eyelid after recovery. (D) Side profile of skull above A1. Create a 2 × 2 mm craniectomy above A1 by repeated thinning of skull around a square area. The skull flap can then be removed using a micro Friedman rongeur. (E) Gently remove the dura above A1 using a bent tip 25G needle. Dura can be seen as a reflective membrane which can be gently hooked by the needle. Once hooked, the dura can be removed by gently pulling the needle away from the brain. (F) Tie electrode ground and reference wire to the titanium bone screw using Teflon tweezers. Suture knots should be made to ensure wires make solid contact with the bone screw. (G) Place the recording electrode at 500 μ m into A1. Start applying Gaussian noise burst stimuli to the contralateral ear through the hollow ear bars. Slowly advance the array until consistent, low latency multiunit responses are seen on some of the recording electrodes. This is indicative of putative placement of the device into layer III/IV. (H) Seal recording electrode into place by first applying Kwik-Sil around the electrode to act as a dental sealant, followed by dental acrylic around the electrode. Note that Kwik-Sil only provides a loose connection, and the device should only be removed from electrode holder after dental acrylic has dried. (I) Implant the fiber optrode into the MGB (D.V. −6 mm). Connect the optrode to the stereotaxic frame and position the optrode above the surface of the brain. Slowly advance the optrode until the desired depth is reached. (J) Seal the optrode into place using dental acrylic. Complete the headcap by placing the recording interface on top of the skull at a distance from the optrode and sealed to the skull using dental acrylic. Recording electrode ribbon cable and structural bone screws should be placed entirely under dental acrylic. A purse string suture is then placed around the headcap to facilitate healing. Figure was created using BioRender ( www.biorender.com ) under a publication license.
Titanium Reference Bone Screw, supplied by Thomas RECORDING, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/titanium+bone+screws/pmc11728987-55-0-5?v=Thomas+RECORDING
Average 90 stars, based on 1 article reviews
titanium reference bone screw - by Bioz Stars, 2026-07
90/100 stars
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90
Cochlear Limited bone-anchored titanium screw pedestal
Description of the implantation procedure (A) Situate the animal in a stereotaxic frame using hollow ear bars. (B) After contact sterilization, create an incision down midline to reveal cranial sutures. Create a craniectomy above MGB (−6 mm A.P., −3.5 mm M.L.). Place 4 <t>bone</t> screws equidistant around the MGB craniectomy. One bone <t>screw</t> (shown in gold) is a <t>titanium</t> bone screw to serve as recording electrode ground and <t>reference.</t> (C) Reflect the temporalis muscle over the cranial ridge and off the side of the skull. Care should be taken to prevent blunt dissection of the muscle. Accidental dissection of the muscle runs the risk of severing the supraorbital nerve, leading to inability to close eyelid after recovery. (D) Side profile of skull above A1. Create a 2 × 2 mm craniectomy above A1 by repeated thinning of skull around a square area. The skull flap can then be removed using a micro Friedman rongeur. (E) Gently remove the dura above A1 using a bent tip 25G needle. Dura can be seen as a reflective membrane which can be gently hooked by the needle. Once hooked, the dura can be removed by gently pulling the needle away from the brain. (F) Tie electrode ground and reference wire to the titanium bone screw using Teflon tweezers. Suture knots should be made to ensure wires make solid contact with the bone screw. (G) Place the recording electrode at 500 μ m into A1. Start applying Gaussian noise burst stimuli to the contralateral ear through the hollow ear bars. Slowly advance the array until consistent, low latency multiunit responses are seen on some of the recording electrodes. This is indicative of putative placement of the device into layer III/IV. (H) Seal recording electrode into place by first applying Kwik-Sil around the electrode to act as a dental sealant, followed by dental acrylic around the electrode. Note that Kwik-Sil only provides a loose connection, and the device should only be removed from electrode holder after dental acrylic has dried. (I) Implant the fiber optrode into the MGB (D.V. −6 mm). Connect the optrode to the stereotaxic frame and position the optrode above the surface of the brain. Slowly advance the optrode until the desired depth is reached. (J) Seal the optrode into place using dental acrylic. Complete the headcap by placing the recording interface on top of the skull at a distance from the optrode and sealed to the skull using dental acrylic. Recording electrode ribbon cable and structural bone screws should be placed entirely under dental acrylic. A purse string suture is then placed around the headcap to facilitate healing. Figure was created using BioRender ( www.biorender.com ) under a publication license.
Bone Anchored Titanium Screw Pedestal, supplied by Cochlear Limited, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/titanium+bone+screws/pmc06405327-14-35-36?v=Cochlear+Limited
Average 90 stars, based on 1 article reviews
bone-anchored titanium screw pedestal - by Bioz Stars, 2026-07
90/100 stars
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90
BioMaterials Korea bone fixation titanium self-tapping screws in diameter and in length
Description of the implantation procedure (A) Situate the animal in a stereotaxic frame using hollow ear bars. (B) After contact sterilization, create an incision down midline to reveal cranial sutures. Create a craniectomy above MGB (−6 mm A.P., −3.5 mm M.L.). Place 4 <t>bone</t> screws equidistant around the MGB craniectomy. One bone <t>screw</t> (shown in gold) is a <t>titanium</t> bone screw to serve as recording electrode ground and <t>reference.</t> (C) Reflect the temporalis muscle over the cranial ridge and off the side of the skull. Care should be taken to prevent blunt dissection of the muscle. Accidental dissection of the muscle runs the risk of severing the supraorbital nerve, leading to inability to close eyelid after recovery. (D) Side profile of skull above A1. Create a 2 × 2 mm craniectomy above A1 by repeated thinning of skull around a square area. The skull flap can then be removed using a micro Friedman rongeur. (E) Gently remove the dura above A1 using a bent tip 25G needle. Dura can be seen as a reflective membrane which can be gently hooked by the needle. Once hooked, the dura can be removed by gently pulling the needle away from the brain. (F) Tie electrode ground and reference wire to the titanium bone screw using Teflon tweezers. Suture knots should be made to ensure wires make solid contact with the bone screw. (G) Place the recording electrode at 500 μ m into A1. Start applying Gaussian noise burst stimuli to the contralateral ear through the hollow ear bars. Slowly advance the array until consistent, low latency multiunit responses are seen on some of the recording electrodes. This is indicative of putative placement of the device into layer III/IV. (H) Seal recording electrode into place by first applying Kwik-Sil around the electrode to act as a dental sealant, followed by dental acrylic around the electrode. Note that Kwik-Sil only provides a loose connection, and the device should only be removed from electrode holder after dental acrylic has dried. (I) Implant the fiber optrode into the MGB (D.V. −6 mm). Connect the optrode to the stereotaxic frame and position the optrode above the surface of the brain. Slowly advance the optrode until the desired depth is reached. (J) Seal the optrode into place using dental acrylic. Complete the headcap by placing the recording interface on top of the skull at a distance from the optrode and sealed to the skull using dental acrylic. Recording electrode ribbon cable and structural bone screws should be placed entirely under dental acrylic. A purse string suture is then placed around the headcap to facilitate healing. Figure was created using BioRender ( www.biorender.com ) under a publication license.
Bone Fixation Titanium Self Tapping Screws In Diameter And In Length, supplied by BioMaterials Korea, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/titanium+bone+screws/pm36760029-57-16-30?v=BioMaterials+Korea
Average 90 stars, based on 1 article reviews
bone fixation titanium self-tapping screws in diameter and in length - by Bioz Stars, 2026-07
90/100 stars
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90
Kinamed Inc titanium self-tapping bone screws quick tap
Description of the implantation procedure (A) Situate the animal in a stereotaxic frame using hollow ear bars. (B) After contact sterilization, create an incision down midline to reveal cranial sutures. Create a craniectomy above MGB (−6 mm A.P., −3.5 mm M.L.). Place 4 <t>bone</t> screws equidistant around the MGB craniectomy. One bone <t>screw</t> (shown in gold) is a <t>titanium</t> bone screw to serve as recording electrode ground and <t>reference.</t> (C) Reflect the temporalis muscle over the cranial ridge and off the side of the skull. Care should be taken to prevent blunt dissection of the muscle. Accidental dissection of the muscle runs the risk of severing the supraorbital nerve, leading to inability to close eyelid after recovery. (D) Side profile of skull above A1. Create a 2 × 2 mm craniectomy above A1 by repeated thinning of skull around a square area. The skull flap can then be removed using a micro Friedman rongeur. (E) Gently remove the dura above A1 using a bent tip 25G needle. Dura can be seen as a reflective membrane which can be gently hooked by the needle. Once hooked, the dura can be removed by gently pulling the needle away from the brain. (F) Tie electrode ground and reference wire to the titanium bone screw using Teflon tweezers. Suture knots should be made to ensure wires make solid contact with the bone screw. (G) Place the recording electrode at 500 μ m into A1. Start applying Gaussian noise burst stimuli to the contralateral ear through the hollow ear bars. Slowly advance the array until consistent, low latency multiunit responses are seen on some of the recording electrodes. This is indicative of putative placement of the device into layer III/IV. (H) Seal recording electrode into place by first applying Kwik-Sil around the electrode to act as a dental sealant, followed by dental acrylic around the electrode. Note that Kwik-Sil only provides a loose connection, and the device should only be removed from electrode holder after dental acrylic has dried. (I) Implant the fiber optrode into the MGB (D.V. −6 mm). Connect the optrode to the stereotaxic frame and position the optrode above the surface of the brain. Slowly advance the optrode until the desired depth is reached. (J) Seal the optrode into place using dental acrylic. Complete the headcap by placing the recording interface on top of the skull at a distance from the optrode and sealed to the skull using dental acrylic. Recording electrode ribbon cable and structural bone screws should be placed entirely under dental acrylic. A purse string suture is then placed around the headcap to facilitate healing. Figure was created using BioRender ( www.biorender.com ) under a publication license.
Titanium Self Tapping Bone Screws Quick Tap, supplied by Kinamed Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/titanium+bone+screws/10__3171_slash_2014__12__jns141768-95-10-14?v=Kinamed+Inc
Average 90 stars, based on 1 article reviews
titanium self-tapping bone screws quick tap - by Bioz Stars, 2026-07
90/100 stars
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Image Search Results


(a, b) View of subnasal depression. (c–e) The PMMA block was fixed with two titanium-based bone graft fixation screws. (f) The gingival flap was repositioned with vertical mattress sutures.

Journal: Case Reports in Dentistry

Article Title: Labial Repositioning Using Print Manufactured Polymethylmethacrylate- (PMMA-) Based Cement for Gummy Smile

doi: 10.1155/2021/7607522

Figure Lengend Snippet: (a, b) View of subnasal depression. (c–e) The PMMA block was fixed with two titanium-based bone graft fixation screws. (f) The gingival flap was repositioned with vertical mattress sutures.

Article Snippet: After crown lengthening, the PMMA block was fixed with two titanium-based bone graft fixation screws, measuring 1.5 mm × 10 mm (Neodent, Group Straumann, Curitiba, Brazil).

Techniques: Blocking Assay

Description of the implantation procedure (A) Situate the animal in a stereotaxic frame using hollow ear bars. (B) After contact sterilization, create an incision down midline to reveal cranial sutures. Create a craniectomy above MGB (−6 mm A.P., −3.5 mm M.L.). Place 4 bone screws equidistant around the MGB craniectomy. One bone screw (shown in gold) is a titanium bone screw to serve as recording electrode ground and reference. (C) Reflect the temporalis muscle over the cranial ridge and off the side of the skull. Care should be taken to prevent blunt dissection of the muscle. Accidental dissection of the muscle runs the risk of severing the supraorbital nerve, leading to inability to close eyelid after recovery. (D) Side profile of skull above A1. Create a 2 × 2 mm craniectomy above A1 by repeated thinning of skull around a square area. The skull flap can then be removed using a micro Friedman rongeur. (E) Gently remove the dura above A1 using a bent tip 25G needle. Dura can be seen as a reflective membrane which can be gently hooked by the needle. Once hooked, the dura can be removed by gently pulling the needle away from the brain. (F) Tie electrode ground and reference wire to the titanium bone screw using Teflon tweezers. Suture knots should be made to ensure wires make solid contact with the bone screw. (G) Place the recording electrode at 500 μ m into A1. Start applying Gaussian noise burst stimuli to the contralateral ear through the hollow ear bars. Slowly advance the array until consistent, low latency multiunit responses are seen on some of the recording electrodes. This is indicative of putative placement of the device into layer III/IV. (H) Seal recording electrode into place by first applying Kwik-Sil around the electrode to act as a dental sealant, followed by dental acrylic around the electrode. Note that Kwik-Sil only provides a loose connection, and the device should only be removed from electrode holder after dental acrylic has dried. (I) Implant the fiber optrode into the MGB (D.V. −6 mm). Connect the optrode to the stereotaxic frame and position the optrode above the surface of the brain. Slowly advance the optrode until the desired depth is reached. (J) Seal the optrode into place using dental acrylic. Complete the headcap by placing the recording interface on top of the skull at a distance from the optrode and sealed to the skull using dental acrylic. Recording electrode ribbon cable and structural bone screws should be placed entirely under dental acrylic. A purse string suture is then placed around the headcap to facilitate healing. Figure was created using BioRender ( www.biorender.com ) under a publication license.

Journal: STAR Protocols

Article Title: Protocol for artificial intelligence-guided neural control using deep reinforcement learning and infrared neural stimulation

doi: 10.1016/j.xpro.2024.103496

Figure Lengend Snippet: Description of the implantation procedure (A) Situate the animal in a stereotaxic frame using hollow ear bars. (B) After contact sterilization, create an incision down midline to reveal cranial sutures. Create a craniectomy above MGB (−6 mm A.P., −3.5 mm M.L.). Place 4 bone screws equidistant around the MGB craniectomy. One bone screw (shown in gold) is a titanium bone screw to serve as recording electrode ground and reference. (C) Reflect the temporalis muscle over the cranial ridge and off the side of the skull. Care should be taken to prevent blunt dissection of the muscle. Accidental dissection of the muscle runs the risk of severing the supraorbital nerve, leading to inability to close eyelid after recovery. (D) Side profile of skull above A1. Create a 2 × 2 mm craniectomy above A1 by repeated thinning of skull around a square area. The skull flap can then be removed using a micro Friedman rongeur. (E) Gently remove the dura above A1 using a bent tip 25G needle. Dura can be seen as a reflective membrane which can be gently hooked by the needle. Once hooked, the dura can be removed by gently pulling the needle away from the brain. (F) Tie electrode ground and reference wire to the titanium bone screw using Teflon tweezers. Suture knots should be made to ensure wires make solid contact with the bone screw. (G) Place the recording electrode at 500 μ m into A1. Start applying Gaussian noise burst stimuli to the contralateral ear through the hollow ear bars. Slowly advance the array until consistent, low latency multiunit responses are seen on some of the recording electrodes. This is indicative of putative placement of the device into layer III/IV. (H) Seal recording electrode into place by first applying Kwik-Sil around the electrode to act as a dental sealant, followed by dental acrylic around the electrode. Note that Kwik-Sil only provides a loose connection, and the device should only be removed from electrode holder after dental acrylic has dried. (I) Implant the fiber optrode into the MGB (D.V. −6 mm). Connect the optrode to the stereotaxic frame and position the optrode above the surface of the brain. Slowly advance the optrode until the desired depth is reached. (J) Seal the optrode into place using dental acrylic. Complete the headcap by placing the recording interface on top of the skull at a distance from the optrode and sealed to the skull using dental acrylic. Recording electrode ribbon cable and structural bone screws should be placed entirely under dental acrylic. A purse string suture is then placed around the headcap to facilitate healing. Figure was created using BioRender ( www.biorender.com ) under a publication license.

Article Snippet: Titanium reference bone screw , Thomas RECORDING , AN000583.

Techniques: Dissection, Membrane

Journal: STAR Protocols

Article Title: Protocol for artificial intelligence-guided neural control using deep reinforcement learning and infrared neural stimulation

doi: 10.1016/j.xpro.2024.103496

Figure Lengend Snippet:

Article Snippet: Titanium reference bone screw , Thomas RECORDING , AN000583.

Techniques: Recombinant, Software, Control, Microscopy