Abstract
Introduction
Conventional screws achieve sufficient insertion torque in healthy bone. In poor bone screw stripping can occur prior to sufficient torque generation. It was hypothesized that a screw with a larger major/minor diameter ratio would provide improved purchase in poor bone as compared to conventional screws. We evaluated the mechanical characteristics of such a screw using multiple poor bone quality models.
Methods
Testing groups included: conventional screws, osteopenia screws used in bail-out manner (ie, larger major/minor diameter screws inserted into a hole stripped by a conventional screw), and osteopenia screws used in a preemptive manner (ie, no screw stripping occurrence).
Stripping Torque: Screws were inserted through standard straight plates into a low density block of foam with a predrilled hole. Stripping torque was defined as maximum insertion torque reached by the screw before the screw began to spin freely in the foam.
Pullout
Pullout tests were conducted on screws inserted into the same test media. Axial pull-out testing was then conducted by applying a tensile load to the screws.
Compression
Screws were inserted through standard straight plates by hand while the amount of compression achieved between plate and bone was measured using a pressure sensor. The same foam test media was utilized in addition to osteoporotic fresh-frozen femoral diaphyseal cadaver (bone mineral density<0.60 g/cm2). The screws were tightened across a range of possible insertion torques with pressure measurements taken at multiple intervals.
Results
The osteopenia bone screws showed a 67% increase in torque before stripping occurred (p<0.01) when compared to the conventional screw. The osteopenia screw used in a bail-out manner showed a 57% increase in stripping torque (p<0.01) and a 76% increase in pullout strength (p<0.01) when compared to the conventional screw. Additionally, the bail-out screw showed a minimal decrease in both stripping torque (6%, p = 0.45) and pullout strength (11%, p<0.01) when compared to the osteopenia screw tested in preemptive manner. There was a linear relationship between applied torque and compressive force generation for both osteopenia and conventional screws. The osteopenia screws were able to gain greater compression against bone across a range of insertion values as compared to conventional bone screws.
Discussion
The osteopenia screw achieved superior stripping torque, pullout strength, and compressive forces when compared to conventional screws in simulated poor quality bone and osteoporotic cadaver bone. When used as a bail-out screw, it also achieved superior stripping torque and pullout strength. The results of this study indicate that a screw of larger major/minor diameter ratio could be an effective bail-out option for screw stripping associated with osteopenic fracture fixation.
