Abstract
Sufficient implant anchoring in osteoporotic bone is one major challenge in trauma and orthopedic surgery. In these cases, preoperative planning of osteosynthesis is becoming increasingly important. This study presents the development and first biomechanical validation of a bone-implant-anchorage score based on clinical routine quantitative computer tomography (qCT) scans. 10 pairs of fresh frozen femora (mean age 77.4 years) underwent clinical qCT scans after placing 3 referential screws (for matching with the second scan). Afterwards, three 4.5 mm cortical screws (DePuy Synthes, Zuchwil, Switzerland) were placed in each distal femur in the dia-metaphyseal transition followed by the second CT scan. The femur was segmented using thresholding and its outer shape was visualized as a surface model. A 3D model of the cortex screw in STL format was used to model the screw surface precisely. For each femur, the 3 cortex screw models were exactly positioned at the locations previously determined using the second CT scan. The BMD value was calculated at the center of each triangle as an interpolation from the measured values at the three vertices (triangle corners) in the CT. Scores are based on the sum of all the triangles’ areas multiplied by their BMD values. Four different scores were calculated. A screw pull-out test was performed until loss of resistance. A quadratic model adequately describes the relation between all the scores and pull-out values. The square of the best score explains just fewer than 70% of the total variance of the pull-out values and the standardized residual which were approximately normally distributed. In addition, there was a significant correlation between this score and the peak pull-out force (p < 0.001). The coefficient of determination was 0.82. The presented score has the potential to improve preoperative planning by adding the mechanical to the anatomical dimension when planning screw placement.
Highlights
Sufficient implant anchoring in osteoporotic bone is one major challenge in trauma and orthopedic surgery
The aim of this study was the development and a first biomechanical validation of a bone-implantanchorage score based on clinical routine quantitative computer tomography scans of the distal femur
The lower Akaikes information criterion (AIC) was found for the bone mineral density (BMD) score based on the weighted sum of the 0.6 mm sphere (Score_0.6w, Fig. 6)
Summary
Sufficient implant anchoring in osteoporotic bone is one major challenge in trauma and orthopedic surgery. This study presents the development and first biomechanical validation of a bone-implant-anchorage score based on clinical routine quantitative computer tomography (qCT) scans. Studies show that about 30% of excess mortality is directly attributable to the fracture event[1] In absolute terms, this means that in the EU5+ countries, approximately 34,000 deaths each year are caused by osteoporotic fractures[1]. The use of bone cement is associated with prolonged surgery time, as well as additional risks to the patient and increased health care costs Another problem of augmentation is the identification of patients who benefit from this measure. The aim of this study was the development and a first biomechanical validation of a bone-implantanchorage score based on clinical routine quantitative computer tomography (qCT) scans of the distal femur
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