Design Features
The Kaufmann Total Elbow (KTE) arthroplasty is not cemented and uses intramedullary screws to gain purchase into the threaded intramedullary canals of the humerus and ulna. One cross locking screw in the humerus and two screws in ulna augment the construct’s stability.
In distinction to semiconstrained implants, this design does not exhibit a direct mechanical pin linkage between the humeral and ulnar components. The snap fit hinge employs laxity that allows for varus and valgus deviation while also providing proprioceptive feedback to the surgeon when implanting the components as it was designed to mimic the capsule that surrounds the elbow.
Elbow stability is derived from the ligament reconstruction, which is designed to transmit forces between the humerus and ulna and aims to mimic the primary static stabilizers of the elbow. The medial and lateral collateral ligaments are considered essential stabilizers and are reconstructed during implantation of this total elbow arthroplasty.
This uncemented elbow replacement requires osseointegration for the bone to secure the implant. Because this arthroplasty design is stabilized with a ligament reconstruction, ligament incorporation into bone is also required. While both of these processes happen, elbow replacements will face biomechanical challenges and this healing environment needs to be protected with a hinged brace and activity modification. We believe that substantial ligament healing will occur in three months and that bone incorporation will occur before that.Humeral Body Component Implantation
Five different diameter drill bits will accommodate the variability in the inner diameter of the intramedullary canal. Custom drill bits were created that have a smooth leading (cutting) edge that aims to not engage the cortex. The drill head was designed to "find its way" within the intramedullary canal. The implant will use drill bit diameters of ¼”, 5/16”, Letter U drill (0.368”), 27/64”, and 17/32”, which will correspond to IM screws that have of 5/16-18, 3/8-16, 7/16-14, 1/2-13 and 5/8-11 threads. The smallest diameter drill bit is used first and then increasing diameter drill bits are utilized as needed. The drill needs to first find the intramedullary canal and then remove primarily cancellous bone. It is imperative that during drilling of the IM canal, the drill is not engaging too much bone. Once resistance is met, the drilling effort is halted.
If no chatter is appreciated with the smallest bit (¼”) then larger drill bits (5/16”, 0.368”, 27/64”, 17/32”) are used until chatter is felt. Once the last drill bit has been employed that reaches the inner wall of the intramedullary canal the larger diameter drill bit is replaced with the 5/16” diameter drill bit, which now acts as a guide. The 5/16” diameter drill bit is advanced roughly 4” within the IM canal of the humeral shaft and acts as a determinant of the location for the long axis of the humeral shaft.
The centerline of rotation is addressed in the next step. The center of the capitellum is used on the lateral side. The anterior inferior aspect of the medial epicondyle is used as a reference on the medial side. K-wires are drilled into bone ensuring that they do not interfere with the intramedullary drill bit.
At this stage, the centerline of the intramedullary canal of the humeral shaft as well as the centerline of ulnohumeral rotation has been identified. Successful implantation relies on accurate characterization of these anatomical landmarks as the subsequent steps use these features as guides for cutting efforts.
The distal humerus should have a 5/16” diameter drill bit that is advanced within the intramedullary canal as well as two K-wires along the centerline of ulnohumeral rotation. It is important that K - wire tips are not too close to the IM drill bit to avoid damage to the K - wires during subesequent bone cutting.Three custom cutting guides were designed to match the dimensions of the three sizes (S, M, L) of the distal humerus body components. Each cutting guide incorporates a hole for the IM drill bit that is located within the humeral shaft. On each sides are holes that accommodate 0.45 K - wires that are placed by the implanting surgeon and used to aid in the parallelism of this cutting guide with the K - wires within the distal humerus along the centerline of ulnohumeral rotation.
The next step involves placing the cutting block in line with the intramedullary drill bit. The medial and lateral K - wires that were placed in holes within the cutting block assist with ensuring proper alignment. The cutting block K-wires are then used to rotate the block so that its K - wires are parallel with the ulnohumeral centerline of rotation K-wires that were drilled into bone.
tetext hereadd
The cutting block dimensions are identical to the outside of the humeral body component. The cutting block is placed so that the grooves in the block line up with the medial and lateral K-wires denoting the centerline of rotation. as well as the long axis of the intramedullary drill bit. It must be verified that, when the cutting block is correctly positioned, medial and lateral bone is present on each side of the cutting guide. If that is not the case then a smaller implant size must be placed.The guide plate is placed on the anterior flat surface. The plate has a cross in the middle, which is used to visually align the IM axis of the humeral shaft and the K-wires that denote the centerline of ulnohumeral rotation. The distal holes are marked with a pen, which denote the distal extent of the sagittal saw cutting effort.
Ulnar Body Component Implantation.
Custom designed taps create threads within the IM canal of the ulna. The shaft diameter is designed so that a Synthes adjustable T handle chuck can be used and advanced along the shaft to create handle fixation at variable distances from the working end of the tap. The shaft has measurement notches that allow for visual assessment of how far the tap has progressed.
A rotary ulnar broach was designed that would match the geometry of the polyethylene. It is attached to a drill and removes only bone that is needed to properly seat this component. In this process, the broach is rotated and pressed into the olecranon to cut an axisymmetric shape. The cut depth governed by the application of pressure by the surgeon while the rotary broach is spinning.
A hand held screw driver gains purchase into the head of the screw and then, with screw rotation, the advancing screw pulls the implant into a sturdy location within the proximal ulna. The implant will seat itself as it is pulled by the advancing IM screw. The ulnar body component exhibits a wedge shape, which will create significant hoop forces during implantation. IM screw tightening advances the implant and must occur without using substantial torque so as to prevent an ulna fracture. Rasping and broaching efforts must ensure that the body seats fully within the proximal ulna prior to IM screw tightening so that hoop stresses are minimized as the implant is advanced.
The groove within the polyethylene allows for the 7 degree valgus alignment that is necessary for maintenance of the carrying angle. Ultra-high-molecular-weight polyethylene (UHMWPE) is a high-modulus polyethylene with extremely long chains. The longer chain serves to transfer load more effectively to the polymer backbone by strengthening intermolecular interactions. This results in a very tough material with one of the highest impact strengths of any thermoplastic material.
Design Features
The Kaufmann Total Elbow (KTE) arthroplasty is not cemented and uses intramedullary screws to gain purchase into the threaded intramedullary canals of the humerus and ulna. One cross locking screw in the humerus and two screws in ulna augment the construct’s stability.
In distinction to semiconstrained implants, this design does not exhibit a direct mechanical pin linkage between the humeral and ulnar components. The snap fit hinge employs laxity that allows for varus and valgus deviation while also providing proprioceptive feedback to the surgeon when implanting the components as it was designed to mimic the capsule that surrounds the elbow.
Elbow stability is derived from the ligament reconstruction, which is designed to transmit forces between the humerus and ulna and aims to mimic the primary static stabilizers of the elbow. The medial and lateral collateral ligaments are considered essential stabilizers and are reconstructed during implantation of this total elbow arthroplasty.
This uncemented elbow replacement requires osseointegration for the bone to secure the implant. Because this arthroplasty design is stabilized with a ligament reconstruction, ligament incorporation into bone is also required. While both of these processes happen, elbow replacements will face biomechanical challenges and this healing environment needs to be protected with a hinged brace and activity modification. We believe that substantial ligament healing will occur in three months and that bone incorporation will occur before that.Humeral Body Component Implantation
Five different diameter drill bits will accommodate the variability in the inner diameter of the intramedullary canal. Custom drill bits were created that have a smooth leading (cutting) edge that aims to not engage the cortex. The drill head was designed to "find its way" within the intramedullary canal. The implant will use drill bit diameters of ¼”, 5/16”, Letter U drill (0.368”), 27/64”, and 17/32”, which will correspond to IM screws that have of 5/16-18, 3/8-16, 7/16-14, 1/2-13 and 5/8-11 threads. The smallest diameter drill bit is used first and then increasing diameter drill bits are utilized as needed. The drill needs to first find the intramedullary canal and then remove primarily cancellous bone. It is imperative that during drilling of the IM canal, the drill is not engaging too much bone. Once resistance is met, the drilling effort is halted.
If no chatter is appreciated with the smallest bit (¼”) then larger drill bits (5/16”, 0.368”, 27/64”, 17/32”) are used until chatter is felt. Once the last drill bit has been employed that reaches the inner wall of the intramedullary canal the larger diameter drill bit is replaced with the 5/16” diameter drill bit, which now acts as a guide. The 5/16” diameter drill bit is advanced roughly 4” within the IM canal of the humeral shaft and acts as a determinant of the location for the long axis of the humeral shaft.
The centerline of rotation is addressed in the next step. The center of the capitellum is used on the lateral side. The anterior inferior aspect of the medial epicondyle is used as a reference on the medial side. K-wires are drilled into bone ensuring that they do not interfere with the intramedullary drill bit.
At this stage, the centerline of the intramedullary canal of the humeral shaft as well as the centerline of ulnohumeral rotation has been identified. Successful implantation relies on accurate characterization of these anatomical landmarks as the subsequent steps use these features as guides for cutting efforts.
The distal humerus should have a 5/16” diameter drill bit that is advanced within the intramedullary canal as well as two K-wires along the centerline of ulnohumeral rotation. It is important that K - wire tips are not too close to the IM drill bit to avoid damage to the K - wires during subesequent bone cutting.Three custom cutting guides were designed to match the dimensions of the three sizes (S, M, L) of the distal humerus body components. Each cutting guide incorporates a hole for the IM drill bit that is located within the humeral shaft. On each sides are holes that accommodate 0.45 K - wires that are placed by the implanting surgeon and used to aid in the parallelism of this cutting guide with the K - wires within the distal humerus along the centerline of ulnohumeral rotation.
The next step involves placing the cutting block in line with the intramedullary drill bit. The medial and lateral K - wires that were placed in holes within the cutting block assist with ensuring proper alignment. The cutting block K-wires are then used to rotate the block so that its K - wires are parallel with the ulnohumeral centerline of rotation K-wires that were drilled into bone.
tetext hereadd
The cutting block dimensions are identical to the outside of the humeral body component. The cutting block is placed so that the grooves in the block line up with the medial and lateral K-wires denoting the centerline of rotation. as well as the long axis of the intramedullary drill bit. It must be verified that, when the cutting block is correctly positioned, medial and lateral bone is present on each side of the cutting guide. If that is not the case then a smaller implant size must be placed.The guide plate is placed on the anterior flat surface. The plate has a cross in the middle, which is used to visually align the IM axis of the humeral shaft and the K-wires that denote the centerline of ulnohumeral rotation. The distal holes are marked with a pen, which denote the distal extent of the sagittal saw cutting effort.
Ulnar Body Component Implantation.
Custom designed taps create threads within the IM canal of the ulna. The shaft diameter is designed so that a Synthes adjustable T handle chuck can be used and advanced along the shaft to create handle fixation at variable distances from the working end of the tap. The shaft has measurement notches that allow for visual assessment of how far the tap has progressed.
A rotary ulnar broach was designed that would match the geometry of the polyethylene. It is attached to a drill and removes only bone that is needed to properly seat this component. In this process, the broach is rotated and pressed into the olecranon to cut an axisymmetric shape. The cut depth governed by the application of pressure by the surgeon while the rotary broach is spinning.
A hand held screw driver gains purchase into the head of the screw and then, with screw rotation, the advancing screw pulls the implant into a sturdy location within the proximal ulna. The implant will seat itself as it is pulled by the advancing IM screw. The ulnar body component exhibits a wedge shape, which will create significant hoop forces during implantation. IM screw tightening advances the implant and must occur without using substantial torque so as to prevent an ulna fracture. Rasping and broaching efforts must ensure that the body seats fully within the proximal ulna prior to IM screw tightening so that hoop stresses are minimized as the implant is advanced.
The groove within the polyethylene allows for the 7 degree valgus alignment that is necessary for maintenance of the carrying angle. Ultra-high-molecular-weight polyethylene (UHMWPE) is a high-modulus polyethylene with extremely long chains. The longer chain serves to transfer load more effectively to the polymer backbone by strengthening intermolecular interactions. This results in a very tough material with one of the highest impact strengths of any thermoplastic material.
Design Features
The Kaufmann Total Elbow (KTE) arthroplasty is not cemented and uses intramedullary screws to gain purchase into the threaded intramedullary canals of the humerus and ulna. One cross locking screw in the humerus and two screws in ulna augment the construct’s stability.
In distinction to semiconstrained implants, this design does not exhibit a direct mechanical pin linkage between the humeral and ulnar components. The snap fit hinge employs laxity that allows for varus and valgus deviation while also providing proprioceptive feedback to the surgeon when implanting the components as it was designed to mimic the capsule that surrounds the elbow.
Elbow stability is derived from the ligament reconstruction, which is designed to transmit forces between the humerus and ulna and aims to mimic the primary static stabilizers of the elbow. The medial and lateral collateral ligaments are considered essential stabilizers and are reconstructed during implantation of this total elbow arthroplasty.
This uncemented elbow replacement requires osseointegration for the bone to secure the implant. Because this arthroplasty design is stabilized with a ligament reconstruction, ligament incorporation into bone is also required. While both of these processes happen, elbow replacements will face biomechanical challenges and this healing environment needs to be protected with a hinged brace and activity modification. We believe that substantial ligament healing will occur in three months and that bone incorporation will occur before that.Humeral Body Component Implantation
Five different diameter drill bits will accommodate the variability in the inner diameter of the intramedullary canal. Custom drill bits were created that have a smooth leading (cutting) edge that aims to not engage the cortex. The drill head was designed to "find its way" within the intramedullary canal. The implant will use drill bit diameters of ¼”, 5/16”, Letter U drill (0.368”), 27/64”, and 17/32”, which will correspond to IM screws that have of 5/16-18, 3/8-16, 7/16-14, 1/2-13 and 5/8-11 threads. The smallest diameter drill bit is used first and then increasing diameter drill bits are utilized as needed. The drill needs to first find the intramedullary canal and then remove primarily cancellous bone. It is imperative that during drilling of the IM canal, the drill is not engaging too much bone. Once resistance is met, the drilling effort is halted.
If no chatter is appreciated with the smallest bit (¼”) then larger drill bits (5/16”, 0.368”, 27/64”, 17/32”) are used until chatter is felt. Once the last drill bit has been employed that reaches the inner wall of the intramedullary canal the larger diameter drill bit is replaced with the 5/16” diameter drill bit, which now acts as a guide. The 5/16” diameter drill bit is advanced roughly 4” within the IM canal of the humeral shaft and acts as a determinant of the location for the long axis of the humeral shaft.
The centerline of rotation is addressed in the next step. The center of the capitellum is used on the lateral side. The anterior inferior aspect of the medial epicondyle is used as a reference on the medial side. K-wires are drilled into bone ensuring that they do not interfere with the intramedullary drill bit.
At this stage, the centerline of the intramedullary canal of the humeral shaft as well as the centerline of ulnohumeral rotation has been identified. Successful implantation relies on accurate characterization of these anatomical landmarks as the subsequent steps use these features as guides for cutting efforts.
The distal humerus should have a 5/16” diameter drill bit that is advanced within the intramedullary canal as well as two K-wires along the centerline of ulnohumeral rotation. It is important that K - wire tips are not too close to the IM drill bit to avoid damage to the K - wires during subesequent bone cutting.Three custom cutting guides were designed to match the dimensions of the three sizes (S, M, L) of the distal humerus body components. Each cutting guide incorporates a hole for the IM drill bit that is located within the humeral shaft. On each sides are holes that accommodate 0.45 K - wires that are placed by the implanting surgeon and used to aid in the parallelism of this cutting guide with the K - wires within the distal humerus along the centerline of ulnohumeral rotation.
The next step involves placing the cutting block in line with the intramedullary drill bit. The medial and lateral K - wires that were placed in holes within the cutting block assist with ensuring proper alignment. The cutting block K-wires are then used to rotate the block so that its K - wires are parallel with the ulnohumeral centerline of rotation K-wires that were drilled into bone.
tetext hereadd
The cutting block dimensions are identical to the outside of the humeral body component. The cutting block is placed so that the grooves in the block line up with the medial and lateral K-wires denoting the centerline of rotation. as well as the long axis of the intramedullary drill bit. It must be verified that, when the cutting block is correctly positioned, medial and lateral bone is present on each side of the cutting guide. If that is not the case then a smaller implant size must be placed.The guide plate is placed on the anterior flat surface. The plate has a cross in the middle, which is used to visually align the IM axis of the humeral shaft and the K-wires that denote the centerline of ulnohumeral rotation. The distal holes are marked with a pen, which denote the distal extent of the sagittal saw cutting effort.
Ulnar Body Component Implantation.
Custom designed taps create threads within the IM canal of the ulna. The shaft diameter is designed so that a Synthes adjustable T handle chuck can be used and advanced along the shaft to create handle fixation at variable distances from the working end of the tap. The shaft has measurement notches that allow for visual assessment of how far the tap has progressed.
A rotary ulnar broach was designed that would match the geometry of the polyethylene. It is attached to a drill and removes only bone that is needed to properly seat this component. In this process, the broach is rotated and pressed into the olecranon to cut an axisymmetric shape. The cut depth governed by the application of pressure by the surgeon while the rotary broach is spinning.
A hand held screw driver gains purchase into the head of the screw and then, with screw rotation, the advancing screw pulls the implant into a sturdy location within the proximal ulna. The implant will seat itself as it is pulled by the advancing IM screw. The ulnar body component exhibits a wedge shape, which will create significant hoop forces during implantation. IM screw tightening advances the implant and must occur without using substantial torque so as to prevent an ulna fracture. Rasping and broaching efforts must ensure that the body seats fully within the proximal ulna prior to IM screw tightening so that hoop stresses are minimized as the implant is advanced.
The groove within the polyethylene allows for the 7 degree valgus alignment that is necessary for maintenance of the carrying angle. Ultra-high-molecular-weight polyethylene (UHMWPE) is a high-modulus polyethylene with extremely long chains. The longer chain serves to transfer load more effectively to the polymer backbone by strengthening intermolecular interactions. This results in a very tough material with one of the highest impact strengths of any thermoplastic material.