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01-03-2008 | Original Article

Subchondral bone density of the radial head measured with subtraction densitometry

Authors: T. C. Koslowsky, K. Mader, A. Brandenburg, M. Hellmich, J. Koebke

Published in: Surgical and Radiologic Anatomy | Issue 2/2008

Abstract

The purpose of this study was to develop a two-dimensional density distribution pattern of the subchondral cortical bone of the radial head using subtraction densitometry. The bone density of 32 normal specimens and five with macroscopic signs of osteoarthritis was measured before and after milling off the cortical bone surface. Electronic subtraction gave the density of the subchondral cortical bone. Twenty-one specimens had areas of high bone density in the ulnar-dorsal area, five specimens showed a ventral and ulnar density maximum and six had a density maximum in the center of the radial head joint surface. No density maximum was seen in the lateral part of the joint surface. The density maximum shifted towards the dorsal-ulnar part of the radial head with decreasing total subchondral bone density. Osteoarthritic radial heads had the same distribution as non-arthritic specimens. Eccentric subchondral bone density reflects eccentric radiohumeral force transmission. This could be a reason for development of radiohumeral arthritis or the failure of radial head prostheses. Bone density patterns correlate with the incidence of radial head fractures and fracture line may be positioned between areas of high and low densities.

Ahrens PM, Redfern DR, Forester AJ (2001) Patterns of articular wear in the cadaveric elbow joint. J Shoulder Elbow Surg Jan Feb 10(1):52–56CrossRef

Bünck S (1990) Curvatures and contact surfaces of the humeroradial joint. Anat Anz 171:45–53PubMed

Ciraelli MJ, Goldstein SA, Kuhn JL (1991) Evaluation of orthogonal mechanical properties and density of human trabecular bone from major metaphyseal regions with material testing and computer tomography. J Orthop Res 9:674–682CrossRef

Eckstein F, Merz B, Schön M, Jacobs CR, Putz R (1999) Tension bending, but not compression alone determine the functional adaptation of subchondral bone in incongruous joints. Anat Embryol 199:85–97PubMedCrossRef

Eckstein F, Müller-Gerbl M, Steinlechner M, Kierse R, Putz R (1995) Subchondral bone density in the human elbow assessed by computed tomography osteoabsorptiometry: a reflection of the loading history of the joint surfaces. J Orthop Res 13(2):268–278PubMedCrossRef

Eckstein F, Steinlechner M, Müller-Gerbl M, Putz R (1993) Mechanical stress and subchondral mineralization of the human elbow joint. A CT-osteoabsorptiometric study. Unfallchirurg 96(8):399–404

Goel VK, Singh D, Bijlani V (1982) Contact areas in human elbow joints. J Biomech Eng 104:169–175PubMedCrossRef

Goodfellow JW, Bullough PG (1967) The pattern of aging of the articular cartilage of the elbow joint. J Bone Joint Surg (Br) 49:174–179

Gordon KD, Duck TR, King GJ, Johnson JA (2003) Mechanical properties of subchondral cancellous bone of the radial head. J Orthop Trauma 17(4):285–289PubMedCrossRef

10.

Goto A, Moritomo H, Murase T, Oka K, Sugamoto K, Arimura T, Nakajima Y, Yamazaki T, Sato Y, Tamura S, Yoshikawa H, Ochi T (2004) In vivo elbow biomechanical analysis during flexion: three-dimensional motion analysis using magnetic resonance imaging. J Shoulder Elbow Surg 13(4):441–447PubMedCrossRef

11.

Halls AA, Travill A (1964) Transmission of pressure across the elbow joint. Anat Rec 150:243–248PubMedCrossRef

12.

Horsman A, Currey JD (1983) Estimation of mechanical properties of the distal radius from bone mineral content and cortical width. Clin Orthop Relat Res (176):298–304

13.

Josefchak RG, Finlay JB, Bourne RB (1987) Cancellous bone support for patellar resurfacing. Clin Orthop 220:192–199

14.

Keyak JH, Lee IY, Skinner HB (1994) Correlations between orthogonal mechanical properties and density of trabecular bone: use of different densitometric measures. J Biomed Mat Res 28:1329–1336CrossRef

15.

Koebke J, Mockenhaupt J, Lorbach O (1991) Die Subtraktionsäquidensitometrie als Methode zur Analyse der Gelenkbeanspruchung—dargestellt am Beispiel des radiocarpalen Gelenkes. Osteologie—interdisziplinär. Hrsg.: von Werner E, Matthias, H. H., Springer, Berlin, Heidelberg, New York, pp 78–81

16.

Koslowsky TC, Germund I, Beyer F, Mader K, Krieglstein CF, Koebke J (2007) Morphometric parameters of the radial head: an anatomical study. Surg Radiol Anat 29(3):225–230PubMedCrossRef

17.

Koslowsky TC, Beyer F, Germund I, Mader K, Jergas M, Koebke J (2007) Morphometric parameters of the radial neck: an anatomical study. Surg Radiol Anat 29(4):279–284PubMedCrossRef

18.

Kummer B (1985) Die kausale Histogenese der Gewebe des Bewegungsapparates und funktionelle Anpassung. In: Benninghoff A (ed) Markroskopische und Mikroskopiscshe Anatomie des Menschen, vol 1. München, Wien und Batimore, Urban & Schwarzenberg, pp 199–213

19.

Lill CA, Goldhahn J, Albrecht A, EcksteinF, Gatzka C, Schneider E (2003) Impact of bone density on distal radius fracture patterns and comparison between five different fracture classifications. J Orthp Trauma 17(4):271–278CrossRef

20.

Louis O, Boulpaep F, Willnecker J, Van den Winkel P, Osteaux M (1995) Cortical mineral content of the radius assessed by peripheral QCT predicts compressive strength on biomechanical testing. Bone 16(3):375–379PubMedCrossRef

21.

Mazocca AD, Caputo AE, Ryan NE, Grasso JA (1998) The subchondral and cartilage architecture of the radial head: a histomorphometric analysis with correlation to fracture patterns and force transmission. Transactions of the 44th ORS, 1151

22.

Myers ER, Sebeny EA, Hecker AT, Corcoran TA, Hipp JA, Greenspan SL, Hayes WC (1991) Correlations between photon absorption properties and failure load of the distal radius in vitro. Calcif Tissue Int 49(4):292–297PubMedCrossRef

23.

Morrey BF (2000) Radial head fractures In: Morrey BF (ed) The elbow and its disorders. WB Saunders, Philadelphia, pp 341–363

24.

Pauwels F (1965) Gesammelte Abhandlungen zur funktionellen Anatomie des Bewegungsapparates. Springer, Berlin, Heidelberg, New York

25.

Rho JY, Hobatho MC, Ashmann RB (1995) Relations of mechanical properties to density and CT numbers in human bone. Med Eng Phys 17:347–355PubMedCrossRef

Title: Subchondral bone density of the radial head measured with subtraction densitometry
Authors: T. C. Koslowsky
K. Mader
A. Brandenburg
M. Hellmich
J. Koebke
Publication date: 01-03-2008
Publisher: Springer-Verlag
Published in: Surgical and Radiologic Anatomy / Issue 2/2008
Print ISSN: 0930-1038
Electronic ISSN: 1279-8517
DOI: https://doi.org/10.1007/s00276-007-0299-9

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Subchondral bone density of the radial head measured with subtraction densitometry

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