Straightforward, safe, and efficient interlocking screw insertion during intramedullary nailing using a Steinmann pin and hammer: a comparative study

Abstract

Objectives: Accurately targeting distal nail holes and placing distal interlocking screws pose challenges during intramedullary nailing. This study proposes a straightforward technique for distal locking screw insertion using a Steinmann pin, eliminating the need to reposition the pin or drill bit. Methods: We utilized 18 Sawbones femur models and intramedullary femur nails. A first-year resident created two distal locking holes on each model, employing both the conventional freehand technique and a novel method involving a Steinmann pin and hammer under image intensification. These techniques were evaluated based on three parameters: (1) the time required to create distal locking holes, measured from the moment the pin was positioned at the center of the hole until the far cortex was drilled through the interlocking hole; (2) the radiation dose (in mrem/h), as estimated with a personal gamma radiation dosimeter; and (3) the number of failures, defined as the creation of more than one hole in the near and far cortex. Results: The new technique was associated with a lower radiation dose (P=0.0268) and fewer failures (P=0.0367) than the conventional approach. Additionally, the time required to establish distal holes was shorter using the new technique compared to the conventional method (P=0.0217). Conclusion: The creation of distal interlocking holes with a Steinmann pin and hammer is accurate, efficient, and cost-effective.