Plunging Dangerously: A Quantitative Assessment of Drilling the Clavicle.

Bicortical drilling of the clavicle is associated with risk of iatrogenic damage from plunging given the close proximity of neurovascular structures. This study determined plunge depth during superior-to-inferior clavicle drilling using a standard drill vs drill-sensing technology. Two orthopedic surgeons drilled 10 holes in a fresh cadaveric clavicle with drill-sensing technology in freehand mode (functions as standard orthopedic drill) and another 10 holes with drill-sensing technology in bicortical mode (drill motor stops when the second cortex is breached and depth is measured in real time).

Examination of fluoroscopy monitor as a source of indirect bacterial contamination in orthopaedic surgery.

Background: Surgical site infection is a well-documented complication of surgery. While contact with fomites represents a recognised source of contamination, electrostatic charge can cause contamination without surface contact as shown in previous studies evaluating operating room equipment. In cases requiring fluoroscopy, an intraoperative X-ray method, it is common for a surgeon to point to the associated monitor, particularly when teaching.

Automated pressure map segmentation for quantifying phalangeal kinetics during cylindrical gripping.

Inverse dynamics models used to investigate musculoskeletal disorders associated with handle gripping require accurate phalangeal kinetics. Cylindrical handles wrapped with pressure film grids have been used in studies of gripping kinetics. We present a method fusing six degree-of-freedom hand kinematics and a kinematic calibration of a cylinder-wrapped pressure film.

Inverse dynamic analysis of the biomechanics of the thumb while pipetting: a case study.

Thumb-push manual pipettes are commonly used tools in many medical, biological, and chemical laboratories. Epidemiological studies indicate that the use of thumb-push mechanical pipettes is associated with musculoskeletal disorders in the hand. The goal of the current study was to evaluate the kinematics and joint loading of the thumb during pipetting.

Kinematic performance of a six degree-of-freedom hand model (6DHand) for use in occupational biomechanics.

Upper extremity musculoskeletal disorders represent an important health issue across all industry sectors; as such, the need exists to develop models of the hand that provide comprehensive biomechanics during occupational tasks. Previous optical motion capture studies used a single marker on the dorsal aspect of finger joints, allowing calculation of one and two degree-of-freedom (DOF) joint angles; additional algorithms were needed to define joint centers and the palmar surface of fingers. We developed a 6DOF model (6DHand) to obtain unconstrained kinematics of finger segments, modeled as frusta of right circular cones that approximate the palmar surface.