Santanu Majumder1, Amit Roychowdhury, Subrata Pal. 1. Dept. of Aerospace Engineering & Applied Mechanics, Bengal Engineering and Science University, Shibpur, Howrah 711103, West Bengal, India. Electronic address: majumder.santanu@gmail.com.
Abstract
BACKGROUND: Hip fracture depends on various anthropometric parameters such as trochanteric soft tissue thickness, body height and body weight. The objective was to evaluate the responses to the variations in anthropometric parameters during sideways fall, and to identify the most dominant parameter among them. METHOD: Seven finite element models were developed having anthropometric variations in trochanteric soft tissue thickness (5-26 mm), body height (1.70-1.88 m), and body weight (63-93.37 kg). These were simulated for sideways fall with ANSYS-LS-DYNA® code. FINDINGS: Significant effect of trochanteric soft tissue thickness variation was found on 'normalized peak impact force with respect to the body weight' (p=0.004, r²=0.808) and strain ratio (p=0.083, r²=0.829). But, variation in body height was found to be less significant on normalized peak impact force (p=0.478, r²=0.105) and strain ratio (p=0.292, r²=0.217). Same was true for the variation in body weight on normalized peak impact force (p=0.075, r²=0.456) and strain ratio (p=0.857, r²=0.007). The risk factor for fracture was also well correlated to the strain ratio for the inter-trochanteric zone (p<0.0007, r²=0.917) where the most fractures are clinically observed to happen. INTERPRETATIONS: Trochanteric soft tissue thickness was found likely to be the most dominant parameter over body height and body weight, signifying that a slimmer elderly person, taller or shorter, with less trochanteric soft tissue thickness should be advised to take preventive measures against hip fracture under sideways fall.
BACKGROUND:Hip fracture depends on various anthropometric parameters such as trochanteric soft tissue thickness, body height and body weight. The objective was to evaluate the responses to the variations in anthropometric parameters during sideways fall, and to identify the most dominant parameter among them. METHOD: Seven finite element models were developed having anthropometric variations in trochanteric soft tissue thickness (5-26 mm), body height (1.70-1.88 m), and body weight (63-93.37 kg). These were simulated for sideways fall with ANSYS-LS-DYNA® code. FINDINGS: Significant effect of trochanteric soft tissue thickness variation was found on 'normalized peak impact force with respect to the body weight' (p=0.004, r²=0.808) and strain ratio (p=0.083, r²=0.829). But, variation in body height was found to be less significant on normalized peak impact force (p=0.478, r²=0.105) and strain ratio (p=0.292, r²=0.217). Same was true for the variation in body weight on normalized peak impact force (p=0.075, r²=0.456) and strain ratio (p=0.857, r²=0.007). The risk factor for fracture was also well correlated to the strain ratio for the inter-trochanteric zone (p<0.0007, r²=0.917) where the most fractures are clinically observed to happen. INTERPRETATIONS: Trochanteric soft tissue thickness was found likely to be the most dominant parameter over body height and body weight, signifying that a slimmer elderly person, taller or shorter, with less trochanteric soft tissue thickness should be advised to take preventive measures against hip fracture under sideways fall.
Authors: S K Gratza; P O Chocano-Bedoya; E J Orav; M Fischbacher; G Freystätter; R Theiler; A Egli; R W Kressig; J A Kanis; H A Bischoff-Ferrari Journal: Osteoporos Int Date: 2019-08-03 Impact factor: 4.507
Authors: Ingmar Fleps; William S Enns-Bray; Pierre Guy; Stephen J Ferguson; Peter A Cripton; Benedikt Helgason Journal: PLoS One Date: 2018-08-16 Impact factor: 3.240
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