The predictive value of quantitative computed tomography for vertebral body compressive strength and ash density

wbldb

Mosekilde, Lis¹; Bentzen, S. M.²; Ørtoft, G.¹; Jørgensen, J.³

The predictive value of quantitative computed tomography for vertebral body compressive strength and ash density

Bone. 1989;10(6):465-470

©1990 Pergamon Press plc

Affiliations

¹Department of Connective Tissue Biology, Institute of Anatomy, University of Aarhus

²Department of Medical Physics, Aarhus Kommunehospital, University of Aarhus

³Department of Diagnostic Radiology, Aarhus Kommunehospital, University of Aarhus, Aarhus C, Denmark
Abstract and keywords

Whole lumbar vertebral sections (L₂ and L₃) were obtained from 30 elderly individuals aged 43–95 years, mean 81 years (13 females, 17 males). None of the subjects had had malignant diseases. Quantitative computed tomography (QCT) was performed on an EMI 7070 scanner. One 8 mm slice parallel to the end-plates was obtained from the center of each vertebral body. The trabecular bone mass in each slice was outlined interactively by means of a tracer-ball. A CT-histogram was recorded inside this area, and average CT-values were expressed in Hounsfield Units (HU).

The whole vertebral body (L₂) was compressed in a materials testing machine. From the central part of L₃, vertical cylindrical pure trabecular bone specimens were obtained. The biomechanical competence of these specimens was also assessed by means of a materials testing machine. Finally, all bone specimens were incinerated for determination of apparent ash-density.

Highly significant positive correlations were found between average CT-values and (a) stress values of the trabecular bone (r = 0.81, p < 0.001) and (b) ash-density of the pure trabecular bone (r = 0.81, p < 0.001). Furthermore, a significant positive correlation was found between CT-values and (a) total vertebral body load (r = 0.72, p < 0.001), (b) total vertebral body stress (load/cross-sectional area) (r = 0.55, p < 0.001) and (c) ash-density of the whole vertebral body (r = 0.76, p < 0.001).

It is concluded that quantitative computed tomography gives valid predictions of both vertebral trabecular bone mass and mechanical competence. The predictive value for whole vertebral body load, stress and ash-density, although less marked, is still highly significant.

Keywords: Quantitative computed tomography; Vertebral body compressive strength; Ash-density; Bone architecture; Aging
Links

DOI: 10.1016/8756-3282(89)90080-X

PubMed: 2624829

WoS: A1989CJ70600012
History

Received: 1989-01-10

Revised: 1989-08-03

Accepted: 1989-08-30

Cited Works (16)

Year	Entry
1988	Bergot C, Laval-Jeantet A-M, Prêteux F, Meunier A. Measurement of anisotropic vertebral trabecular bone loss during aging by quantitative image analysis. Calcif Tiss Int. September 1988;43(3):143-149.
1986	Mosekilde L, Mosekilde L. Normal vertebral body size and compressive strength: relations to age and to vertebral and iliac trabecular bone compressive strength. Bone. 1986;7(3):207-212.
1987	Mosekilde L, Mosekilde L, Danielsen CC. Biomechanical competence of vertebral trabecular bone in relation to ash density and age in normal individuals. Bone. 1987;8(2):79-85.
1980	Cann CE, Genant HK. Precise measurement of vertebral mineral content using computed tomography. J Comput Assist Tomogr. 1980;4(4):493-500.
1985	Mosekilde L, Viidik A, Mosekilde L. Correlation between the compressive strength of iliac and vertebral trabecular bone in normal individuals. Bone. 1985;6(5):291-295.
1987	Parfitt AM. Trabecular bone architecture in the pathogenesis and prevention of fracture. Am J Med. January 26, 1987;82(suppl 1B):68-72.
1987	Bentzen SM, Hvid I, Jorgensen J. Mechanical strength of tibial trabecular bone evaluated by X-ray computed tomography. J Biomech. 1987;20(8):743-752.
1969	Rockoff SD, Sweet E, Bleustein J. The relative contribution of trabecular and cortical bone to the strength of human lumbar vertebrae. Calcif Tiss Res. December 1969;3(1):163-175.
1988	Cann CE. Quantitative CT for determination of bone mineral density: a review. Radiology. February 1988;166(2):509-522.
1977	Carter DR, Hayes WC. The compressive behavior of bone as a two-phase porous structure. J Bone Joint Surg. 1977;59A(7):954-962.
1985	Cann CE, Genant HK, Kolb FO, Ettinger B. Quantitative computed tomography for prediction of vertebral fracture risk. Bone. 1985;6(1):1-7.
1985	Kleerekoper M, Villanueva AR, Stanciu J, Rao DS, Parfitt AM. The role of three-dimensional trabecular microstructure in the pathogenesis of vertebral compression fractures. Calcif Tiss Int. 1985;37(6):594-597.
1988	Mosekilde L. Age-related changes in vertebral trabecular bone architecture—assessed by a new method. Bone. 1988;9(4):247-250.
1985	McBroom RJ, Hayes WC, Edwards WT, Goldberg RP, White AA III. Prediction of vertebral body compressive fracture using quantitative computed tomography. J Bone Joint Surg. 1985;67A(8):1206-1214.
1988	Mosekilde L, Mosekilde L. Iliac crest trabecular bone volume as predictor for vertebral compressive strength, ash density and trabecular bone volume in normal individuals. Bone. 1988;9(4):195-199.
1988	Biggemann M, Hilweg D, Brinckmann P. Prediction of the compressive strength of vertebral bodies of the lumbar spine by quantitative computed tomography. Skeletal Radiol. June 1988;17(4):264-269.

Cited By (47)

Year	Entry
1995	Louis O, Boulpaep F, Willnecker J, Van den Winkel P, Osteaux M. Cortical mineral content of the radius assessed by peripheral QCT predicts compressive strength on biomechanical testing. Bone. March 1995;16(3):375-379.
1995	Singer K, Edmondston S, Day R, Breidahl P, Price R. Prediction of thoracic and lumbar vertebral body compressive strength: correlations with bone mineral density and vertebral region. Bone. August 1995;17(2):167-174.
1997	Silva MJ, Gibson LJ. Modeling the mechanical behavior of vertebral trabecular bone: effects of age-related changes in microstructure. Bone. 1997;21(2):191-199.
1998	Ebbesen EN, Thomsen JS, Beck-Nielsen H, Nepper-Rasmussen HJ, Mosekilde L. Vertebral bone density evaluated by dual-energy X-ray absorptiometry and quantitative computed tomography in vitro. Bone. September 1998;23(3):283-290.
1999	Ebbesen EN, Thomsen JS, Beck-Nielsen H, Nepper-Rasmussen HJ, Mosekilde L. Lumbar vertebral body compressive strength evaluated by dual-energy X-ray absorptiometry, quantitative computed tomography, and ashing. Bone. December 1999;25(6):713-724.
2002	Thomsen JS, Ebbesen EN, Mosekilde L. Zone-dependent changes in human vertebral trabecular bone: clinical implications. Bone. May 2002;30(5):664-669.
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.
2007	Buckley JM, Loo K, Motherway J. Comparison of quantitative computed tomography-based measures in predicting vertebral compressive strength. Bone. March 2007;40(3):767-774.
1990	Mazess RB. Fracture risk: a role for compact bone. Calcif Tiss Int. October 1990;47(4):191-193.
1993	Myers ER, Hecker AT, Rooks DS, Hipp JA, Hayes WC. Geometric variables from DXA of the radius predict forearm fracture load in vitro. Calcif Tiss Int. March 1993;52(3):199-204.
2007	Eswaran SK, Bayraktar HH, Adams MF, Gupta A, Hoffmann PF, Lee DC, Papadopoulos P, Keaveny TM. The micro-mechanics of cortical shell removal in the human vertebral body. Comput Meth Appl Mech Eng. June 15, 2007;196(31-32):3025-3032.
1994	Bowman SM, Keaveny TM, Gibson LJ, Hayes WC, McMahon TA. Compressive creep behavior of bovine trabecular bone. J Biomech. March 1994;27(3):301-310.
2002	Kim HS, Al-Hassan STS. A morphological model of vertebral trabecular bone. J Biomech. August 2002;35(8):1101-1114.
1993	Keaveny TM, Hayes WC. A 20-year perspective on the mechanical properties of trabecular bone. J Biomech Eng. November 1993;115(4B):534-542.
2018	Hussein AI, Louzeiro DT, Unnikrishnan GU, Morgan EF. Differences in trabecular microarchitecture and simplified boundary conditions limit the accuracy of quantitative computed tomography-based finite element models of vertebral failure. J Biomech Eng. February 2018;140(2):021004.
2000	Whealan KM, Kwak SD, Tedrow JR, Inoue K, Snyder BD. Noninvasive imaging predicts failure load of the spine with simulated osteolytic defects. J Bone Joint Surg. September 2000;82A(9):1240-1251.
1997	Cheng XG, Nicholson PHF, Boonen S, Lowet G, Brys P, Aerssens J, van der Perre G, Dequeker J. Prediction of vertebral strength in vitro by spinal bone densitometry and calcaneal ultrasound. J Bone Miner Res. October 1997;12(10):1721-1728.
1999	Ebbesen EN, Thomsen JS, Beck‐Nielsen H, Nepper‐Rasmussen HJ, Mosekilde L. Age‐ and gender‐related differences in vertebral bone mass, density, and strength. J Bone Miner Res. August 1999;14(8):1394-1403.
2000	McCreadie BR, Goldstein SA. Biomechanics of fracture: is bone mineral density sufficient to assess risk? J Bone Miner Res. December 2000;15(12):2305-2308.
2003	Paschalis EP, Boskey AL, Kassem M, Eriksen EF. Effect of hormone replacement therapy on bone quality in early postmenopausal women. J Bone Miner Res. June 2003;18(6):955-959.
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.
2008	Engelke K, Adams JE, Armbrecht G, Augat P, Bogado CE, Bouxsein ML, Felsenberg D, Ito M, Prevrhal S, Hans DB, Lewiecki EM. Clinical use of quantitative computed tomography and peripheral quantitative computed tomography in the management of osteoporosis in adults: the 2007 ISCD official positions. J Clin Densitom. January–March 2008;11(1):123-162.
2015	Zysset P, Qin L, Lang T, Khosla S, Leslie WD, Shepherd JA, Schousboe JT, Engelke K. Clinical use of quantitative computed tomography–based finite element analysis of the hip and spine in the management of osteoporosis in adults: the 2015 ISCD official positions—part II. J Clin Densitom. July–September 2015;18(3):359-392.
2000	Kopperdahl DL, Pearlman JL, Keaveny TM. Biomechanical consequences of an isolated overload on the human vertebral body. J Orthop Res. September 2000;18(5):685-690.
1991	Hayes WC, Piazza SJ, Zysset PK. Biomechanics of fracture risk prediction of the hip and spine by quantitative computed tomography. Radiol Clin North Am. 1991;29(1):1-18.
1991	Faulkner KG, Cann CE, Hasegawa BH. Effect of bone distribution on vertebral strength: assessment with patient-specific nonlinear finite element analysis. Radiology. June 1991;179(3):669-674.
1998	Wehrli FW, Hwang SN, Ma J, Song HK, Ford JC, Haddad JG. Cancellous bone volume and structure in the forearm: noninvasive assessment with MR microimaging and image processing. Radiology. February 1998;206(2):347-357.
1997	Myers ER, Wilson SE. Biomechanics of osteoporosis and vertebral fracture. Spine. December 15, 1997;22(24)(suppl):25S-31S.
2003	Liebschner MAK, Kopperdahl DL, Rosenberg WS, Keaveny TM. Finite element modeling of the human thoracolumbar spine. Spine. March 15, 2003;28(6):559-565.
2004	Crawford RP, Keaveny TM. Relationship between axial and bending behaviors of the human thoracolumbar vertebra. Spine. October 15, 2004;29(20):2248-2255.
2006	Imai K, Ohnishi I, Bessho M, Nakamura K. Nonlinear finite element model predicts vertebral bone strength and fracture site. Spine. July 15, 2006;31(16):1789-1794.
2013	Hussein Ali AI. 3-D Visualization and Prediction of Spine Fractures Under Axial Loading [PhD thesis]. Boston University; 2013.
1997	Bowman SM. Creep of Trabecular Bone [PhD thesis]. Cambridge, MA: Harvard University; May 1997.
1996	Silva MJ. Predicting the Failure Behavior of the Human Vertebral Body [PhD thesis]. Cambridge, MA: Massachusetts Institute of Technology; February 1996.
2004	Wang X. Measurement and Analysis of Microdamage in Bone [PhD thesis]. University of Notre Dame; December 2004.
2011	Wagnac É. Expérimentation et modélisation détaillée de la colonne vertébrale pour étudier le rôle de facteurs anatomiques et biomécaniques sur les traumatismes rachidiens [PhD thesis]. École polytechnique de Montréal; November 2011.
2005	Buie HR. Use of Finite Element Method Modelling and Rapid Prototyping to Study the Effect of Trabecular Bone Architecture on Apparent Mechanical Properties [Master's thesis]. Queen's University; November 2005.
2008	Crookshank MCM. Optimizing Fracture Management: Correlating the Physical and Mechanical Properties of Bone to Computed Tomography to Generate an Estimate of Bone Quality [Master's thesis]. Queen's University; January 2008.
2014	Bradke BS. The Role of Cortical and Cancellous Bone Quality on Vertebral Fragility [PhD thesis]. Troy, NY: Rensselaer Polytechnic Institute; April 2014.
2016	Britz HM. The Effect of Genetic Variation on Mouse Bone Strength [PhD thesis]. Calgary, AB: University of Calgary; August 2016.
1990	Faulkner KG. Quantitative Computed Tomography and Finite Element Modeling to Predict Vertebral Fractures [PhD thesis]. Berkeley, CA: Berkeley, University of California; June 1990.
1998	Kopperdahl DL. Structural Consequences of Damage on the Mechanical Behavior of the Human Vertebral Body [PhD thesis]. Berkeley, CA: Berkeley, University of California; 1998.
2000	Niebur GL. A Computational Investigation of Multiaxial Failure in Trabecular Bone [PhD thesis]. Berkeley, CA: University of California; 2000.
2002	Graham JH. Fracture Toughness Testing of the Trabecular Bone/acrylic Bone Cement Interface [PhD thesis]. Berkeley, CA: Berkeley, University of California; 2002.
2010	Wald MJ. Mapping Trabecular Bone Fabric Tensor by in Vivo Magnetic Resonance Imaging [PhD thesis]. Philadelphia, PA: University of Pennsylvania; 2010.
1993	Boyce TM. Aging Changes Within the Human Femoral Neck Cortex [PhD thesis]. University of Utah; August 1993.
2009	García-Rodríguez S. Mechanical Behavior of Trabecular Bone [PhD thesis]. University of Wisconsin – Madison; 2009.