Inflatable Hip Protectors

Falls and fall-related injuries are crucial health problems among older adults, and hip protectors are designed to reduce fall-related injuries in this population. This thesis explores the technology of inflatable hip protectors with the aim to provide insight for future designers and manufacturers of these devices. The thesis comprises two studies. In the first, a mathematical model of an inflatable hip protector is developed. For system identification, a prototype of an inflatable hip protector is fabricated, and tested with an electromagnetic shaker. In the second study, a pelvis release experimental configuration is investigated to determine the effectiveness of inflatable hip protectors compared with commercially available hip protectors. Results suggest that airbags of moderate size – 20 cm x 10 cm – provide over three times the force attenuation of current passive devices. These results support ongoing efforts to develop inflatable hip protectors for older adults who are at high risk for falls and hip fracture.

Keywords: Hip fracture; Inflatable hip protectors; Modelling; Biomechanical effectiveness

Year	Entry
1996	Pinilla TP, Boardman KC, Bouxsein ML, Myers ER, Hayes WC. Impact direction from a fall influences the failure load of the proximal femur as much as age-related bone loss. Calcif Tiss Int. April 1996;58(4):231-235.
1998	Kopperdahl DL, Keaveny TM. Yield strain behavior of trabecular bone. J Biomech. July 1998;31(7):601-608.
1990	Lotz JC, Gerhart TN, Hayes WC. Mechanical properties of trabecular bone from the proximal femur: a quantitative CT study. J Comput Assist Tomogr. January–February 1990;14(1):107-114.
1990	Lotz JC, Hayes WC. The use of quantitative computed tomography to estimate risk of fracture of the hip from falls. J Bone Joint Surg. June 1990;72A(5):689-700.
1996	Courtney AC, Hayes WC, Gibson LJ. Age-related differences in post-yield damage in human cortical bone: experiment and model. J Biomech. November 1996;29(11):1463-1471.
2008	Laing AC, Robinovitch SN. The force attenuation provided by hip protectors depends on impact velocity, pelvic size, and soft tissue stiffness. J Biomech Eng. December 2008;130(6):061005.
1994	Courtney AC, Wachtel EF, Myers ER, Hayes WC. Effects of loading rate on strength of the proximal femur. Calcif Tiss Int. 1994;55(1):53-58.
1995	Courtney AC, Wachtel EF, Myers ER, Hayes WC. Age-related reductions in the strength of the femur tested in a fall-loading configuration. J Bone Joint Surg. March 1995;77A(3):387-395.
1988	Tinetti ME, Speechley M, Ginter SF. Risk factors for falls among elderly persons living in the community. NEJM. December 29, 1988;319(26):1701-1707.
1997	Robinovitch SN, Hayes WC, McMahon TA. Distribution of contact force during impact to the hip. Ann Biomed Eng. May 1997;25(3):499-508.
2007	Feldman F, Robinovitch SN. Reducing hip fracture risk during sideways falls: evidence in young adults of the protective effects of impact to the hands and stepping. J Biomech. 2007;40(12):2612-2618.
2009	Garrison JG, Slaboch CL, Niebur GL. Density and architecture have greater effects on the toughness of trabecular bone than damage. Bone. May 2009;44(5):924-929.

Year

Entry

1996

Pinilla TP, Boardman KC, Bouxsein ML, Myers ER, Hayes WC. Impact direction from a fall influences the failure load of the proximal femur as much as age-related bone loss. Calcif Tiss Int. April 1996;58(4):231-235.

1998

Kopperdahl DL, Keaveny TM. Yield strain behavior of trabecular bone. J Biomech. July 1998;31(7):601-608.

1990

Lotz JC, Gerhart TN, Hayes WC. Mechanical properties of trabecular bone from the proximal femur: a quantitative CT study. J Comput Assist Tomogr. January–February 1990;14(1):107-114.

1990

Lotz JC, Hayes WC. The use of quantitative computed tomography to estimate risk of fracture of the hip from falls. J Bone Joint Surg. June 1990;72A(5):689-700.

1996

Courtney AC, Hayes WC, Gibson LJ. Age-related differences in post-yield damage in human cortical bone: experiment and model. J Biomech. November 1996;29(11):1463-1471.