the university of sydneypage 1 bone remodelling andrian sue amme4981/9981 week 9 semester 1, 2015...

The University of Sydney

Bone Remodelling

Andrian SueAMME4981/9981Week 9Semester 1, 2015

Lecture 7


Mechanical Responses of Bone

– Bone microstructure– Descriptions– Imaging

– Bone constitutive models and relationships– Stiffness and apparent

density– Bone remodelling

mechanisms– Physiological responses

to mechanical stimuli– Models of bone responses

– Simple example calculations

Body kinemati

cs

Biomaterial

mechanics

Biomaterial

responses


Bone microstructureDescription and clinical imaging


Description of bone microstructure and composition

– Five major functions: load transfer; muscle attachment; joint formation; protection; hematopoiesis

– Composition and structure of bone heavily influences its mechanical properties– Collagen fibres– Bone mineral (hydroxyapatite)– Bone cells (osteoblasts, osteoclasts, osteocytes)

– Two classes of bone structure– Cancellous (or spongy) bone– Cortical (or compact) bone


Description of cortical bone microstructure


Bone imaging modalities

– DXA – Dual energy X-ray Absorptiometry– Provides bone mineral

density (BMD)– Commonly used to diagnose

osteoporosis (based on BMD)– Two beams are used and soft

tissue absorption is subtracted– MRI – Magnetic Resonance

Imaging– Ideal for soft tissues– Commonly used to examine

joints for soft tissue injuries– fMRI for brain studies

– CT – X-Ray Computed Tomography.– Ideal for hard tissues.

MRI scan of the knee joint


DXA – Dual Energy X-Ray Absorptiometry

GE Lunar DEXA Systems

http://www.gehealthcare.com/inen/rad/bonedens/bdcommunity/prodimages.html


Imaging of bone microstructure

– To examine the bone microstructure, high resolution scanning is required

– Micro-CT and Nano-CT options have high resolution that allows visualisation of bone microstructure

Imaging Modality

Max. Resolution (in-vivo) in microns

Medical CT 200 x 200 x 200

3D-pQCT 165 x 165 x 165

MRI 150 x 150 x 150

Micro-MRI 40 x 40 x 40

Micro-CT 5 x 5 x 5

Nano-CT 0.05 x 0.05 x 0.05


Micro-CT of bone microstructure

– MicroCT Scanner (SkyScan 1172).

– Micro-CT scan sectional image segmentation 3D image (STL)

– Limited field of view


Microstructural changes in cancellous bone

– Right: decreasing bone density with age as indicated.

– Bottom: comparison of bone density between a healthy 37-year-old male (L) and a 73-year-old osteoporotic female (R).

32-year-old male

59-year-old male

89-year-old male


Bone constitutive modelsStiffness and apparent density relationships


Power law relationship for cancellous bone stiffness

– Well-established relationship between apparent density (ρ) and cancellous bone Young’s modulus (E)

– a, p are empirically determined constants

𝐸=𝑎𝜌𝑝

References p R2

Carter and Hayes (1977) J Bone Joint Surg Am, 59:954 3.00 0.74

Rice et al. (1988), J Biomech 21:155. 2.00 0.78

Hodgkinson and Currey (1992), J Mater Sci Mater Med 3:377

1.96 0.94

Kabel et al. (1999), Bone 24:115 1.93 0.94


Power law models for cancellous bone

– Hodgkinson – Currey model (1992)– Kabel isotropic model (1999)

– Yang (1999) – orthotropic cancellous model

φ – volume fraction and ρ – 1800φ kg/m3

𝐸𝑚𝑒𝑎𝑛=0.003715 𝜌1.96

𝐸=𝐸𝑡𝑖𝑠𝑠𝑢𝑒 813𝜑1.93=𝐸𝑡𝑖𝑠𝑠𝑢𝑒813( 𝜌

1800 )1.93

=𝐸𝑡𝑖𝑠𝑠𝑢𝑒0.000424 𝜌1.93


Orthotropy of bone

– Material possesses symmetry about three orthogonal planes

– 9 independent components

– 3 Young’s moduli:

– 3 Poisson’s ratios:

– 3 shear moduli:

1

2

3

{𝜖11𝜖22𝜖332𝜖232𝜖132𝜖12

}=[1𝐸1

−𝜈12𝐸1

−𝜈13𝐸1

0 0 0

−𝜈12𝐸2

1𝐸2

−𝜈23𝐸2

0 0 0

−𝜈13𝐸3

−𝜈23𝐸3

1𝐸3

0 0 0

0 0 01𝐺23

0 0

0 0 0 01𝐺31

0

0 0 0 0 01𝐺12

]{𝜎11𝜎22𝜎33𝜎23𝜎13𝜎12}


Orthotropic constitutive models of cortical bone

E3 (axial)

E2 (circumferential)

E1 (radial)

Young’s modulus

Poisson’s ratio Shear modulus

E1=6.9GPa 12=0.49, 21=0.62 G12=2.41GPa

E2=8.5GPa 13=0.12, 31=0.32 G13=3.56GPa

E3=18.4GPa 23=0.14, 32=0.31 G23=4.91GPa

Young’s modulus

Poisson’s ratio Shear modulus

E1=12.0GPa 12=0.376, 21=0.422 G12=4.53GPa

E2=13.4GPa 13=0.222, 31=0.371 G13=5.61GPa

E3=22.0GPa 23=0.235, 32=0.350 G23=6.23GPa

(Humpherey and Delange, An Introduction to Biomechanics, 2004)

Tibia

Femur


Homogenisation techniques for bone microstructure

Voxel-based FE model(element size: 25 microns)

– Directly transfer voxel to element (Grid mesh)

– Large number of elements– Stress concentration

Solid-based FE model(element size: 150 microns)

– Segmentation process– Smoothing, creation of

geometry– Control of meshing

algorithmsPerform static FEA under simple loading to determine the effective

stiffness of these structures


Bone remodelling mechanismsPhysiological responses to mechanical stimuli


Concept of bone remodelling

– Living tissues are subject to remodelling/adaptation, where the properties change over time in response to various factors

– “every change in the function of bone is followed by certain definite changes in internal architecture and external conformation in accordance with mathematic laws.” – Julius Wolff (1892)

– Cancellous bone aligns itself with internal stress lines


Structural remodelling in bones

– Remodelling or adaptation can occur when there are changes in tissue environment, such as:– Stress/strain/strain

energy density– Loading frequency– Temperature– Formation of micro-

cracks– A good example is to look at

the growth of trees around external structures– Thickening of branches

near fences/gates– Natural optimisation

Mattheck (1998)


Variations in bone remodelling responses

– Bone remodelling is thought to be mediated by osteocytes– Site dependency

– Different bones provide different mechanical function– Different sites have different biological environment– Results in different remodelling equilibrium

– Time dependency– High frequency (25 Hz) vs low frequency– Large load and low frequency can prevent mass loss– At higher frequencies, substantial bone growth is

possible– Fading memory effects, i.e. adaptation of tissue to

mechanical stimulation


Mechanical signal transduction in bones

– Bone transduces mechanical strain to generate an adaptive response– Piezoelectric properties of

collagen– Fatigue micro-fracture

damage-repair– Hydrostatic pressure of

extracellular fluid influences on bone cell

– Hydrostatic pressure influences on solubility of mineral and collagenous component, e.g. change in solubility of hydroxyapatite

– Creation of streaming potential

– Direct response of cells to mechanical loading

These are all mechanisms which may allow mechanical strain to be detected by bone


Bone remodelling by micro-fracture repair

Increased stress causes cracks in bone microstructure

Triggers osteoclast

formation to remove

broken tissue

Osteoblasts are then

recruited to help form new

bone

Osteoblasts become

osteocytes and maintain

bone structure


Bone remodelling by dynamic loading

– Dynamic loading is much more effective at stimulating bone growth.– Burr et al. (2002) found that dynamic loading forces fluids through

canalicular channels, stimulating osteocytes by increased shear stresses.

http://www.nature.com/nature/journal/v412/n6847/fig_tab/412603b0_F1.html


Models of bone responsesBone remodelling calculations


Mechanical stimuli - ψ

– Strain energy density

– Energy stress – linearise the quadratic nature of U

– Mechanical intensity scalar (volumetric shrinking/swelling)

– von Mises stress (σ1,σ2,σ3 – principal stresses)

– Daily stresses (ni = number of cycles of load case i, N = number of different load cases, m = exponent weighting impact of load cycles)

𝜓=𝑈=12

{𝜎 }𝑇 {𝜀 }=12[𝜎11 𝜀11+𝜎22𝜀22+𝜎33𝜀33+𝜎12𝜀12+𝜎13𝜀13+𝜎 23𝜀23 ]

𝜓=𝜎𝑒𝑛𝑒𝑟𝑔𝑦=√2𝐸𝑎𝑣𝑔𝑈𝜓=𝜗=𝑠𝑖𝑔𝑛(𝜀11+𝜀22+𝜀33)√𝑈

𝜓=𝜎𝑣𝑚=√ 12 [ (𝜎 1−𝜎2 )2+ (𝜎 2−𝜎3 )2+ (𝜎 3−𝜎1 )2 ]

𝜓=𝜎𝑑=(∑𝑖=1

𝑁

𝑛𝑖𝜎 𝑖𝑚)

1𝑚


Continuum model of bone remodelling

– Surface remodelling – changes in external geometry of bone (cortical surface) over time, e.g. radius of bone

Ψ(t) – Mechanical stimulus. It may also change with time.Ψ*(t) – Reference stimulus

– Internal remodelling – changes in a material property over time, e.g. apparent density

[𝑆 ]=[𝑆 (𝑡 )] [𝐶 ]=[𝐶 (𝑡 )]


Surface remodelling

– Stimulus Error: deviation of stimulus from some baseline/ref. value.

– Surface Remodelling Rate: cs is a given constant.

– Surface Remodelling Rule with Lazy Zone: ws defines the lazy zone.

𝑒=𝜓 (𝑡 )−𝜓∗(𝑡)

𝑑𝑠𝑑𝑡

= �̇�=𝑐𝑠 [𝜓 (𝑡 )−𝜓∗ (𝑡 ) ]=𝑐𝑠𝑒

�̇�={𝑐𝑠 [𝜓 (𝑡 )−𝜓∗ (𝑡 )−𝑤𝑠 ]0

𝑐𝑠 [𝜓 (𝑡 )−𝜓∗ (𝑡 )+𝑤𝑠]

for 𝜓 (𝑡 )−𝜓∗ (𝑡 )>𝑤𝑠

for −𝑤𝑠<𝜓 (𝑡 )−𝜓∗ (𝑡 )<𝑤𝑠

for𝜓 (𝑡 )−𝜓∗ (𝑡 )<−𝑤𝑠


The lazy zone model

*

Dead zoneLazy zone

0

s

Alternative remodelling rule without lazy zone:


Internal remodelling

*

Dead zoneLazy zone

0

Alternative remodelling rule without lazy zone:


Finite element model workflow

Computestress/strain

tensor

Modifysurface

orBone

density

UpdateFEA

Model

UpdateGeometry or

MaterialProperty

Applyremodelin

g rule

Yes

EquilibriumNo


Calculations!


Example: Bone loss in space

Human spaceflight to Mars could become a reality within the next 15 years, but not until some physiological problems are resolved, including an alarming loss of bone mass, fitness and muscle strength. Gravity at Mars' surface is about 38% of that on Earth. With lower gravitational forces, bones decrease in mass and density. The rate at which we lose bone in space is 10-15 times greater than that of a postmenopausal woman and there is no evidence that bone loss ever slows in space. NASA has collected data that humans in space lose bone mass at a rate of c =1.5%/month. Further, it is not clear that space travelers will regain that bone on returning to gravity. During a trip to Mars, lasting between 13 and 30 months, unchecked bone loss could make an astronaut's skeleton the equivalent of a 100-year-old person.


Bone loss in space: derivation of bone density changes

– Bone remodelling sans lazy zone

– 𝜓 is the Mars stress level, * is the Earth stress level𝜓

�̇�=𝑑𝜌𝑑𝑡≈Δ𝜌Δ𝑡

= 𝜌𝑛+1− 𝜌𝑛

Δ 𝑡=𝑐 𝜌 [𝜓 (𝑡 )−𝜓∗ (𝑡 )

𝜓∗ (𝑡 ) ]𝜌𝑛+1=𝜌𝑛+𝑐𝜌 [𝜓 (𝑡 )−𝜓∗ (𝑡 )

𝜓∗ (𝑡 ) ]Δ𝑡


Critical bone loss in space

– How long could an astronaut survive in space if we assume the critical bone density to be 1.0 g/cm3? Initial bone density on Earth is ~1.79 g/cm3.


Example: simply loaded femur

– Take strain energy density as mechanical stimulus, ψ

– Surface remodelling rate equation with lazy zone

FS

S

x

y

l l

zF

Section S-S

x

y

Cortical

CancellousR

r

𝜓=𝑈=12

{𝜎 }𝑇 {𝜀 }=12[𝜎 𝑥𝑥𝜀𝑥𝑥+𝜎 𝑦𝑦𝜀𝑦𝑦+𝜎 𝑧𝑧 𝜀𝑧𝑧+𝜎 𝑥𝑦𝜀𝑥𝑦+𝜎 𝑦𝑧 𝜀𝑦𝑧+𝜎𝑧𝑥 𝜀𝑧𝑥 ]

�̇�={𝑐𝑠 [𝜓 (𝑡 )−𝜓∗ (𝑡 )−𝑤𝑠 ]0

𝑐𝑠 [𝜓 (𝑡 )−𝜓∗ (𝑡 )+𝑤𝑠]

for 𝜓 (𝑡 )−𝜓∗ (𝑡 )>𝑤𝑠

for −𝑤𝑠<𝜓 (𝑡 )−𝜓∗ (𝑡 )<𝑤𝑠

for𝜓 (𝑡 )−𝜓∗ (𝑡 )<−𝑤𝑠


Spreadsheet calculation for simply loaded femur

Assume lazy zone half-width is 10% of ψ*, so: ψ- ψ* > 0.1 x ψ*Modelled for 18 months, bone growth slows and equilibrium is reached


Spreadsheet calculation for dynamically loaded femur

Force is increased by 10 N every month: F(m+1) = F(m) + 10;Reference stimulus increased by 5% per month: Ψ*(m+1) = 1.05Ψ*(m)


Static vs dynamic loading cases in the femur

0 2 4 6 8 10 12 14 16 18 200.019

0.0195

0.02

0.0205

0.021

0.0215

Months

Rad

ius

(m)


Summary

– Bone microstructure and composition– Bone constitutive models– Bone remodelling mechanisms– Bone remodelling calculations

– Assignment 3 handed out today, due week 13– Group project reports and presentations are due in week 13– Quiz in week 12

the university of sydneypage 1 bone remodelling andrian sue amme4981/9981 week 9 semester 1, 2015...

Documents

structure of bone

imaging of bone microstructure

compact bone slide

university of sydneypage

decreasing bone density

comparison of bone density

cancellous bone right

spongy bone cortical