The titanium alloy bypass locking screws (torx T-10 head) are designed to affix
The titanium alloy bypass locking screws (torx T-10 head) are designed to affix the plate to the bone using a similar design as the cortical locking screw, except that the screw head includes scallops that allow a second locking screw to be installed in the adjacent hole. The bypass locking screws are 2.7mm in diameter and are available in multiple lengths ranging from 10mm to 34mm
Drivers are of various tips and handle geometry and are made of stainless steel
Drivers are of various tips and handle geometry and are made of stainless steel that is heat treated and passivated. Driver assembly handles are made from machined Radel.
Caddies are assemblies of various layouts that hold screws and post of various l
Caddies are assemblies of various layouts that hold screws and post of various lengths and types. The base is of machined Polypropylene, and lids of Smoked Radel.
The titanium alloy bypass locking screws (torx T-10 head) are designed to affix
The titanium alloy bypass locking screws (torx T-10 head) are designed to affix the plate to the bone using a similar design as the cortical locking screw, except that the screw head includes scallops that allow a second locking screw to be installed in the adjacent hole. The bypass locking screws are 2.7mm in diameter and are available in multiple lengths ranging from 10mm to 34mm.
The titanium alloy cortical locking screws (torx T-10 head) are used to affix th
The titanium alloy cortical locking screws (torx T-10 head) are used to affix the plate to the bone. The screws are 2.7mm in diameter and are available in various lengths from 10mm to 34mm.
The titanium alloy cortical locking screws (torx T-10 head) are used to affix th
The titanium alloy cortical locking screws (torx T-10 head) are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 10mm to 45mm.
The titanium alloy cortical locking screws (torx T-10 head) are used to affix th
The titanium alloy cortical locking screws (torx T-10 head) are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 10mm to 45mm.
The titanium alloy cortical (non-locking) torx T-10 head screws are used to affi
The titanium alloy cortical (non-locking) torx T-10 head screws are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 10mm to 34mm.
The titanium alloy cortical (non-locking) torx T-10 head screws are used to affi
The titanium alloy cortical (non-locking) torx T-10 head screws are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 10mm to 34mm.
The titanium alloy cortical (non-locking) torx T-10 head screws are used to affi
The titanium alloy cortical (non-locking) torx T-10 head screws are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 10mm to 34mm.
Titanium alloy posts are used to affix the proximal end of the plate to the prox
Titanium alloy posts are used to affix the proximal end of the plate to the proximal end of the humerus. With the aid of fixtures, the posts have the ability to have cross elements inserted perpendicular to the axis of the cortical thread of the post. The head of the post is a threaded locking configuration that accepts an expansion cap screw. The posts are 5.25mm in diameter and are available in 5 lengths ranging from 30mm to 50mm. They are cannulated i.e a K-wire can pass through the post longitudinally.
The shoulder plates are made of titanium alloy and are designed in right and lef
The shoulder plates are made of titanium alloy and are designed in right and left configurations, as well as various length configurations. The plates are contoured to provide a close fit with the anatomy of the proximal humerus. The distal segment of the plate is provided with between 4 (73mm configuration) and 13 (220mm configuration) holes to accommodate 3.5mm diameter locking or non-locking cortical screws. The proximal segment of the plate has 2 locking screw holes and 3 locking post holes. Around the proximal end are also 4 suture clips.
The long bone plates are made of titanium alloy, are provided in standard and lo
The long bone plates are made of titanium alloy, are provided in standard and low profile thicknesses, and also standard and curved configurations. The plates are contoured to provide a close fit with the anatomy of the radius, ulna and humerus bones. The plates are provided with multiple hole configurations and lengths to accommodate fixation cases for a variety of upper extremity diaphyses.
Drill Bits are of various diameters and lengths, and are made of Stainless Steel
Drill Bits are of various diameters and lengths, and are made of Stainless Steel, heat-treated and passivated. Some drill bits have laser marked scales to show depth of drill.
The titanium alloy cortical screws are used to affix the plate to the humerus. T
The titanium alloy cortical screws are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 20mm to 34mm.
Guides are stainless steel parts of various designs that allow various drill dia
Guides are stainless steel parts of various designs that allow various drill diameters. Some guides are laser weld assemblies with a handle, and others are threaded to screw into plates.
Guides are stainless steel parts of various designs that allow various drill dia
Guides are stainless steel parts of various designs that allow various drill diameters. Some guides are laser weld assemblies with a handle, and others are threaded to screw into plates.
Titanium alloy posts are used to affix the proximal end of the plate to the prox
Titanium alloy posts are used to affix the proximal end of the plate to the proximal end of the humerus. With the aid of fixtures, the posts have the ability to have cross elements inserted perpendicular to the axis of the cortical thread of the post. The head of the post is a threaded locking configuration that accepts an expansion cap screw. The posts are 5.25mm in diameter and are available in 5 lengths ranging from 30mm to 50mm.
Titanium alloy cross elements are designed to provide additional support to the
Titanium alloy cross elements are designed to provide additional support to the humeral head by entering the posts perpendicular to the axis of the cortical thread of the posts.
Titanium alloy cross elements are designed to provide additional support to the
Titanium alloy cross elements are designed to provide additional support to the humeral head by entering the posts perpendicular to the axis of the cortical thread of the posts.
The titanium alloy cortical screws are used to affix the plate to the humerus. T
The titanium alloy cortical screws are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 20mm to 34mm.
The titanium alloy cortical locking screws are used to affix the plate to the hu
The titanium alloy cortical locking screws are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 20mm to 45mm.
The titanium alloy bypass locking screws (torx T-10 head) are designed to affix
The titanium alloy bypass locking screws (torx T-10 head) are designed to affix the plate to the bone using a similar design as the cortical locking screw, except that the screw head includes scallops that allow a second locking screw to be installed in the adjacent hole. The bypass locking screws are 2.7mm in diameter and are available in multiple lengths ranging from 10mm to 34mm
The titanium alloy bypass locking screws (torx T-10 head) are designed to affix
The titanium alloy bypass locking screws (torx T-10 head) are designed to affix the plate to the bone using a similar design as the cortical locking screw, except that the screw head includes scallops that allow a second locking screw to be installed in the adjacent hole. The bypass locking screws are 2.7mm in diameter and are available in multiple lengths ranging from 10mm to 34mm.
The titanium alloy bypass locking screws (torx T-10 head) are designed to affix
The titanium alloy bypass locking screws (torx T-10 head) are designed to affix the plate to the bone using a similar design as the cortical locking screw, except that the screw head includes scallops that allow a second locking screw to be installed in the adjacent hole. The bypass locking screws are 2.7mm in diameter and are available in multiple lengths ranging from 10mm to 34mm.
The titanium alloy cortical locking screws (torx T-10 head) are used to affix th
The titanium alloy cortical locking screws (torx T-10 head) are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 10mm to 45mm.
The titanium alloy cortical locking screws (torx T-10 head) are used to affix th
The titanium alloy cortical locking screws (torx T-10 head) are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 10mm to 45mm.
The titanium alloy cortical (non-locking) torx T-10 head screws are used to affi
The titanium alloy cortical (non-locking) torx T-10 head screws are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 10mm to 34mm.
The titanium alloy cortical (non-locking) torx T-10 head screws are used to affi
The titanium alloy cortical (non-locking) torx T-10 head screws are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 10mm to 34mm.
Titanium alloy posts are used to affix the proximal end of the plate to the prox
Titanium alloy posts are used to affix the proximal end of the plate to the proximal end of the humerus. With the aid of fixtures, the posts have the ability to have cross elements inserted perpendicular to the axis of the cortical thread of the post. The head of the post is a threaded locking configuration that accepts an expansion cap screw. The posts are 5.25mm in diameter and are available in 5 lengths ranging from 30mm to 50mm. They are cannulated i.e a K-wire can pass through the post longitudinally.
Drill Bits are of various diameters and lengths, and are made of Stainless Steel
Drill Bits are of various diameters and lengths, and are made of Stainless Steel, heat-treated and passivated. Some drill bits have laser marked scales to show depth of drill.
The long bone plates are made of titanium alloy, are provided in standard and lo
The long bone plates are made of titanium alloy, are provided in standard and low profile thicknesses, and also standard and curved configurations. The plates are contoured to provide a close fit with the anatomy of the radius, ulna and humerus bones. The plates are provided with multiple hole configurations and lengths to accommodate fixation cases for a variety of upper extremity diaphyses.
The long bone plates are made of titanium alloy, are provided in standard and lo
The long bone plates are made of titanium alloy, are provided in standard and low profile thicknesses, and also standard and curved configurations. The plates are contoured to provide a close fit with the anatomy of the radius, ulna and humerus bones. The plates are provided with multiple hole configurations and lengths to accommodate fixation cases for a variety of upper extremity diaphyses.
The long bone plates are made of titanium alloy, are provided in standard and lo
The long bone plates are made of titanium alloy, are provided in standard and low profile thicknesses, and also standard and curved configurations. The plates are contoured to provide a close fit with the anatomy of the radius, ulna and humerus bones. The plates are provided with multiple hole configurations and lengths to accommodate fixation cases for a variety of upper extremity diaphyse
Drill Bits are of various diameters and lengths, and are made of Stainless Steel
Drill Bits are of various diameters and lengths, and are made of Stainless Steel, heat-treated and passivated. Some drill bits have laser marked scales to show depth of drill.
The shoulder plates are made of titanium alloy and are designed in right and lef
The shoulder plates are made of titanium alloy and are designed in right and left configurations, as well as various length configurations. The plates are contoured to provide a close fit with the anatomy of the proximal humerus. The distal segment of the plate is provided with between 4 (73mm configuration) and 13 (220mm configuration) holes to accommodate 3.5mm diameter locking or non-locking cortical screws. The proximal segment of the plate has 2 locking screw holes and 3 locking post holes. Around the proximal end are also 4 suture clips.
The shoulder plates are made of titanium alloy and are designed in right and lef
The shoulder plates are made of titanium alloy and are designed in right and left configurations, as well as various length configurations. The plates are contoured to provide a close fit with the anatomy of the proximal humerus. The distal segment of the plate is provided with between 4 (73mm configuration) and 13 (220mm configuration) holes to accommodate 3.5mm diameter locking or non-locking cortical screws. The proximal segment of the plate has 2 locking screw holes and 3 locking post holes. Around the proximal end are also 4 suture clips.
Guides are stainless steel parts of various designs that allow various drill dia
Guides are stainless steel parts of various designs that allow various drill diameters. Some guides are laser weld assemblies with a handle, and others are threaded to screw into plates.
The titanium alloy cortical locking screws are used to affix the plate to the hu
The titanium alloy cortical locking screws are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 20mm to 45mm.
The titanium alloy cortical locking screws are used to affix the plate to the hu
The titanium alloy cortical locking screws are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 20mm to 45mm.
The titanium alloy cortical locking screws are used to affix the plate to the hu
The titanium alloy cortical locking screws are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 20mm to 45mm.
The titanium alloy bypass locking screws (torx T-10 head) are designed to affix
The titanium alloy bypass locking screws (torx T-10 head) are designed to affix the plate to the bone using a similar design as the cortical locking screw, except that the screw head includes scallops that allow a second locking screw to be installed in the adjacent hole. The bypass locking screws are 2.7mm in diameter and are available in multiple lengths ranging from 10mm to 34mm.
Guides are stainless steel parts of various designs that allow various drill dia
Guides are stainless steel parts of various designs that allow various drill diameters. Some guides are laser weld assemblies with a handle, and others are threaded to screw into plates.
The titanium alloy bypass locking screws (torx T-10 head) are designed to affix
The titanium alloy bypass locking screws (torx T-10 head) are designed to affix the plate to the bone using a similar design as the cortical locking screw, except that the screw head includes scallops that allow a second locking screw to be installed in the adjacent hole. The bypass locking screws are 2.7mm in diameter and are available in multiple lengths ranging from 10mm to 34mm.
The titanium alloy cortical locking screws (torx T-10 head) are used to affix th
The titanium alloy cortical locking screws (torx T-10 head) are used to affix the plate to the bone. The screws are 2.7mm in diameter and are available in various lengths from 10mm to 34mm.
The titanium alloy cortical locking screws (torx T-10 head) are used to affix th
The titanium alloy cortical locking screws (torx T-10 head) are used to affix the plate to the bone. The screws are 2.7mm in diameter and are available in various lengths from 10mm to 34mm.
The titanium alloy cortical locking screws (torx T-10 head) are used to affix th
The titanium alloy cortical locking screws (torx T-10 head) are used to affix the plate to the bone. The screws are 2.7mm in diameter and are available in various lengths from 10mm to 34mm.
The titanium alloy cortical (non-locking) torx T-10 head screws are used to affi
The titanium alloy cortical (non-locking) torx T-10 head screws are used to affix the plate to the humerus. The screws are 3.5mm diameter and are available in various lengths from 10mm to 34mm.
The Integra Titanium Bone Wedges are a series of wedge-shaped devices intended t
The Integra Titanium Bone Wedges are a series of wedge-shaped devices intended to be used for angular correction of small bones in the ankle and foot. The Integra Titanium Bone Wedges are constructed from commercially pure titanium formed into a cancellous-like structure. Trial Cotton 20 X 6.5
The Integra® Titanium Cotton Wedge Trials are inserted until the footprint is co
The Integra® Titanium Cotton Wedge Trials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra® Titanium Cotton Wedge Trials are inserted until the footprint is co
The Integra® Titanium Cotton Wedge Trials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra® Titanium Cotton Wedge Trials are inserted until the footprint is co
The Integra® Titanium Cotton Wedge Trials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra® Titanium Cotton Wedge Trials are inserted until the footprint is co
The Integra® Titanium Cotton Wedge Trials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra® Titanium Cotton Wedge Trials are inserted until the footprint is co
The Integra® Titanium Cotton Wedge Trials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congr
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congr
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congr
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congr
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congr
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congr
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congr
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congr
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congr
The Integra® Titanium Bone WedgeTrials are inserted until the footprint is congruent to the dimensions of the osteotomy surface, and the desired amount of correction is achieved. The trial is to confirm that the implanted wedge will be congruent with the osteotomy surface to provide the most optimal site for ingrowth of bone into the wedge.
The Integra Titanium Bone Wedge is intended to be used for internal bone fixatio
The Integra Titanium Bone Wedge is intended to be used for internal bone fixation for bone fractures or osteotomies in the ankle and foot. This set includes LCL trials and cotton trials to evaluate proper size and fit of the implants. A wedge inserter and tamp are also included for assistance.
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixa
The Integra® Titanium Bone Wedges are intended to be used for internal bone fixation for bone fracturesor osteotomies in the ankle and foot
The Integra Total Foot System interpositioning plate is used to space apart two
The Integra Total Foot System interpositioning plate is used to space apart two bones or a joint. The plate is anatomically T-shaped with increased width and stem depth for ease of insertion and less intraoperative contouring required.
The Integra Total Foot System interpositioning plate is used to space apart two
The Integra Total Foot System interpositioning plate is used to space apart two bones or a joint. The plate is anatomically T-shaped with increased width and stem depth for ease of insertion and less intraoperative contouring required.
The non-locking partial threaded screw is made from stainless steel and is used
The non-locking partial threaded screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The non-locking partial threaded screw is made from stainless steel and is used
The non-locking partial threaded screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The non-locking partial threaded screw is made from stainless steel and is used
The non-locking partial threaded screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The non-locking partial threaded screw is made from stainless steel and is used
The non-locking partial threaded screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The non-locking partial threaded screw is made from stainless steel and is used
The non-locking partial threaded screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The non-locking partial threaded screw is made from stainless steel and is used
The non-locking partial threaded screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The non-locking partial threaded screw is made from stainless steel and is used
The non-locking partial threaded screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The non-locking partial threaded screw is made from stainless steel and is used
The non-locking partial threaded screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The locking screw is made from stainless steel and is used in conjunction with t
The locking screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The locking screw is made from stainless steel and is used in conjunction with t
The locking screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The locking screw is made from stainless steel and is used in conjunction with t
The locking screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The locking screw is made from stainless steel and is used in conjunction with t
The locking screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The locking screw is made from stainless steel and is used in conjunction with t
The locking screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The locking screw is made from stainless steel and is used in conjunction with t
The locking screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.
The locking screw is made from stainless steel and is used in conjunction with t
The locking screw is made from stainless steel and is used in conjunction with the Integra Proximal Humeral Fracture Plate System.