Understanding Vertebral Fracture Risk in Astronauts

In spaceflight, the loss of mechanical loading has detrimental effects on the musculoskeletal system. These muscular changes will likely affect spinal loading, a key aspect of vertebral fracture risk, but no prior studies have examined how spinal loading is affected by long duration spaceflight. Moreover, the effect of spaceflight on vertebral strength has not been determined, despite reports of significant vertebral trabecular bone loss in long-duration astronauts. Thus trunk muscle and vertebral bone changes and their impact on risk of injury following long-duration spaceflight remain unknown. This is of particular concern for NASA's planned Mars missions and return to Earth after prolonged deconditioning. Our lab has developed a musculoskeletal model of the thoracolumbar spine that has been validated for spinal loading, but has not yet been extended to maximal effort activities or full-body simulations. Thus, the overall goal of this work consisted of two main sections: 1) address the knowledge gap regarding spaceflight and post-flight recovery effects on trunk muscle properties, vertebral strength, compressive spine loading and vertebral fracture risk, and 2) extend our musculoskeletal modeling work into maximal effort simulations in an elderly population and create a full-body scaled model to investigate reproducibility of spine loading estimates using opto-electronic motion capture data.

Whereas deficits in trunk muscle area returned to normal during on-Earth recovery, spaceflight-induced increases in intramuscular fat persisted in some muscles even years after landing. Similarly, spaceflight led to a decrease in lumbar vertebral strength that did not recover even after multiple years on Earth. To gain insight into the effect of spaceflight on vertebral fracture risk, we created subject-specific musculoskeletal models using an individual’s height, weight, sex, muscle measurements, and spine curvature. We found that compressive spine loading was minimally affected by spaceflight and that vertebral fracture risk, calculated as a ratio of vertebral load to strength, was slightly elevated post-flight and remained elevated during readaptation on Earth. Additionally, we focused on the development of additional musculoskeletal modeling tools. Using maximal effort model simulations, we estimated trunk maximum muscle stress in an elderly population, and this critical parameter in musculoskeletal modeling will assist with more detailed model creation. Lastly, we found excellent reliability of spine loading estimations from opto-electronic marker data.

Year	Entry
2001	Anderson FC, Pandy MG. Dynamic optimization of human walking. J Biomech Eng. October 2001;123(5):381-390.
1992	Cooper C, Atkinson EJ, O'Fallon WM, Melton JL III. Incidence of clinically diagnosed vertebral fractures: a population‐based study in Rochester, Minnesota, 1985‐1989. J Bone Miner Res. February 1992;7(2):221-227.
1993	Ross PD, Genant HK, Davis JW, Miller PD, Wasnich RD. Predicting vertebral fracture incidence from prevalent fractures and bone density among non-black, osteoporotic women. Osteoporos Int. May 1993;3(3):120-126.
2006	Eswaran SK, Gupta A, Adams MF, Keaveny TM. Cortical and trabecular load sharing in the human vertebral body. J Bone Miner Res. February 2006;21(2):307-314.
2004	Lang T, LeBlanc A, Evans H, Lu Y, Genant H, Yu A. Cortical and trabecular bone mineral loss from the spine and hip in long‐duration spaceflight. J Bone Miner Res. June 2004;19(6):1006-1012.
2004	Schuit SCE, van der Klift M, Weel AEAM, de Laet CEDH, Burger H, Seeman E, Hofman A, Uitterlinden AG, van Leeuwen JPTM, Pols HAP. Fracture incidence and association with bone mineral density in elderly men and women: the Rotterdam Study. Bone. January 2004;34(1):195-202.
2007	Delp SL, Anderson FC, Arnold AS, Loan P, Habib A, John CT, Guendelman E, Thelen DG. OpenSim: open-source software to create and analyze dynamic simulations of movement. IEEE Trans Biomed Eng. November 2007;54(11):1940-1950.
2009	Keyak JH, Koyama AK, LeBlanc A, Lu Y, Lang TF. Reduction in proximal femoral strength due to long-duration spaceflight. Bone. March 2009;44(3):449-453.
1999	Ismail AA, Cooper C, Felsenberg D, Varlow J, Kanis JA, Silman AJ, O’Neill TW; European Vertebral Osteoporosis Study Group. Number and type of vertebral deformities: epidemiological characteristics and relation to back pain and height loss. Osteoporos Int. March 1999;9(3):206-213.
2007	Melton LJ III, Riggs BL, Keaveny TM, Achenbach SJ, Hoffmann PF, Camp JJ, Rouleau PA, Bouxsein ML, Amin S, Atkinson EJ, Robb RA, Khosla S. Structural determinants of vertebral fracture risk. J Bone Miner Res. December 2007;22(12):1885-1892.
1989	Yamaguchi GT, Zajac FE. A planar model of the knee joint to characterize the knee extensor mechanism. J Biomech. 1989;22(1):1-10.
2000	Klotzbuecher CM, Ross PD, Landsman PB, Abbott TA III, Berger M. Patients with prior fractures have an increased risk of future fractures: a summary of the literature and statistical synthesis. J Bone Miner Res. April 2000;15(4):721-739.
1995	Stokes IAF, Gardner-Morse M. Lumbar spine maximum efforts and muscle recruitment patterns predicted by a model with multijoint muscles and joints with stiffness. J Biomech. February 1995;28(2):173-186.
1990	Delp SL, Loan JP, Hoy MG, Zajac FE, Topp EL, Rosen JM. An interactive graphics-based model of the lower extremity to study orthopaedic surgical procedures. IEEE Trans Biomed Eng. 1990;37(8):757-767.
2005	Wainwright SA, Marshall LM, Ensrud KE, Cauley JA, Black DM, Hillier TA, Hochberg MC, Vogt MT, Orwoll ES; Study of Osteoporotic Fractures Research Group. Hip fracture in women without osteoporosis. J Clin Endocrinol Metab. May 2005;90(5):2787-2793.
1993	Melton LJ III, Lane AW, Cooper C, Eastell R, O'Fallon WM, Riggs BL. Prevalence and incidence of vertebral deformities. Osteoporos Int. May 1993;3(3):113-119.
2014	Kopperdahl DL, Aspelund T, Hoffmann PF, Sigurdsson S, Siggeirsdottir K, Harris TB, Gudnason V, Keaveny TM. Assessment of incident spine and hip fractures in women and men using finite element analysis of CT scans. J Bone Miner Res. March 2014;29(3):570-580.
1996	de Leva P. Adjustments to Zatsiorsky-Seluyanov's segment inertia parameters. J Biomech. September 1996;29(9):1223-1230.
2007	LeBlanc AD, Spector ER, Evans HJ, Sibonga JD. Skeletal responses to space flight and the bed rest analog: a review. J Musculoskel Neuron Interact. 2007;7(1):33-47.
2003	Crawford RP, Cann CE, Keaveny TM. Finite element models predict in vitro vertebral body compressive strength better than quantitative computed tomography. Bone. 2003;33(4):744-750.
2011	Christiansen BA, Kopperdahl DL, Kiel DP, Keaveny TM, Bouxsein ML. Mechanical contributions of the cortical and trabecular compartments contribute to differences in age-related changes in vertebral body strength in men and women assessed by QCT-based finite element analysis. J Bone Miner Res. May 2011;26(5):974-983.
2012	Wang X, Sanyal A, Cawthon PM, Palermo L, Jekir M, Christensen J, Ensrud KE, Cummings SR, Orwoll E, Black DM, Keaveny TM; Osteoporotic Fractures in Men (MrOS) Research Group. Prediction of new clinical vertebral fractures in elderly men using finite element analysis of CT scans. J Bone Miner Res. April 2012;27(4):808-816.
2007	Burge R, Dawson‐Hughes B, Solomon DH, Wong JB, King A, Tosteson A. Incidence and economic burden of osteoporosis‐related fractures in the United States, 2005–2025. J Bone Miner Res. March 2007;22(3):465-475.
2010	Cavanagh PR, Genc KO, Gopalakrishnan R, Kuklis MM, Maender CC, Rice AJ. Foot forces during typical days on the international space station. J Biomech. August 10, 2010;43(11):2182-2188.
1988	Bean JC, Chaffin DB, Schultz AB. Biomechanical model calculation of muscle contraction forces: a double linear programming method. J Biomech. 1988;21(1):59-66.
2006	Lang TF, Leblanc AD, Evans HJ, Lu Y. Adaptation of the proximal femur to skeletal reloading after long-duration spaceflight. J Bone Miner Res. August 2006;21(8):1224-1230.
1999	Melton LJ III, Atkinson EJ, Cooper C, O’Fallon WM, Riggs BL. Vertebral fractures predict subsequent fractures. Osteoporos Int. September 1999;10(3):214-221.
2000	LeBlanc A, Schneider V, Shackelford L, West S, Oganov V, Bakulin A, Voronin L. Bone mineral and lean tissue loss after long duration space flight. J Musculoskel Neuron Interact. 2000;1(2):157-160.

Year

Entry

2001

Anderson FC, Pandy MG. Dynamic optimization of human walking. J Biomech Eng. October 2001;123(5):381-390.

1992

Cooper C, Atkinson EJ, O'Fallon WM, Melton JL III. Incidence of clinically diagnosed vertebral fractures: a population‐based study in Rochester, Minnesota, 1985‐1989. J Bone Miner Res. February 1992;7(2):221-227.

1993

Ross PD, Genant HK, Davis JW, Miller PD, Wasnich RD. Predicting vertebral fracture incidence from prevalent fractures and bone density among non-black, osteoporotic women. Osteoporos Int. May 1993;3(3):120-126.

2006

Eswaran SK, Gupta A, Adams MF, Keaveny TM. Cortical and trabecular load sharing in the human vertebral body. J Bone Miner Res. February 2006;21(2):307-314.

2004

Lang T, LeBlanc A, Evans H, Lu Y, Genant H, Yu A. Cortical and trabecular bone mineral loss from the spine and hip in long‐duration spaceflight. J Bone Miner Res. June 2004;19(6):1006-1012.