Angela Thompson1, Gina Bertocci2, Craig Smalley3. 1. Department of Engineering Fundamentals, University of Louisville, Louisville, KY, USA. Electronic address: Angela.thompson@louisville.edu. 2. Department of Bioengineering, University of Louisville, Louisville, KY, USA. Electronic address: g.bertocci@louisville.edu. 3. Department of Bioengineering, University of Louisville, Louisville, KY, USA. Electronic address: cssmal01@louisville.edu.
Abstract
BACKGROUND: Femur fractures are a common orthopedic injury in young children. Falls account for a large portion of accidental femur fractures in young children, but there is also a high prevalence of femur fractures in child abuse, with falls often provided as false histories. Objective information regarding fracture potential in short distance fall scenarios may aid in assessing whether a child's injuries are the result of abuse or an accidental fall. Knowledge of femur loading is the first step towards understanding likelihood of fracture in a fall. OBJECTIVE: Characterize femur loading during feet-first free falls using a surrogate representing a 12-month-old child. METHODS: The femur and hip joint of a surrogate representing a 12-month-old were modified to improve biofidelity and measure femur loading; 6-axis load cells were integrated into the proximal and distal femur. Femur modification was based upon CT imaging of cadaveric femurs in children 10-14 months of age. Using the modified 12-month-old surrogate, feet-first free falls from 69 cm and 119 cm heights onto padded carpet and linoleum were conducted to assess fall dynamics and determine femur loading. Femur compression, bending moment, shear and torsional moment were measured for each fall. RESULTS: Fall dynamics differed across fall heights, but did not substantially differ by impact surface type. Significant differences were found in all loading conditions across fall heights, while only compression and bending loads differed between carpet and linoleum surfaces. Maximum compression, bending, torsion and shear occurred in 119 cm falls and were 572 N, 23 N-m, 11 N-m and 281 N, respectively. CONCLUSIONS: Fall dynamics play an important role in the biomechanical assessment of falls. Fall height was found to influence both fall dynamics and femur loading, while impact surface affected only compression and bending in feet-first falls; fall dynamics did not differ across carpet and linoleum. Improved pediatric thresholds are necessary to predict likelihood of fracture, but morphologically accurate representation of the lower extremity, along with accurate characterization of loading in falls are a crucial first step.
BACKGROUND:Femur fractures are a common orthopedic injury in young children. Falls account for a large portion of accidental femur fractures in young children, but there is also a high prevalence of femur fractures in child abuse, with falls often provided as false histories. Objective information regarding fracture potential in short distance fall scenarios may aid in assessing whether a child's injuries are the result of abuse or an accidental fall. Knowledge of femur loading is the first step towards understanding likelihood of fracture in a fall. OBJECTIVE: Characterize femur loading during feet-first free falls using a surrogate representing a 12-month-old child. METHODS: The femur and hip joint of a surrogate representing a 12-month-old were modified to improve biofidelity and measure femur loading; 6-axis load cells were integrated into the proximal and distal femur. Femur modification was based upon CT imaging of cadaveric femurs in children 10-14 months of age. Using the modified 12-month-old surrogate, feet-first free falls from 69 cm and 119 cm heights onto padded carpet and linoleum were conducted to assess fall dynamics and determine femur loading. Femur compression, bending moment, shear and torsional moment were measured for each fall. RESULTS: Fall dynamics differed across fall heights, but did not substantially differ by impact surface type. Significant differences were found in all loading conditions across fall heights, while only compression and bending loads differed between carpet and linoleum surfaces. Maximum compression, bending, torsion and shear occurred in 119 cm falls and were 572 N, 23 N-m, 11 N-m and 281 N, respectively. CONCLUSIONS: Fall dynamics play an important role in the biomechanical assessment of falls. Fall height was found to influence both fall dynamics and femur loading, while impact surface affected only compression and bending in feet-first falls; fall dynamics did not differ across carpet and linoleum. Improved pediatric thresholds are necessary to predict likelihood of fracture, but morphologically accurate representation of the lower extremity, along with accurate characterization of loading in falls are a crucial first step.
Authors: Gregory J Galano; Mark A Vitale; Michael W Kessler; Joshua E Hyman; Michael G Vitale Journal: J Pediatr Orthop Date: 2005 Jan-Feb Impact factor: 2.324
Authors: Ernest Deemer; Gina Bertocci; Mary Clyde Pierce; Fernando Aguel; Janine Janosky; Ev Vogeley Journal: Med Eng Phys Date: 2005-01 Impact factor: 2.242
Authors: Gina E Bertocci; Mary Clyde Pierce; Ernest Deemer; Fernando Aguel; Janine E Janosky; Eva Vogeley Journal: Injury Date: 2004-04 Impact factor: 2.586