Effect of Fatigue Loading on Impact Response of Rat Ulna

Stress fracture is a common injury among athletes, such as basketball players. The occurrence of stress fracture is a consequence of both fatigue and impact loading of the bone that will potentially threat athletes’ careers. Scientists and engineers have studied the fatigue properties of many engineering materials, and more recently biological materials. Investigating the role of fatigue on impact properties has received much less attention in bone. In this study, cyclic axial compressive loading was applied in vivo on the right ulnae of sixteen rats (Sprague-Dawley, Charles River), and the left served as contralateral control. The animals were divided into two groups: one day of rest before they were sacrificed and the other seven days. Afterwards, the ulnae were harvested and potted in epoxy and then scanned using micro-Computed Tomography (CT). Impact tests were performed using a customized figure where the impact energy was normalized for all specimens and following impact the specimens were re-scanned using micro-CT scans. There was no significant change in bone volume between the control (mean = 7.01 ± 0.61mm³) and loaded (mean = 6.63 ± 0.19mm³) ulnae in the group with one day rest (p = 0.28). However, after seven days of rest, the average bone volume increased by 4.35% among the control ulnae (mean = 7.32 ± 0.49mm³), and 15.10% among the loaded (mean = 7.63 ± 0.47mm³). The increase in volume was attributed to woven bone formation and was visually confirmed from the micro CT images. The peak impact force was 37.5% higher in the control (mean = 174.96 ± 33.25N) specimens than the loaded (mean = 130.34 ± 22.37N). Our data is limited to some degree by the sample size and two specimens fractured after the cyclic loading which further decease the sample size. Future work should investigate the effect of different rest times. This study indicated that cyclic fatigue loading had a negative impact on bone’s impact response. Bones that experienced fatigue loading became less stiff and resulted in lower peak forces, and an increased fracture rate when subjected to impact. Rest time was crucial to the recovery of fatigue damage. Seven days rest decreased the fracture rate by 66.67%. If more rest time was given, the peak force could return to the same level as the control or even higher as new bone would possibly mineralize. This study can provide a baseline guidance of the training, competition and rest arrangement to minimize the risk of stress fracture and prolong athletes’ careers.

Year	Entry
1971	Heřt J, Lišková M, Landa J. Reaction of bone to mechanical stimuli, I: continuous and intermittent loading of tibia in rabbit. Folia Morphol (Praha). August 1971;19(3):290-300.
1972	Chamay A, Tschantz P. Mechanical influences in bone remodeling: experimental research on Wolff's law. J Biomech. March 1972;5(2):173-180.
1977	Carter DR, Hayes WC. Compact bone fatigue damage, I: residual strength and stiffness. J Biomech. 1977;10(5-6):325-337.
1993	Mori S, Burr DB. Increased intracortical remodeling following fatigue damage. Bone. March–April 1993;14(2):103-109.
1966	McElhaney JH. Dynamic response of bone and muscle tissue. J Appl Physiol. 1966;21(4):1231-1236.
2000	Verborgt O, Gibson GJ, Schaffler MB. Loss of osteocyte integrity in association with microdamage and bone remodeling after fatigue in vivo. J Bone Miner Res. January 2000;15(1):60-67.
1973	Radin EL, Parker HG, Pugh JW, Steinberg RS, Paul IL, Rose RM. Response of joints to impact loading, III: relationship between trabecular microfractures and cartilage degeneration. J Biomech. January 1973;6(1):51-57.
1974	Freeman MAR, Todd RC, Pirie CJ. The role of fatigue in the pathogenesis of senile femoral neck fractures. J Bone Joint Surg. November 1974;56B(4):698-702.
1957	Evans FG, Lebow M. Strength of human compact bone under repetitive loading. J Appl Physiol. January 1957;10(1):127-130.
2018	Enns-Bray WS, Ferguson SJ, Helgason B. Strain rate dependency of bovine trabecular bone under impact loading at sideways fall velocity. J Biomech. June 2018;75:46-52.
1987	Frost HM. Bone "mass" and the "mechanostat": a proposal. Anat Rec. September 1987;219(1):1-9.
1995	Schaffler MB, Choi K, Milgrom C. Aging and matrix microdamage accumulation in human compact bone. Bone. December 1995;17(6):521-525.
1984	Lanyon LE, Rubin CT. Static vs dynamic loads as an influence on bone remodelling. J Biomech. 1984;17(12):897-905.
1996	Forwood MR, Owan I, Takano Y, Turner CH. Increased bone formation in rat tibiae after a single short period of dynamic loading in vivo. Am J Physiol Endocrinol Metab. March 1996;270(3):E419-E423.
1976	Carter DR, Hayes WC. Fatigue life of compact bone, I: effects of stress amplitude, temperature and density. J Biomech. 1976;9(1):27-34.
1991	Turner CH, Akhter MP, Raab DM, Kimmel DB, Recker RR. A noninvasive, in vivo model for studying strain adaptive bone modeling. Bone. 1991;12(2):73-79.
1975	Lanyon LE, Hampson WGJ, Goodship AE, Shah JS. Bone deformation recorded in vivo from strain gauges attached to the human tibial shaft. Acta Orthop Scand. 1975;46(2):256-268.
1984	Rubin CT, Lanyon LE. Regulation of bone formation by applied dynamic loads. J Bone Joint Surg. March 1984;66A(3):397-402.
1981	Carter DR, Caler WE, Spengler DM, Frankel VH. Fatigue behavior of adult cortical bone: the influence of mean strain and strain range. Acta Orthop Scand. 1981;52(5):481-490.
1994	Turner CH, Forwood MR, Rho J, Yoshikawa T. Mechanical loading thresholds for lamellar and woven bone formation. J Bone Miner Res. January 1994;9(1):87-97.
1998	Bentolila V, Boyce TM, Fyhrie DP, Drumb R, Skerry TM, Schaffler MB. Intracortical remodeling in adult rat long bones after fatigue loading. Bone. September 1998;23(3):275-281.
2007	Olszta MJ, Cheng X, Jee SS, Kumar R, Kim Y-Y, Kaufman MJ, Douglas EP, Gower LB. Bone structure and formation: a new perspective. Mater Sci Eng R Rep. November 28, 2007;58(3-5):77-116.
2001	Hsieh Y, Turner CH. Effects of loading frequency on mechanically induced bone formation. J Bone Miner Res. May 2001;16(5):918-924.
2002	Hsieh Y-F, Silva MJ. In vivo fatigue loading of the rat ulna induces both bone formation and resorption and leads to time-related changes in bone mechanical properties and density. J Orthop Res. July 2002;20(4):764-771.
2003	Morgan EF, Bayraktar HH, Keaveny TM. Trabecular bone modulus–density relationships depend on anatomic site. J Biomech. July 2003;36(7):897-904.
1996	Burr DB, Milgrom C, Fyhrie D, Forwood M, Nyska M, Finestone A, Hoshaw S, Saiag E, Simkin A. In vivo measurement of human tibial strains during vigorous activity. Bone. May 1996;18(5):405-410.
1997	Burr DB, Forwood MR, Fyhrie DP, Martin RB, Schaffler MB, Turner CH. Bone microdamage and skeletal fragility in osteoporotic and stress fractures. J Bone Miner Res. January 1997;12(1):6-15.

Year

Entry

1971

Heřt J, Lišková M, Landa J. Reaction of bone to mechanical stimuli, I: continuous and intermittent loading of tibia in rabbit. Folia Morphol (Praha). August 1971;19(3):290-300.

1972

Chamay A, Tschantz P. Mechanical influences in bone remodeling: experimental research on Wolff's law. J Biomech. March 1972;5(2):173-180.

1977

Carter DR, Hayes WC. Compact bone fatigue damage, I: residual strength and stiffness. J Biomech. 1977;10(5-6):325-337.

1993

Mori S, Burr DB. Increased intracortical remodeling following fatigue damage. Bone. March–April 1993;14(2):103-109.

1966

McElhaney JH. Dynamic response of bone and muscle tissue. J Appl Physiol. 1966;21(4):1231-1236.