Sage Journals: Discover world-class research

Abstract

This study examines the relation between the nature of acoustic emission signals emitted from cancellous bone under compression and the mechanical properties of the tissue. The examined bone specimens were taken from 12 normal, 31 osteoporotic and six osteoarthritic femoral heads. The mechanical behaviour of the osteoporotic bone specimens was found to be significantly different from that of the normal specimens both in the pre-yield and post-yield ranges. In the osteoarthritic bones only the elastic behaviour was significantly different. The rates of acoustic events before yield and beyond it were found to be significantly higher both in the osteoporotic and osteoarthritic bone specimens. The average peak amplitude of the signals was also significantly higher in the diseased bones.

Stepwise regression analysis showed that a combination of the acoustic emission parameters could significantly predict some mechanical properties of the bone. The energy absorbed during compression and the ultimate compressive stress of the specimens could be estimated from the rate of pre-yield acoustic events, the average amplitude of the signals and the rate of post-yield events. However, the explanation power of the acoustic emission parameters was only moderate. The nature of acoustic emission signals was thus demonstrated to be a potential tool for assessing bone quality.

Get full access to this article

View all access options for this article.

References

Pollard

H. F.

Sound waves in Solids, 1977, pp. 269–278 (Pioneer Publishers, London).

Dunegan

Harris

Acoustic emission—a new non-destructive testing tool. Ultrasonics, 1989, 7, 160–166.

James

D. R.

Carpenter

S. H.

Relationship between acoustic emission and dislocation kinetics in crystalline solids. J. Appl. Phys., 1971, 42, 4685–4697.

Hanagud

Clinton

R. G.

Acoustic emision techniques in the development of a diagnostic tool for osteoporosis. IEEE Symposium on Ultrasonics, 1975, 41–45.

Jonsson

Eriksson

Microcracking in dog bone under load. A biomechanical study of bone visco-elasticity. Acta Orthop. Scand., 1984, 55, 441–445.

Sugiyama

Whiteside

L. A.

Kaiser

A. D.

Examination of rotational fixation of the femoral component in total hip arthroplasty. A mechanical study of micromovement and acoustic emission. Clin. Orthrop. Rel. Res., 1989, 249, 122–128.

Hanagud

Clinton

R. G.

Lopez

J. P.

Acoustic emission in bone substance. Proceedings of the ASME Symposium on Biomechanics, 1973, 79–81.

Hanagud

Hannon

G. T.

Clinton

R. G.

Acoustic emission and diagnosis of osteoporosis. IEEE Symposium on Ultrasonics, 1974, 77–80.

Wright

T. M.

Vosburgh

Burstein

A. Permanent deformation of compact bone monitored by acoustic emission. J. Biomech., 1981, 14, 405–409.

10.

Fischer

R. A.

Arms

S. W.

Pope

M. H.

Seligson

Analysis of the effect of using two different strain rates on the acoustic emission in bone. J. Biomech., 1986, 19, 119–127.

11.

Thomas

R. A.

Yoon

H. S.

Katz

J. L.

Acoustic emission from fresh bovine femora. IEEE Symposium on Ultrasonics, 1977, 237–240.

12.

Yoon

H. S.

Caraco

Katz

J. L.

Further studies on the acoustic emission of fresh mammalian bones. IEEE Symposium on Ultrasonics, 1979, 399–404.

13.

Wells

J. G.

Rawlings

R. D.

Acoustic emission and mechanical properties of trabecular bone. Biomaterials, 1985, 6, 218–269.

14.

Thomas

I. M.

Evans

J. H.

Acoustic emission from vertebral bodies. J. Mater. Sci. Lett., 1988, 7, 267–269.

15.

Lincoln

K. L.

Kolaja

G. J.

Mathews

An SEM comparison of normal and post-menopausal osteoporotic trabecular bone. Micron, 1981, 12, 295–296.

16.

Alpert

Grynpas

M. D.

Pritzker

K. P. H.

Qualitative changes in subchondral bone mineral in osteoarthritis. Trans. Orthop. Res. Soc. Las-Vegas., 1985, 77.

17.

Bergot

Laval-Jeantet

Preteux

Meunier

Measurement of anisotropic vertebral trabecular bone loss during aging by quantitative image analysis. Calcif. Tissue Int., 1988, 43, 143–149.

18.

Chappard

Alexandre

Riffat

Spatial distribution of trabeculae in iliac bone from 145 osteoporotic females. Acta Anat., 1988, 132, 137–142.

19.

Gibson

L. J.

Ashby

M. F.

The mechanics of three-dimensional cellular materials. Proc. R. Soc. Lond., 1982, A382, 43–59.

20.

Radin

E. L.

Paul

I. L.

Tolkoff

M. J.

Subchondral bone changes in patients with early degenerative joint disease. Arthritis and Rheumatism, 1970, 13, 400–405.

21.

Koszyca

Fazzalari

N. L.

Vernon-Roberts

Trabecular microfractures—nature and distribution in the proximal femur. Clin. Orthop. Rel. Res., 1989, 244, 208–216.

22.

Carter

D. R.

Hayes

W. C.

The compressive behaviour of bones as a two phase porous structure. J. Bone Jt Surg., 1977, 59A, 954–962.

23.

Gibson

L. J.

The mechanical behaviour of cancellous bone. J. Biomech., 1985, 18, 317–328.

24.

Leichter

Simkin

Margulies

J. Y.

Bivas

Roman

Deutsch

Weinreb

. Can the weight-bearing capacity of the femoral neck be estimated by physical measurements on the greater trochanter? Engineering in Medicine, 1988, 17, 59–62.

Acoustic Emission from Trabecular Bone during Mechanical Testing: The Effect of Osteoporosis and Osteoarthritis

Abstract

Get full access to this article

References