Professor John D Currey

Contact Details:
Department of Biology (Area 9)
University of York
YO10 5YW
Tel: 44-(0)1904 32 8589
Fax: 44-(0)1904 32 8505
Email: jdc1@york.ac.uk

My scientific work

I remember, more than 25 years ago at a party, saying to a girl that my real ambition was to find out what happens when a bone breaks. That is still what I am after. (Her ambition was to get off with the millionaire partygiver). We know a great deal about the stresses and strains that you have to impose on bones in order to make them break, but we still have very little idea of what goes on in a nitty-gritty way as cracks start to form, coalesce, and become dangerous. Bone has a quite extraordinarily intimate relationship between its mineral (hydroxyapatite) and its main protein (collagen). The apatite crystals are plate-like and very thin (3º nm or so), and insert themselves between the collagen molecules to produce an architecture that is still unclear. When bone starts to break thousands of little microcracks form. These microcracks are positioned sensibly in relation to the histological structure of the bone, but we don't know where they form in relation to the ultrastructure. Typically when microcracks form they only reach a few microns in length before they come to a halt. The big question is, what brings them to a halt? (Microcracks in themselves can be a good thing, because they absorb energy as they form, and the ability to form microcracks makes the bone tough. There is a corresponding disadvantage that they make the bone less stiff.)

My major interest recently is in this microcracking. The literature is full of reference to 'microcracks', but what people have meant by this is cracks 100º µm or so long. Such long cracks are already on their way to being dangerous. We found multitudes of cracks that were 5 ºµm or so long, and which are much more interesting because they absorb huge amounts of energy as they form. For several years I have been going to conferences saying 'Look folks, these are the important cracks, get a confocal and look!' Solid resistance at first, for some reason, but people are at last coming round to the idea, and the literature is growing. I have been pursuing these microcracks, seeing, for instance, how there are less of them in brittle bone, less of them in bone that has been irradiated, and we are getting some idea about how they grow and multiply.

Zioupos, P.; Currey, J.D.; Sedman, A.J. (1994) An examination of the micromechanics of failure of bone and antler by acoustic emission tests and Laser Scanning Confocal Microscopy. Med. Engng. & Phys. 16: 203-212; 1994.

Zioupos, P and Currey J.D. (1996) Pre-failure toughening mechanisms in the dentine of the narwhal tusk: microscopic examination of stress/strain induced microcracking. Journal of materials science letters 15: 991-994.

Zioupos, P. and Currey, J.D. (1998) Changes in the stiffness, strength, and toughness of human cortical bone with age. Bone 22: 57-66.

Reilly, G.C. and Currey, J.D. (1999) The development of microcracking and failure in bone depends on the loading mode to which it is adapted. Journal of experimental biology 202: 543-552.

Reilly, G.C. and Currey, J.D. (2000) The effects of damage and microcracking on the impact strength of bone. Journal of Biomechanics 33, 337-343.

I also work on other areas of bone mechanics.

1) What is the effect of ageing, disease, and treatment on the mechanical properties of bone? I am interested in how bone gets less tough with age, and what causes this - is it a change in the stability of the collagen (answer probably yes) or is it a change in the mineral, or is it that the bone becomes deranged or changed at a somewhat higher level (the histological).

Zioupos, P., Currey, J.D. and Hamer, A.J. 1999 J Biomed Materials Res: 45, 108-116. The role of collagen in the declining mechanical properties of ageing human cortical bone.

Batson, E.L., Reilly, G.C., Currey, J.D. and Balderson, D.S. 2000 Equine Veterinary Journal: 32, 95-100. Postexercise and positional variation in mechanical properties of the radius in young horses.

The detailed way this bone breaks up in old versus young, osteoporotic and osteoarthritic pathologies is giving us a clearer understanding of the cause of the incidence of fractures in various pathological states.

2) What is the range of the mechanical properties of bone and how are they adapted to the functional requirements of the animal? I have produced, by hard experimentation over the years, and am adding to, a large database of the mechanical properties of various bones. We are finding some very extreme properties, some of which can be clearly seen to be adaptive, others less so. I am also concerned with whether the more usual differences one finds in 'ordinary' bones are adaptive. I have also compared fatigue and other properties of highly mineralised bone with that of similarly mineralised mother of pearl, and found that mother of pearl is far superior (presumably because mother of pearl is designed to be highly mineralised, bone isn't).

Currey, J.D. Brear, K. And Zioupos, P. 1994 Dependence of mechanical properties on fibre angle in narwhal tusk, a highly oriented biological composite. J. Biomech. 27: 885-897.

Zioupos, P., Currey, J.D., Casinos, A. and De Buffrénil, V. 1997 Mechanical properties of the rostrum of the whale Mesoplodon densirostris, a remarkably dense bony tissue. Journal of zoology, London 241: 725-737

Zioupos, P., Currey, J.D. Casinos, A. (2000) Exploring the effects of hypermineralisation in bone tissue by using an extreme biological example. Connective tissue research 41:229-248

Currey JD, Zioupos P, Davies P, Casinos A (2001) Mechanical properties of nacre and highly mineralized bone. Proceedings of the Royal Society of London B 268:107-111

3) I have had a blinding glimpse of the obvious and, using my large data set, looked at the relationship between the stiffness of the bone and its bending strength. There is an extremely tight proportional relationship, which no-one has really commented on before. This sounds like a piece of Ho Hum, but is actually very important, because it shows that the bending strength of bone is determined by its yield stress (still with me?). The extent to which it is not the yield stress, tells us other related things about the fracture process in bending. This kind of thing is rather well known to mechanical engineers in other materials, but its presence and significance in bone has not been described before.

Currey, J.D. 1999 What determines the bending strength of bone? Journal of Experimental Biology 202: 2495-2503.

I am looking at similar effects in tension, and find very interesting differences.

4) Nanoindentation is a technique that allows one to examine the stiffness of very small areas of bone. We are using this technique to look at how the stiffness changes between the inside of Haversian systems and outside, and with orientation, and with age.

Rho, J.Y., Zioupos, P. Currey, J.D. Pharr, G.M. (1999) Variations in the individual thick lamellar properties within osteons by nanoindentation. Bone 25:295-300.

Rho, J.Y., Currey, J.D., Zioupos, P., Pharr, , G.M. (2001) The anisotropic Young's modulus of equine secondary osteones and interstitial bone determined by nanoindentation. Journal of experimental biology. 204: 1775-1781

Rho JY, Zioupos P, Currey JD, Pharr GM (2002) Microstructural elasticity and regional heterogeneity in human femoral bone of various ages examined by nano-indentation. Journal of Biomechanics 35:189-198.

5) People who have been moaning at me occasionally about not producing a second edition of my book may or may not be pleased to know that it now published:
'Bones: structure and mechanics' (2002) Princeton University Press.
Those who are brave enough to read it (everybody should buy it) should know that there is an error in Table 3.2. The values 141 12 (10) and 156 7.9 (6) should both be moved one column to the right. People who care about these things would have worked this out for themselves I think. Sorry. No doubt there are other errors!

I have various collaborations, of varying intensity.

Peter Zioupos. Royal Military College Shrivenham (Cranfield University). Peter is my ex post-doc, and we are still writing papers together and collaborating on further work.

Professor Steve Weiner. In February 2003 I worked with Steve Weiner and Paul Zaslanski at the Weizmann Institute in Rehovot, Israel, on the development of a speckle interferometer. This can measure minute displacements (and therefore strains) over reasonably large areas. We intend to use it to answer some new questions that we can now ask about stress/strain/damage relationships in bone.'

Dr Jae-Young Rho. University of Memphis (Tennessee). This is a tri-partite collaboration between myself, Jae and Peter Zioupos. Jae has a nanoindentor, capable of determining the hardness and Young's modulus of very small areas of bone. We have been doing work together on the properties of different layers in bone. Tragically, Jae-Young died at the very end of 2002, of a heart attack, at the unbearably early age of 43, leaving a wife and young family. So that collaboration has ended.