The possibility of a traumatic bone fracture in space is a concern due to the observed decrease in astronaut bone mineral density (BMD) during spaceflight and because of the physical demands of the mission. The Bone Fracture Risk Module (BFxRM) was developed to quantify the probability of fracture at the femoral neck and lumbar spine during space exploration missions. The BFxRM is scenario-based, providing predictions for specific activities or events during a particular space mission. The key elements of the BFxRM are the mission parameters, the biomechanical loading models, the bone loss and fracture models and the incidence rate of the activity or event. Uncertainties in the model parameters arise due to variations within the population and unknowns associated with the effects of the space environment. Consequently, parameter distributions were used in Monte Carlo simulations to obtain an estimate of fracture probability under real mission scenarios. The model predicts an increase in the probability of fracture as the mission length increases and fracture is more likely in the higher gravitational field of Mars than on the moon. The resulting probability predictions and sensitivity analyses of the BFxRM can be used as an engineering tool for mission operation and resource planning in order to mitigate the risk of bone fracture in space

Griffin, Devon

Lewandowski, Beth E.

Myers, Jerry G.

Nelson, Emily S.

NASA Technical Reports Server

RISK ASSESSMENT OF BONE FRACTURE DURING SPACE 
EXPLORATION MISSIONS TO THE MOON AND MARS 
 
B.E. Lewandowski1, J.G. Myers1, E.S. Nelson1, A. Licata2, D. Griffin1  
1. NASA Glenn Research Center, 21000 Brookpark Rd., Cleveland, OH 44135, 
Beth.E.Lewandowski@nasa.gov, Jerry.G.Myers@nasa.gov, Emily.S.Nelson@nasa.gov, 
Devon.Griffin@nasa.gov,  
2. Cleveland Clinic, 9500 Euclid Ave., Cleveland, OH 44195, licata@ccf.org 
 
Abstract 
The possibility of a traumatic bone fracture in space is a concern due to the observed decrease in 
astronaut bone mineral density (BMD) during spaceflight and because of the physical demands of the mission. 
The Bone Fracture Risk Module (BFxRM) was developed to quantify the probability of fracture at the femoral 
neck and lumbar spine during space exploration missions. The BFxRM is scenario-based, providing predictions 
for specific activities or events during a particular space mission. The key elements of the BFxRM are the 
mission parameters, the biomechanical loading models, the bone loss and fracture models and the incidence 
rate of the activity or event. Uncertainties in the model parameters arise due to variations within the population 
and unknowns associated with the effects of the space environment. Consequently, parameter distributions 
were used in Monte Carlo simulations to obtain an estimate of fracture probability under real mission 
scenarios. The model predicts an increase in the probability of fracture as the mission length increases and 
fracture is more likely in the higher gravitational field of Mars than on the moon. The resulting probability 
predictions and sensitivity analyses of the BFxRM can be used as an engineering tool for mission operation and 
resource planning in order to mitigate the risk of bone fracture in space. 
https://ntrs.nasa.gov/search.jsp?R=20080047428 2019-08-30T05:48:42+00:00Z
1www.nasa.gov
RISK ASSESSMENT OF BONE FRACTURE 
DURING SPACE EXPLORATION MISSIONS TO 
THE MOON AND MARS
Exploration Medicine Capabilities Project
Human Research Program
GRC/CCF IMM Team:
Jerry G. Myers, Jr. PhD
Beth Lewandowski, MS
Emily Nelson, PhD
Angelo Licata, MD, PhD
2www.nasa.gov
Topics to cover
• Overview of Integrated Medical Model (IMM) and 
Bone Fracture Risk Module (BFxRM)
• Definition of Fracture Risk Index (FRI)
• Library of biomechanical models used to estimate 
load on bones during activities and events
• Decrease of Bone Mineral Density (BMD) in space 
and relationship between BMD and ultimate strength 
of bone
• Model uncertainty
• Earth based validations of models
• Sample results – probability of fracture on moon and 
Mars missions
• Conclusions 
3www.nasa.gov
Integrated Medical Model (IMM)
• The Integrated Medical Model (IMM) is a tool for quantifying the
probability and consequences of medical risks 
• Integrate best evidence in a quantifiable assessment of risk
• Identify medical resources such as skills, equipment, and supplies 
necessary to optimize mitigation strategies.
Likelihood of occurrence, 
probable severity of 
occurrence, and 
optimization of treatment 
and resources.
Crew Dem
ographics and M
edical history
M
iss
io
n 
Pr
of
ile
Potential Medical 
Condition
Evaluate 
with IMM
4www.nasa.gov
Bone Fracture Risk Module (BFxRM)
Bone Loss in 
Space
courses.washington.e
du/me598rc 
Biomechanics 
and Mission 
Operations
0
2000
4000
6000
8000
10000
12000
14000
16000
0 0.2 0.4 0.6 0.8 1 1 .2
F e m o ra l N e ck  B M D  (g /c m ^ 2)
F
r
a
c
t
u
r
e
 
L
o
a
d
 
(
N
)
Bec k e t. A l, 1990
Hay es , My ers , 1996  (2mm/s )
Hay es , My ers , 1996  (100mm/s )
Kukla  e t. A l 2002
F ig u re  2 .  S u m m a ry  o f  lite ra tu re  s u rv e y  o n  fra c tu re  lo a d  a s  a  fu n c tio n  o f  fe m o ra l 
n e c k  B M D  
Clinical and 
Engineering 
Characteristics of 
Bone Strength
Estimate of 
Fracture Probability
Probability of 
Fracture 
Probability bone 
will fail to support 
load 
Probability 
of event
5www.nasa.gov
Fracture Risk Index (FRI)
• The ratio of the load experienced by the bone during an activity to the 
ultimate strength of the bone.
– An FRI of less than one indicates that the bone should be strong enough 
to support the load 
– An FRI of greater than one indicates that there is a significant risk of bone 
fracture. 
Chaffin DB, Baker WH, A biomechanical model for analysis of symmetric 
sagittal plane lifting, AIIE Transactions, 2(1), March 1970, pp. 16-27
Loads experienced by the bone are 
estimated with biomechanical models 
The ultimate strength of bone is found from 
testing the strength of cadaver bone
http://www.bartleby.com
Yoganandan N, Pintar F, Sances A, Maiman D, Mykelbust J, Biomechanical investigations of the 
human thoracolumbar spine, In Biomechanics of Impact Injuries and Injury Tolerances of the 
Abdomen, Lumbar Spine and Pelvis Complex, Edited by SH Backaitis, Society of Automotive 
Engineers, Inc., 1995, pp. 97 – 114.  
6www.nasa.gov
Library of biomechanical loading models
Pelvis and 
leg mass
Upper body
mass
Foot mass
Stiffness and damping 
of lumbar spine
Stiffness
of leg
Stiffness and damping 
of ground
Femoral Neck – Fall to the side
Lumbar Spine – Fall, 
landing on two feet
Lumbar Spine – Trunk flexed, 
holding a load
Load
CoM
Load on 
Spine
Hip mass
Stiffness and damping 
of hip pad and ground
S. N. Robinovitch, W. C. Hayes, and T. A. McMahon, "Prediction of femoral impact 
forces in falls on the hip," J. Biomech. Eng, vol. 113, no. 4, pp. 366-374, Nov.1991. 
A. Schultz, G. B. Andersson, R. Ortengren, R. Bjork, and M. Nordin, "Analysis and 
quantitative myoelectric measurements of loads on the lumbar spine when holding 
weights in standing postures," Spine, vol. 7, no. 4, pp. 390-397, July1982. 
K. J. Chi and D. Schmitt, "Mechanical energy and effective foot mass 
during impact loading of walking and running," J. Biomech., vol. 38, 
no. 7, pp. 1387-1395, July2005. 
7www.nasa.gov
BMD Loss in space over time
Data used to determine slope includes LSHA Data and 
Published Data and takes into consideration uncertainty
BMDDoE = BMD value on the day of the event
BMDStart = BMD at the beginning of the mission
BMDLoss = The amount of BMD loss prior to the day of the event
)1(
Start
Loss
StartDoE BMD
BMDBMDBMD −=
8www.nasa.gov
Relationship between BMD and Ultimate Load 
of bone for different loading conditions
K. Singer, S. Edmondston, R. Day, P. Breidahl, and R. Price, "Prediction of thoracic and lumbar vertebral body compressive strength - Correlations with Bone Mineral 
Density and vertebral region," Bone, vol. 17, no. 2, pp. 167-174, 1995. 
E. N. Ebbesen, J. S. Thomsen, H. Beck-Nielsen, H. J. Nepper-Rasmussen, and L. Mosekilde, "Lumbar vertebral body compressive strength evaluated by dual-energy X-
ray absorptiometry, quantitative computed tomography, and ashing," Bone, vol. 25, no. 6, pp. 713-724, Dec.1999.
D. P. Lindsey, M. J. Kim, M. Hannibal, and T. F. Alamin, "The monotonic and fatigue properties of osteoporotic thoracic vertebral bodies," Spine, vol. 30, no. 6, pp. 
645-649, Mar.2005. 
B. S. Myers, K. B. Arbogast, B. Lobaugh, K. D. Harper, W. J. Richardson, and M. K. Drezner, "Improved assessment of lumbar vertebral body strength using supine 
lateral dual-energy x-ray absorptiometry," J. Bone Miner. Res., vol. 9, no. 5, pp. 687-693, May1994.
9www.nasa.gov
Stiffness constants Damping constants
• Monte Carlo and Latin Hypercube simulations performed to determine 
most likely probability since:
– The system parameters (i.e. astronaut mass, reference BMD level, BMD 
loss per day, ultimate strength/BMD, anthropometric values, physiological 
stiffness and damping constants, angle of trunk flexion, load lifted, etc.)  are 
defined as distributions over a range of values.
– The event could happen on any day during the mission
BFxRM uncertainty
Astronaut Mass
Mission day of event
10www.nasa.gov
Earth based validations– Static lumbar spine 
model
Comparison of lumbar spine loading 
calculations
Comparison of FRI calculations
Condition 1 are young subjects
Condition 2 are elderly subjects
Y. Duan, E. Seeman, and C. H. Turner, "The biomechanical basis of vertebral body fragility in men and women," J. Bone Miner. Res., 
vol. 16, no. 12, pp. 2276-2283, Dec.2001. 
M. L. Bouxsein, L. J. Melton, III, B. L. Riggs, J. Muller, E. J. Atkinson, A. L. Oberg, R. A. Robb, J. J. Camp, P. A. Rouleau, C. H. 
McCollough, and S. Khosla, "Age- and sex-specific differences in the factor of risk for vertebral fracture: a population-based study using 
QCT," J. Bone Miner. Res., vol. 21, no. 9, pp. 1475-1482, Sept.2006. 
11www.nasa.gov
Earth based validations– Static lumbar spine 
model
Comparison of Ultimate Load 
vs. Age
Comparison of % FRI above 
1 vs. Age
M. L. Bouxsein, L. J. Melton, III, B. L. Riggs, J. Muller, E. J. Atkinson, A. L. Oberg, R. A. Robb, J. J. Camp, P. A. Rouleau, C. 
H. McCollough, and S. Khosla, "Age- and sex-specific differences in the factor of risk for vertebral fracture: a population-
based study using QCT," J. Bone Miner. Res., vol. 21, no. 9, pp. 1475-1482, Sept.2006. 
M. Biggeman, D. Hilweg, S. Seidel, M. Horst, and P. Brinckmann, “Risk of vertebral insufficiency fractures in relation to 
compressive strength predicted by quantitative computed tomography, ”Euro J Rad, vol. 13, pp. 6-10, 1991.
12www.nasa.gov
Earth based validations – Dynamic lumbar 
spine model
Comparison of Ground Reaction Force calculations
J. G. Seegmiller and S. T. McCaw, "Ground Reaction Forces Among Gymnasts and Recreational Athletes in Drop Landings," J. Athl. Train., vol. 38, no. 4, pp. 311-
314, Dec.2003.
A. Arampatzis, G. P. Bruggemann, and G. M. Klapsing, "Leg stiffness and mechanical energetic processes during jumping on a sprung surface," Med. Sci. Sports 
Exerc., vol. 33, no. 6, pp. 923-931, June2001.
A. Arampatzis, F. Schade, M. Walsh, and G. P. Bruggemann, "Influence of leg stiffness and its effect on myodynamic jumping performance," J. Electromyogr. 
Kinesiol., vol. 11, no. 5, pp. 355-364, Oct.2001.
A. Arampatzis, S. Stafilidis, G. Morey-Klapsing, and G. P. Bruggemann, "Interaction of the human body and surfaces of different stiffness during drop jumps," Med. 
Sci. Sports Exerc., vol. 36, no. 3, pp. 451-459, Mar.2004.
P. J. McNair and H. Prapavessis, "Normative data of vertical ground reaction forces during landing from a jump," J. Sci. Med. Sport, vol. 2, no. 1, pp. 86-88, 
Mar.1999.
P. Kwok, W. Kong, K. Kasturi, C. Lee, J. Hamill, “A biomechanical study on the parachute landing fall,” 17th AIAA Aerodynamic Decelerator Systems Technology 
Conference and Seminar, 19-22 May 2003, Monterey, CA., AIAA 2003-2149.
13www.nasa.gov
Earth based validations – Dynamic lumbar 
spine model
Comparison of fracture prediction for a fall height distribution
Our simulations predicted an FRI above 1 for 34.2% of the trials. Goonetilleke 
found 29.7% of falls in his study resulted in fracture.
U. K. Goonetilleke, "Injuries caused by falls from heights," Med. Sci. Law, vol. 20, no. 4, pp. 262-275, Oct.1980. 
14www.nasa.gov
Example results
Gender Mean Probability
Standard 
Deviation 5% 95%
Male 3.19e-4 1.17e-4 1.84e-4 5.36e-4
Female 3.28e-4 1.36e-4 1.8e-4 5.85e-4
Probability of fracture of the lumbar spine by a male or female astronaut 
due to lifting a load with the trunk flexed during an EVA during a long 
duration, Lunar mission.
Male Female
15www.nasa.gov
Example results
Gender
Mean 
Probability
Standard 
Deviation 5% 95%
Male 2.64e-3 5.36e-3 5.54e-5 1.19e-2
Female 3.02e-3 6.00e-3 5.97e-5 1.39e-2
Male
Probability of fracture of the lumbar spine by a male or female astronaut 
due to a 1m fall during an EVA during a long duration, Martian mission.
Female
16www.nasa.gov
Conclusions
• A model has been developed that bounds the 
uncertainty associated with the risk of bone fracture in 
space. 
– Integrative approach accounting for extenuating factors 
• Equipment and Vehicle 
• Bone Health 
• Training and Operations
• The model can be used to predict the most likely 
probability of bone fracture in space. 
– “what if” scenarios
• What if reduced gravity is osteo-protective?
• What if the FFD is reduced to t-score of -1.25?
• The model can be used as a useful engineering tool 
during mission planning.
17www.nasa.gov
Future Work
• Wrist fracture risk assessment
• Renal stone formation risk assessment
• Insomnia and circadian rhythm upset risk 
assessment
18www.nasa.gov
Acknowledgements
• The BFxRM was funded by the NASA Human Research 
Program, which is managed at the Johnson Space Center. 
• Contributors
– Tina Sulkowski, Student, University of Akron
– Kelley Ruehl, Student, Rose-Hulman Institute of Technology
• Special Thanks
– Jean Sibonga – Bone Team Lead NASA-JSC
– Peter Cavanagh – CCF/NSBRI
– Joyce Keyak and Tom Lang - NSBRI
– John Charles – Acting Chief Scientist HRP Program NASA-JSC
– ExMC and IMM development teams
19www.nasa.gov
Extra Slides
20www.nasa.gov
Calculating Bone Ultimate Structural Strength
State of Bone at 1g
Pre-Flight DEXA-BMD
Estimate Time Course to and Degree
Of Bone Loss at Skeletal Location
On day of loading
Use BMD correlations to
Estimate UL
Apply UL attenuation for 
load direction
Linear or Exponential Model
Posterolaterial fall: 
UL Reduced up to 
0.8% per Degree
NHANES DATA - Represents Pre-
Flight Bone Health, FFD Standards 
And Reference Max BMD Condition
Based on appropriate 
ex vivo test data
Ultimate Structural Load 
Capacity for Loading Conditions
Maximum Loss Est.
With Pop. Variability
Time
ΔBMD
Linear Loss Model
With Pop. Variability
0
1000
2000
3000
4000
5000
6000
7000
8000
9000
10000
0.35 0.45 0.55 0.65 0.75 0.85 0.95 1.05 1.15 1.25
DEXA-BMD @ Trochanter (g/cm^2)
U
l
t
i
m
a
t
e
 
L
o
a
d
 
(
N
)
Female
Male
Average
CF - female
CF - Male
Male: UL = 11249*BMD -3510
R^2 = 0.88, SEE = 613
Female: UL = 9231*BMD -2546
R^2 = 0.83, SEE = 515
21www.nasa.gov
Calculating Loading in Reduced Gravity 
Environment
Loading Event Occurs
From Specified
Activity or Incident
Estimate of Load
w/ 1g Biomechanics 
Scale Load to Gravity Level
Using Appropriate Methods
Determine Load Additive or
Attenuation Factors
Resultant Skeletal Load
EVA Suit
Mass & Padding
Active Response
Represents a perceived 
loading state during on 
surface activities
Uses the change in momentum
Includes additional mass
 
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UPDATE: Newest models use 
simulations based on Robinovitch 
type loading simulations
22www.nasa.gov
Tying It All Together:  Falls to the Side 
Impacting Proximal Femur
 
Probability of 
FN Fracture 
Probability bone 
will fail to 
support load 
Probability fall is 
posteriorlateral  
Probability of 1 
or more Falls 
Apollo 
Data 
FRI Estimates 
From BFRM 
• Bone Loss 
• Bone Strength / 
Quality 
• Loading Levels in 
Hypo-g 
• Mission 
Characteristics 
• Equipment / Suit 
Characteristics 
Published 
Data 
Relating 
FRI and 
Fracture 
Probability 
 
0
0.2
0.4
0.6
0.8
1
1.2
0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6
FRI
P
r
o
b
a
b
i
l
i
t
y
 
o
f
 
F
r
a
c
t
u
r
e
mu = 0.58, theta = 7.7
mu = 0.95, theta = 15
mu = 0.58, theta = 15
mu = 0.95, theta = 7.7
Fall Rate: 0.35/hr and σ = 0.066
Pr(Postlat): 0.0517 and σ = 0.0404 Estimated upper and lower bounds:
FRI To Probability of Fracture
23www.nasa.gov
Pre-flight estimate of FRI for Unhindered Posteriolateral Fall 
i.e. a fall to the side and slightly backward
Male in 1g with ~1m fall heights 
“Smell” Test Validation
 
Lang et al 2006
Mean +/- 2 SD
M = 2.1
SD = 0.47
IMM-BFRM
Mean = 1.98
SD = 0.90
M
F
M
F
Schaffner
Results
24www.nasa.gov
Probability of Fracture Due to Side Falls 
Male on Extra Vehicular Activity
Mission Fracture Probability Std 5th Percentile 95th Percentile
Lunar: 8D Surface 1.50E-4 1.15E-3 3.30E-07 5.36E-04
Lunar: 170D Surface 1.94E-4 1.54E-3 3.47E-07 6.15E-04
Mars: 40D Surface 1.44E-3 7.66E-3 1.15E-06 4.85E-03
Mars: 540D Surface 2.47E-3 9.95E-3 1.68E-06 1.15E-02
Lateral/Posteriolateral Fall heights range from .25m to ~1m
Bone loss not attenuated by partial gravity
FRI  = 0.28 ± 0.20
Data Shown for Mars: 540D Surface Mission
25www.nasa.gov
Model Sensitivity
• The suit attenuation characteristics and the impulse scaling factors 
produce the most sensitivity
• Interesting to note that
– Successful reaction to the fall is the next most driving factor
– Bone loss rates are not as significant for lunar missions
– Reference BMD produces more sensitivity to the calculation than rate of 
bone loss in both scenarios
Lunar: Long Mars: Long


Risk Assessment of Bone Fracture During Space Exploration Missions to the Moon and Mars

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