Last month I posted a message regarding Euler Angle sequences
for describing 3D scapular motion. I asked if there is any FUNDAMENTAL
motivation for the selection of a particular sequence that would make it
the "best" sequence and how does this relate to the description of
scapular rotations?
In this followup posting, I have included a summary of the suggestions
I received and the complete text of those responses. I appologize for
length of this posting, but it was necessary for completeness.
Thanks to all those who responded.
 Andy
__________________________________________________ ________
Andrew Karduna, Ph.D.
Assistant Professor, Department of Physical Therapy
Biomechanics Laboratory, 219 N Broad St
Allegheny University of the Health Sciences
Philadelphia, PA 19107
fax: (215) 7626076 phone: (215) 7625057
karduna@auhs.edu
__________________________________________________ _______
SUMMARY
There appears to be a consensus that there is no FUNDAMENTAL
or CORRECT order of rotations and that it is difficult to use
conventions from other bones because there is no "long axis"
of the scapula.
Here are some of the suggestions I have received:
 Select the sequence that most clearly demonstrates a consistent
difference between normal and a pathological movement.
 Use the relationship between Euler and projected angles to help.
 Instead of Euler Angles, use the attitude vector.
 Use the standard proposed by Frans van der Helm at
http://wwwmr.wbmt.tudelft.nl/schouder/dsg/standardization.html
 Use the to Angulus Acromialis (posteriorlateral ridge of acromion)
instead of the AC joint to avoid gimbal lock.
RESPONSES

1) Frances T. Sheehan  sheehan@me.udel.edu
 Reply 1
I have not worked on the shoulder joint at all, but have ran into
similar difficulties when trying to describe the 3D movement of
the knee. Basically, the orientation of 2 bodies is completely
described by the orientation matrix (3x3 quantity) ONCE a set of
reference frames have been fixed in both bodies. So, the first
question to ask is:
1) How are you defining your reference frames and are they
consistent from experiment to experiment? Without consistent reference
frames, you don't have a chance at comparing data.
Next, there are numerous methods for "simplifying" the
orientation matrix.
If you are planning on using 3 orientation angles, there are 24 different
geometric series you can use. Typically, the only constraint in choosing
a sequence is mathematical (i.e., avoiding gimbal lock, as you noted).
If you are trying to define a normal versus a pathological movement
pattern, I would choose the sequence that most clearly demonstrates a
consistent difference.
 Reply 2
It may sound post hoc to choose a sequence that best defines the
pathology, but depending upon your aims, I think it can be very useful.
First, the 3D orientation angles are not biological, they are a
mathematical simplification of a complex 3D event (as your different
results show). Thus, if you are trying to derive a test to define
healthy versus pathological, it makes sense to process all the sequences
and determine which one provides the largest statistical difference.
Clinically, this is the standard method for processing data. For example,
in investigating patellar tracking problems various 2D angles are typically
analyzed and the researchers try to define which single quantity provides
the clearest definition of the pathology.
Of course, if you are attempting to derive a cohesive description of
kinematics, regardless of the state of the joint, you are best of
choosing just one orientation angle sequence and sticking with it.
Frances T. Sheehan, Ph.D.
126 Spencer Hall (Office 312)
Mechanical Engineering Department
University of Delaware
Newark, Delaware 197163140
(302) 8311013 (phone)
(302) 8313619 (fax)

2) Ingram Murray  I.A.Murray@newcastle.ac.uk
I was quite amazed to see your posting on BiomechL as I was
about to post almost the same question myself. I am
looking at motion of the humerus in relation to the scapula and have
over the last couple of days trawled through the summary of the
arguments in the archives, which though very entertaining failed to
answer the question I had which was  why are some sequences better
than others ? (specifically related to the JCS of Grood and Suntay (1983))
I have recently carried out some work related to the movement at the
shoulder and found like you that there is quite a discrepancy in
results when using each of the six possible sequences. In my work
I found the sequence suggested by Cole et al (1993) to give
considerably better results than any of the others but have had
difficulty convincing myself why this is the case.
Although I'm afraid all this falls into the 'General Reply' category
and is not of specific help in your case, I would be very grateful if
you could forward me any relevant replies than give a reasonable
explanation of the different results obtained by applying different
sequences.
Ingram Murray
CREST
Room G32
Stephenson Building
University of Newcastle upon Tyne
Newcastle upon Tyne
NE1 7RU
UK

3) Neil Crawford  ncrawfo@mha.chw.edu
 Reply 1
Unlike other joints that have a clear plane of symmetry or a long axis,
it is not so clear which is the appropriate Euler/Cardan sequence for
the scapula. However, with your knowledge of scapular anatomy, you may
be able to decide which is the appropriate projection angle to use in
each plane, and then you can use the relationship between projection
angles and Euler angles to choose the appropriate Euler sequence.
In each plane, there are two possible projection angles. For example,
looking down the xaxis at the yz plane, it is clear that the
projection angle about the xaxis (Px) can be described either by the
projection of a vector j initially aligned with the yaxis (Pxj) or a
vector k initially aligned with the zaxis (Pxk). There is usually an
Euler/Cardan sequence that corresponds to the different projection
sets. The relationship between projection angle sets and Euler angle
sets is:
Projection Euler
Angle set Sequence
 
Pxj, Pyi, Pzi Rx>Ry>Rz
Pxj, Pyi, Pzj Ry>Rx>Rz
Pxj, Pyk, Pzi (none)
Pxj, Pyk, Pzj Ry>Rz>Rx
Pxk, Pyi, Pzi Rx>Rz>Ry
Pxk, Pyi, Pzj (none)
Pxk, Pyk, Pzi Rz>Rx>Ry
Pxk, Pyk, Pzj Rz>Ry>Rx
(no corresponding Euler sequence in the 2 cases where you use each axis
once in the projection angles)
You can choose the appropriate projection angles if you can
identify a plane of symmetry for scapular movement and determine that
motion about one of the three coordinate axes is different in nature
from the other two (for instance, at a motion segment in the spine or
at the wrist joint, there are two "bending" motions and one "twisting"
motion). If two of the motions are similar in nature (like the 2
bending motions), they should be described by the same vector projected
in different planes (e.g., xaxis rotation and yaxis rotation can both
be described by projecting the k vector, which was initially aligned with the
zaxis: Pxk and Pyk). Also, motion describing deviation from a plane of
symmetry should use a vector initially in that plane (e.g., if the yz
plane is a plane of symmetry, such as the midsagittal plane in the
spine, Pyk and Pzj are preferred over Pyi and Pzi since the former two
angles use vectors that were initially in the plane of symmetry while
the latter two do not).
I hope this explanation is not too convoluted. For a clearer
presentation, see Crawford et al., "Methods for determining spinal
flexion/extension, lateral bending, and axial rotation from marker
coordinate data: Analysis and refinement", Human Movement Science
15:5578, 1996.
If you cannot choose the appropriate projections using this
method, I would suggest using whatever has most commonly been reported
for scapular movement as long as the second Euler angle does not
approach 90 degrees.
 Reply 2
Regarding the correspondence between Euler angles and projection angles,
there is one Euler angle per sequence (the third rotation when rotations
are taken about global fixed coordinates) that is mathematically
identical to a certain projection angle. For the Euler sequence
Rx>Ry>Rz, the third angle Rz is mathematically identical to the
projection angle Pzi (the projection of the i vector on the plane
perpendicular to the zaxis). The equation for both Rz in this sequence
and Pzi is Rz=Pzi=atan2(iy,ix). (sorry, it's hard to write equations
without subscripts, etc. iy and ix are the y and x components of the i
vector, the unit vector that was initially aligned with the xaxis
before the rotation).
The other two Euler angles for a given sequence are not identical to any
particular projection angle, but for angles less than about 30 degrees
(which is most of the range of motion of many joints), they are much
closer to one of the two projections in a given plane than to the
other. Rx in the sequence Rx>Ry>Rz is more closely approximated by
Pxj than by Pxk. Ry in the sequence Rx>Ry>Rz is more closely
approximated by Pyi than by Pyk. The reason can be understood by
looking at the equations for the angles. Ry from Rx>Ry>Rz is
Ry=atan2(iz,ix cos Rz + iy sin Rz) while Pyi=atan2(iz,ix) and
Pyk=atan2(kx,kz). If Rz is small, then cos Rz approaches 1 and sin Rz
approaches 0. Then, the equation for Ry reduces to Ry~=atan2(iz,ix)
Ry>Rz
is Rx=atan2(kx sin Rz  ky cos Rz, jy cos Rz  jx sin Rz) while
Pxj=atan2(jz,jy) and Pxk=atan2(ky,kz). If Rz is small,
Rx~=atan2(ky,jy) From my limited experience experimenting with these rotation sequences,having the largest rotation as the last rotation is the most confusing from a
clinical perspective. I realize this "clinical perspective" isn't a
very strong rationale. I think much of the difficulty arises because of our
tendency (or at least mine) to want to interpret these rotations as the
"path" of motion rather than a position description that needs to
consider all of the rotations and the sequence used. As far as the potential
singularity or "gimbal lock" problem with upward rotation as the second
rotation, even using the AC joint in the axis definition, 90% of the
subjects I have tested have had values below 70 degrees during abduction
of the arm in the scapular plane. I do not test them at the extremes of
their range of motion, however.
 Reply 2
I haven't seen Jurriaan de Groot's thesis but the statement makes sense.
I would roughly estimate using the posterior acromion would decrease the
upward rotation numbers maybe ten degrees or so. I actually digitized
both the posterior lateral acromion and the AC joint in my latest study,
but have presently calculated the data only using the AC joint. I like
that point because I think the plane of the scapula is more correctly
defined but it does increase the upward rotation values from the
traditional clinical numbers. I collected both points to allow me to
potentially experiment with this a bit and compare to the published data
in both formats. I actually think these local coordinate system
definitions are more critical than the rotation sequences for
"standards" since it is more difficult to convert the data. Perhaps using
the y coordinate of the AC joint and z coordinate of the posterior acromion
would be ideal (assuming x lateral, y anterior, and z superior on the
right shoulder) but I realize that would be somewhat bizarre...
Paula Ludewig
The University of Iowa

7) Frans C.T. van der Helm  F.C.T.vanderHelm@wbmt.tudelft.nl
The subject of defining a standardized rotation sequence for rotations
of the shoulder bones had my interest for some time. On request of the
ISB, I wrote together with Jesus Dapena recommendations for a
standardization effort of the ISB. No definite decision has been taken
on that issue. Since then, we made a few adaptations, and I wrote a
paper on standardization for the First Conference of the International
Shoulder Group (Delft, The Netherlands, 1996):
Frans C.T. van der Helm (1996). A standardized protocol for motion
recordings of the shoulder. Proc. First Conf. of the International
Shoulder Group (Eds: HEJ Veeger, FCT van der Helm, PM Rozing), Delft,
The Netherlands, pp. 712.
Euler/Cardan angles have been chosen to describe motions. For the
scapula with respect to the thorax, the following choice has been made:
A local coordinate systems has been defined with respect to bony
landmarks as follows:
Xsaxis: Along the scapular spine, from Trigonum Spinae (TS)
to Angulus Acromialis (AA)
Zsaxis: Perpendicular to the scapular plane, defined by TS, AA
and Angulus Inferior (AI)
Ysaxis: Perpendicular to Xs and Zs, hence in the scapular plane.
Rotations are interpreted with respect to a starting position of the
scapula aligned with the Local coordinate system of the thorax:
Ytaxis: (IJ + C7)/2  (PX + T8)/2 (and normalized. )
(IJ: Incisura Jugularis; C7: proc. spinosus 7th Cervical Vertebra;
PX: Processus Xiphoideus; T8: proc. spinosus 8th Thoracic Vertebra)
Xtaxis: Yt x (C7  IJ) (vector product)
Ztaxis: Xt x Yt
Rotation order:
Pro/retraction about the Ysaxis, defines the angle of the scapular
spine w.r.t. the frontal plane.
Lateral/medial rotation about the Zs'axis (moved by the previous
rotation), i.e. rotation in the scapular plane
Tipping forward/backward about the Xs"axis (scapular spine, moved by
the previous rotations).
Rationale:
The first two rotations define the orientation of the scapular spine in
space, the last rotation is a rotation about the scapular spine. It is
preferred to have the last rotation about a longitudinal axis of the
bone, however for the scapula there is no unique longitudinal axis. The
second rotation can result in gimbal lock problems (if the rotation
angle approaches 90 degrees), therefore AA has been chosen instead of
the acromioclavicular joint (AC), as in previous recommendations of our
group. The order of rotations is close to interpretation of medical
terminology. Note that the zerozerozero orientation (starting
position) is not a feasible orientation of the scapula, due to the
motion constraints of clavicle and thorax!
In my opinion, there is no FUNDAMENTAL argument to choose for the one or
other rotation order. Interpretation of rotation in combination with
avoidance of gimbal lock should be the first rationale, and
interpretation is certainly subjective. It is important to define local
coordinate systems with respect to bony landmarks. If one uses the same
bony landmarks, every definition can be reconstructed. However, it is
preferred to use a standardized definition in order to improve the
communication between researchers and clinicians.
Frans C.T. van der Helm, PhD
ManMachine Systems & Control group
Dept. of Mechanical Engineering
Delft University of Technology
Mekelweg 2
2628 CD Delft
The Netherlands
tel. (+31)152785616
fax. (+31)152784717
email: F.C.T.vanderHelm@wbmt.tudelft.nl

8) Jurriaan de Groot  J.H.degroot@wbmt.tudelft.nl
 Reply 1
I agree with you that there should be an agreement on the definition of
the rotation axes, rotation order and defined initial position for the
description of motions of the shoulder bones.
As a part of my Ph.D. thesis I looked at the accuracy of the Cardan
parameters by which the scapular Cardan angles can be expressed. I must
confess that the choice of rotation axes and rotation order where
initially based on the traditions within our group. The arguments for
these definitions however were rather convincing, based on the fact that
the rotations should be interpretable and accurate.
Your questions were:
1) Is there any FUNDAMENTAL (mechanical, clinical or mathematical)
motivation for the selection of a particular sequence that would make
it the "best" sequence? and
2) How does this relate to the description scapular rotations?
I think that the 'best sequence' is not unique. A mathematical best sequence
will e.g. be based on the most accurate description, the
clinical best will be based in the interpretation of the angles.
To my opinion the best sequence for the scapula will be one that is well
interpretable (e.g. in the clinic) and in which the variability introduced
by the definition is negligibly small with respect to the variability of
intra and interindividual shoulder motions.
The best sequence depends on:
1  the axis definition with respect to the recordable landmarks.
2  the definition of the initial reference position.
3  the need of interpretation of the rotations.
4  the wish to describe bony motions or joint motions
Van der Helm and Pronk 1995 (J.Biom.Eng 117: 2740) define the
orientation of the scapula with respect to a 'vertical' thorax. The
rotation axes are based on palpable bony landmarks: the
acromioclavicular joint [AC], the angulus acromialis [AA], the trigonum
spinae [TS] and the angulus inferior [AI].
Three perpendicular axes were defined:
 A mediallateral axis defined by the landmarks TS and AC (Sxaxis).
 An anteriorposterior axis, perpendicular to the 'scapular plane'
defined by AC,TS and AI (Sz axis).
 A caudalcranial Syaxis perpendicular to the Sz and Sx axis.
The missing longitudinal axis of the scapula could be referred to as the
axis between the ACjoint and the GHjoint, but the rotations would not
be very interpretable.
In the initial 'reference' position all axes of the scapula were
aligned with the axes of the thorax. Otherwise an predefined
thoraxarm posture should be agreed in order to be able to compare
recorded data.
The chosen rotation order was SySzSx, which agrees to the definition
mentioned in the original posting: protractionelevationtilt.
The order is motivated by the fact that the second rotation should be
the largest rotation of a clear structure (the scapular spine),
preceeded by a rotation that defines the plane of the second rotation.
In case of the scapula, the second rotation is the elevation of the
scapular spine, preceeded by the initial rotation to align the scapula
to the 'tangential plane' of the curved thorax. As such the scapular
elevation coincides best with the elevation in the scapular plane
The choice of rotation order is not based on mechanical or mathematical
motivation but purely on interpretation of the resulting angles
(clinical).
However, if the second rotation is in the order of 90 degrees one must
be aware of the problems of the indetermined gimballock position. In a
study in which the total variation the recorded motions was
identified, it was shown that the scapula position based on the AC, TS
and AI landmarks, was liable to this gimballock inaccuracy (Groot 1998,
Clin. Biomech. in press]. Using the AAlandmark instead of the AClandmark
hardly changes the interpretation of the recorded angles, and reduces the
gimballock to a negligible influence.
Concluding: the chosen rotation order of Van der Helm and Pronk (1995)
combined with the coordinate system based on AA, TS and AI (Groot 1998)
and referred to an initial scapular reference position which is aligned
with the thorax coordinate system, results in an accurate and
interpretable description of the scapular motions.
An advantage of this description is, that the global orientation of the
scapula can be recorded directly by means of a scapula locator, used by
Johnson et al. 1993 (Clin.Biom.5:123128)
 Reply 2
To my opinion it is best to define all the landmarks that you can record
in a local coordinate system. In this way e.g. the GHrotation centre
can be approximated. In any case every body can compare his/her data
with the data presented. The AClandmark is absolutely a better landmark
in order to approximate the rotations in the actual ACjoint.
However from the point of accurate description of the motion of the
scapula, which was your major concern I would advice to use the
AAlandmark instead of the AClandmark. The position of the ACTSAI
triangle ('scapular plane') can always accurately be reconstructed.
The scapular ridge of major importance is the medial border, wich is
assumed to make contact to the thoracicgliding plane under normal
circumstances. This is defined by both ACTSAI and AATSAI triangles
(but is not congruent with either Ysaxes however).
Jurriaan de Groot (Ph.D) Tel : 31(0)152782156
Lab. of Measurement and Control Fax : 31(0)152784747
Fac. Mechanical Engineering Email : J.H.DeGroot@wbmt.tudelft.nl
Delft University of Technology 
 ____/(O
Mekelweg 2  :::::/
2628 CD Delft  :::/ DUTCH SHOULDER GROUP
The Netherlands  :/

http://wwwmr.wbmt.tudelft.nl/shoulder/dsg/tud/tud.html

9) Carolyn Anglin  Carolyn.Anglin@sulzer.ch
As you have described, the descriptions used for the long bones cannot
be easily adapted to the scapula. Van der Helm's group in the
Netherlands has done a lot of work and thinking on this topic. I would
therefore support using their method in order to standardize the
reporting of data, which greatly simplifies comparing studies.
The technique is described in:
Van der Helm FCT & Pronk GM (1995) Threedimensional recording
and description of motions of the shoulder mechanism. J. Biomechanical
Engineering 117:2740.
Another reference for your interest is:
Peterson B (1994) On a model of the upper extremity. Advances
in the Biomechanics of the Hand and Wrist. Schuind F [ed.]. Plenum
Press, New York.
Carolyn Anglin
Sulzer Orthopedics Ltd.
P.O. Box 65
CH 8404 Winterthur
Switzerland
Tel: +41 (52) 262 68 32
Fax: +41 (52) 262 01 87
Email: carolyn.anglin@sulzer.ch


To unsubscribe send UNSUBSCRIBE BIOMCHL to LISTSERV@nic.surfnet.nl
For information and archives: http://www.bme.ccf.org/isb/biomchl

for describing 3D scapular motion. I asked if there is any FUNDAMENTAL
motivation for the selection of a particular sequence that would make it
the "best" sequence and how does this relate to the description of
scapular rotations?
In this followup posting, I have included a summary of the suggestions
I received and the complete text of those responses. I appologize for
length of this posting, but it was necessary for completeness.
Thanks to all those who responded.
 Andy
__________________________________________________ ________
Andrew Karduna, Ph.D.
Assistant Professor, Department of Physical Therapy
Biomechanics Laboratory, 219 N Broad St
Allegheny University of the Health Sciences
Philadelphia, PA 19107
fax: (215) 7626076 phone: (215) 7625057
karduna@auhs.edu
__________________________________________________ _______
SUMMARY
There appears to be a consensus that there is no FUNDAMENTAL
or CORRECT order of rotations and that it is difficult to use
conventions from other bones because there is no "long axis"
of the scapula.
Here are some of the suggestions I have received:
 Select the sequence that most clearly demonstrates a consistent
difference between normal and a pathological movement.
 Use the relationship between Euler and projected angles to help.
 Instead of Euler Angles, use the attitude vector.
 Use the standard proposed by Frans van der Helm at
http://wwwmr.wbmt.tudelft.nl/schouder/dsg/standardization.html
 Use the to Angulus Acromialis (posteriorlateral ridge of acromion)
instead of the AC joint to avoid gimbal lock.
RESPONSES

1) Frances T. Sheehan  sheehan@me.udel.edu
 Reply 1
I have not worked on the shoulder joint at all, but have ran into
similar difficulties when trying to describe the 3D movement of
the knee. Basically, the orientation of 2 bodies is completely
described by the orientation matrix (3x3 quantity) ONCE a set of
reference frames have been fixed in both bodies. So, the first
question to ask is:
1) How are you defining your reference frames and are they
consistent from experiment to experiment? Without consistent reference
frames, you don't have a chance at comparing data.
Next, there are numerous methods for "simplifying" the
orientation matrix.
If you are planning on using 3 orientation angles, there are 24 different
geometric series you can use. Typically, the only constraint in choosing
a sequence is mathematical (i.e., avoiding gimbal lock, as you noted).
If you are trying to define a normal versus a pathological movement
pattern, I would choose the sequence that most clearly demonstrates a
consistent difference.
 Reply 2
It may sound post hoc to choose a sequence that best defines the
pathology, but depending upon your aims, I think it can be very useful.
First, the 3D orientation angles are not biological, they are a
mathematical simplification of a complex 3D event (as your different
results show). Thus, if you are trying to derive a test to define
healthy versus pathological, it makes sense to process all the sequences
and determine which one provides the largest statistical difference.
Clinically, this is the standard method for processing data. For example,
in investigating patellar tracking problems various 2D angles are typically
analyzed and the researchers try to define which single quantity provides
the clearest definition of the pathology.
Of course, if you are attempting to derive a cohesive description of
kinematics, regardless of the state of the joint, you are best of
choosing just one orientation angle sequence and sticking with it.
Frances T. Sheehan, Ph.D.
126 Spencer Hall (Office 312)
Mechanical Engineering Department
University of Delaware
Newark, Delaware 197163140
(302) 8311013 (phone)
(302) 8313619 (fax)

2) Ingram Murray  I.A.Murray@newcastle.ac.uk
I was quite amazed to see your posting on BiomechL as I was
about to post almost the same question myself. I am
looking at motion of the humerus in relation to the scapula and have
over the last couple of days trawled through the summary of the
arguments in the archives, which though very entertaining failed to
answer the question I had which was  why are some sequences better
than others ? (specifically related to the JCS of Grood and Suntay (1983))
I have recently carried out some work related to the movement at the
shoulder and found like you that there is quite a discrepancy in
results when using each of the six possible sequences. In my work
I found the sequence suggested by Cole et al (1993) to give
considerably better results than any of the others but have had
difficulty convincing myself why this is the case.
Although I'm afraid all this falls into the 'General Reply' category
and is not of specific help in your case, I would be very grateful if
you could forward me any relevant replies than give a reasonable
explanation of the different results obtained by applying different
sequences.
Ingram Murray
CREST
Room G32
Stephenson Building
University of Newcastle upon Tyne
Newcastle upon Tyne
NE1 7RU
UK

3) Neil Crawford  ncrawfo@mha.chw.edu
 Reply 1
Unlike other joints that have a clear plane of symmetry or a long axis,
it is not so clear which is the appropriate Euler/Cardan sequence for
the scapula. However, with your knowledge of scapular anatomy, you may
be able to decide which is the appropriate projection angle to use in
each plane, and then you can use the relationship between projection
angles and Euler angles to choose the appropriate Euler sequence.
In each plane, there are two possible projection angles. For example,
looking down the xaxis at the yz plane, it is clear that the
projection angle about the xaxis (Px) can be described either by the
projection of a vector j initially aligned with the yaxis (Pxj) or a
vector k initially aligned with the zaxis (Pxk). There is usually an
Euler/Cardan sequence that corresponds to the different projection
sets. The relationship between projection angle sets and Euler angle
sets is:
Projection Euler
Angle set Sequence
 
Pxj, Pyi, Pzi Rx>Ry>Rz
Pxj, Pyi, Pzj Ry>Rx>Rz
Pxj, Pyk, Pzi (none)
Pxj, Pyk, Pzj Ry>Rz>Rx
Pxk, Pyi, Pzi Rx>Rz>Ry
Pxk, Pyi, Pzj (none)
Pxk, Pyk, Pzi Rz>Rx>Ry
Pxk, Pyk, Pzj Rz>Ry>Rx
(no corresponding Euler sequence in the 2 cases where you use each axis
once in the projection angles)
You can choose the appropriate projection angles if you can
identify a plane of symmetry for scapular movement and determine that
motion about one of the three coordinate axes is different in nature
from the other two (for instance, at a motion segment in the spine or
at the wrist joint, there are two "bending" motions and one "twisting"
motion). If two of the motions are similar in nature (like the 2
bending motions), they should be described by the same vector projected
in different planes (e.g., xaxis rotation and yaxis rotation can both
be described by projecting the k vector, which was initially aligned with the
zaxis: Pxk and Pyk). Also, motion describing deviation from a plane of
symmetry should use a vector initially in that plane (e.g., if the yz
plane is a plane of symmetry, such as the midsagittal plane in the
spine, Pyk and Pzj are preferred over Pyi and Pzi since the former two
angles use vectors that were initially in the plane of symmetry while
the latter two do not).
I hope this explanation is not too convoluted. For a clearer
presentation, see Crawford et al., "Methods for determining spinal
flexion/extension, lateral bending, and axial rotation from marker
coordinate data: Analysis and refinement", Human Movement Science
15:5578, 1996.
If you cannot choose the appropriate projections using this
method, I would suggest using whatever has most commonly been reported
for scapular movement as long as the second Euler angle does not
approach 90 degrees.
 Reply 2
Regarding the correspondence between Euler angles and projection angles,
there is one Euler angle per sequence (the third rotation when rotations
are taken about global fixed coordinates) that is mathematically
identical to a certain projection angle. For the Euler sequence
Rx>Ry>Rz, the third angle Rz is mathematically identical to the
projection angle Pzi (the projection of the i vector on the plane
perpendicular to the zaxis). The equation for both Rz in this sequence
and Pzi is Rz=Pzi=atan2(iy,ix). (sorry, it's hard to write equations
without subscripts, etc. iy and ix are the y and x components of the i
vector, the unit vector that was initially aligned with the xaxis
before the rotation).
The other two Euler angles for a given sequence are not identical to any
particular projection angle, but for angles less than about 30 degrees
(which is most of the range of motion of many joints), they are much
closer to one of the two projections in a given plane than to the
other. Rx in the sequence Rx>Ry>Rz is more closely approximated by
Pxj than by Pxk. Ry in the sequence Rx>Ry>Rz is more closely
approximated by Pyi than by Pyk. The reason can be understood by
looking at the equations for the angles. Ry from Rx>Ry>Rz is
Ry=atan2(iz,ix cos Rz + iy sin Rz) while Pyi=atan2(iz,ix) and
Pyk=atan2(kx,kz). If Rz is small, then cos Rz approaches 1 and sin Rz
approaches 0. Then, the equation for Ry reduces to Ry~=atan2(iz,ix)
Ry>Rz
is Rx=atan2(kx sin Rz  ky cos Rz, jy cos Rz  jx sin Rz) while
Pxj=atan2(jz,jy) and Pxk=atan2(ky,kz). If Rz is small,
Rx~=atan2(ky,jy) From my limited experience experimenting with these rotation sequences,having the largest rotation as the last rotation is the most confusing from a
clinical perspective. I realize this "clinical perspective" isn't a
very strong rationale. I think much of the difficulty arises because of our
tendency (or at least mine) to want to interpret these rotations as the
"path" of motion rather than a position description that needs to
consider all of the rotations and the sequence used. As far as the potential
singularity or "gimbal lock" problem with upward rotation as the second
rotation, even using the AC joint in the axis definition, 90% of the
subjects I have tested have had values below 70 degrees during abduction
of the arm in the scapular plane. I do not test them at the extremes of
their range of motion, however.
 Reply 2
I haven't seen Jurriaan de Groot's thesis but the statement makes sense.
I would roughly estimate using the posterior acromion would decrease the
upward rotation numbers maybe ten degrees or so. I actually digitized
both the posterior lateral acromion and the AC joint in my latest study,
but have presently calculated the data only using the AC joint. I like
that point because I think the plane of the scapula is more correctly
defined but it does increase the upward rotation values from the
traditional clinical numbers. I collected both points to allow me to
potentially experiment with this a bit and compare to the published data
in both formats. I actually think these local coordinate system
definitions are more critical than the rotation sequences for
"standards" since it is more difficult to convert the data. Perhaps using
the y coordinate of the AC joint and z coordinate of the posterior acromion
would be ideal (assuming x lateral, y anterior, and z superior on the
right shoulder) but I realize that would be somewhat bizarre...
Paula Ludewig
The University of Iowa

7) Frans C.T. van der Helm  F.C.T.vanderHelm@wbmt.tudelft.nl
The subject of defining a standardized rotation sequence for rotations
of the shoulder bones had my interest for some time. On request of the
ISB, I wrote together with Jesus Dapena recommendations for a
standardization effort of the ISB. No definite decision has been taken
on that issue. Since then, we made a few adaptations, and I wrote a
paper on standardization for the First Conference of the International
Shoulder Group (Delft, The Netherlands, 1996):
Frans C.T. van der Helm (1996). A standardized protocol for motion
recordings of the shoulder. Proc. First Conf. of the International
Shoulder Group (Eds: HEJ Veeger, FCT van der Helm, PM Rozing), Delft,
The Netherlands, pp. 712.
Euler/Cardan angles have been chosen to describe motions. For the
scapula with respect to the thorax, the following choice has been made:
A local coordinate systems has been defined with respect to bony
landmarks as follows:
Xsaxis: Along the scapular spine, from Trigonum Spinae (TS)
to Angulus Acromialis (AA)
Zsaxis: Perpendicular to the scapular plane, defined by TS, AA
and Angulus Inferior (AI)
Ysaxis: Perpendicular to Xs and Zs, hence in the scapular plane.
Rotations are interpreted with respect to a starting position of the
scapula aligned with the Local coordinate system of the thorax:
Ytaxis: (IJ + C7)/2  (PX + T8)/2 (and normalized. )
(IJ: Incisura Jugularis; C7: proc. spinosus 7th Cervical Vertebra;
PX: Processus Xiphoideus; T8: proc. spinosus 8th Thoracic Vertebra)
Xtaxis: Yt x (C7  IJ) (vector product)
Ztaxis: Xt x Yt
Rotation order:
Pro/retraction about the Ysaxis, defines the angle of the scapular
spine w.r.t. the frontal plane.
Lateral/medial rotation about the Zs'axis (moved by the previous
rotation), i.e. rotation in the scapular plane
Tipping forward/backward about the Xs"axis (scapular spine, moved by
the previous rotations).
Rationale:
The first two rotations define the orientation of the scapular spine in
space, the last rotation is a rotation about the scapular spine. It is
preferred to have the last rotation about a longitudinal axis of the
bone, however for the scapula there is no unique longitudinal axis. The
second rotation can result in gimbal lock problems (if the rotation
angle approaches 90 degrees), therefore AA has been chosen instead of
the acromioclavicular joint (AC), as in previous recommendations of our
group. The order of rotations is close to interpretation of medical
terminology. Note that the zerozerozero orientation (starting
position) is not a feasible orientation of the scapula, due to the
motion constraints of clavicle and thorax!
In my opinion, there is no FUNDAMENTAL argument to choose for the one or
other rotation order. Interpretation of rotation in combination with
avoidance of gimbal lock should be the first rationale, and
interpretation is certainly subjective. It is important to define local
coordinate systems with respect to bony landmarks. If one uses the same
bony landmarks, every definition can be reconstructed. However, it is
preferred to use a standardized definition in order to improve the
communication between researchers and clinicians.
Frans C.T. van der Helm, PhD
ManMachine Systems & Control group
Dept. of Mechanical Engineering
Delft University of Technology
Mekelweg 2
2628 CD Delft
The Netherlands
tel. (+31)152785616
fax. (+31)152784717
email: F.C.T.vanderHelm@wbmt.tudelft.nl

8) Jurriaan de Groot  J.H.degroot@wbmt.tudelft.nl
 Reply 1
I agree with you that there should be an agreement on the definition of
the rotation axes, rotation order and defined initial position for the
description of motions of the shoulder bones.
As a part of my Ph.D. thesis I looked at the accuracy of the Cardan
parameters by which the scapular Cardan angles can be expressed. I must
confess that the choice of rotation axes and rotation order where
initially based on the traditions within our group. The arguments for
these definitions however were rather convincing, based on the fact that
the rotations should be interpretable and accurate.
Your questions were:
1) Is there any FUNDAMENTAL (mechanical, clinical or mathematical)
motivation for the selection of a particular sequence that would make
it the "best" sequence? and
2) How does this relate to the description scapular rotations?
I think that the 'best sequence' is not unique. A mathematical best sequence
will e.g. be based on the most accurate description, the
clinical best will be based in the interpretation of the angles.
To my opinion the best sequence for the scapula will be one that is well
interpretable (e.g. in the clinic) and in which the variability introduced
by the definition is negligibly small with respect to the variability of
intra and interindividual shoulder motions.
The best sequence depends on:
1  the axis definition with respect to the recordable landmarks.
2  the definition of the initial reference position.
3  the need of interpretation of the rotations.
4  the wish to describe bony motions or joint motions
Van der Helm and Pronk 1995 (J.Biom.Eng 117: 2740) define the
orientation of the scapula with respect to a 'vertical' thorax. The
rotation axes are based on palpable bony landmarks: the
acromioclavicular joint [AC], the angulus acromialis [AA], the trigonum
spinae [TS] and the angulus inferior [AI].
Three perpendicular axes were defined:
 A mediallateral axis defined by the landmarks TS and AC (Sxaxis).
 An anteriorposterior axis, perpendicular to the 'scapular plane'
defined by AC,TS and AI (Sz axis).
 A caudalcranial Syaxis perpendicular to the Sz and Sx axis.
The missing longitudinal axis of the scapula could be referred to as the
axis between the ACjoint and the GHjoint, but the rotations would not
be very interpretable.
In the initial 'reference' position all axes of the scapula were
aligned with the axes of the thorax. Otherwise an predefined
thoraxarm posture should be agreed in order to be able to compare
recorded data.
The chosen rotation order was SySzSx, which agrees to the definition
mentioned in the original posting: protractionelevationtilt.
The order is motivated by the fact that the second rotation should be
the largest rotation of a clear structure (the scapular spine),
preceeded by a rotation that defines the plane of the second rotation.
In case of the scapula, the second rotation is the elevation of the
scapular spine, preceeded by the initial rotation to align the scapula
to the 'tangential plane' of the curved thorax. As such the scapular
elevation coincides best with the elevation in the scapular plane
The choice of rotation order is not based on mechanical or mathematical
motivation but purely on interpretation of the resulting angles
(clinical).
However, if the second rotation is in the order of 90 degrees one must
be aware of the problems of the indetermined gimballock position. In a
study in which the total variation the recorded motions was
identified, it was shown that the scapula position based on the AC, TS
and AI landmarks, was liable to this gimballock inaccuracy (Groot 1998,
Clin. Biomech. in press]. Using the AAlandmark instead of the AClandmark
hardly changes the interpretation of the recorded angles, and reduces the
gimballock to a negligible influence.
Concluding: the chosen rotation order of Van der Helm and Pronk (1995)
combined with the coordinate system based on AA, TS and AI (Groot 1998)
and referred to an initial scapular reference position which is aligned
with the thorax coordinate system, results in an accurate and
interpretable description of the scapular motions.
An advantage of this description is, that the global orientation of the
scapula can be recorded directly by means of a scapula locator, used by
Johnson et al. 1993 (Clin.Biom.5:123128)
 Reply 2
To my opinion it is best to define all the landmarks that you can record
in a local coordinate system. In this way e.g. the GHrotation centre
can be approximated. In any case every body can compare his/her data
with the data presented. The AClandmark is absolutely a better landmark
in order to approximate the rotations in the actual ACjoint.
However from the point of accurate description of the motion of the
scapula, which was your major concern I would advice to use the
AAlandmark instead of the AClandmark. The position of the ACTSAI
triangle ('scapular plane') can always accurately be reconstructed.
The scapular ridge of major importance is the medial border, wich is
assumed to make contact to the thoracicgliding plane under normal
circumstances. This is defined by both ACTSAI and AATSAI triangles
(but is not congruent with either Ysaxes however).
Jurriaan de Groot (Ph.D) Tel : 31(0)152782156
Lab. of Measurement and Control Fax : 31(0)152784747
Fac. Mechanical Engineering Email : J.H.DeGroot@wbmt.tudelft.nl
Delft University of Technology 
 ____/(O
Mekelweg 2  :::::/
2628 CD Delft  :::/ DUTCH SHOULDER GROUP
The Netherlands  :/

http://wwwmr.wbmt.tudelft.nl/shoulder/dsg/tud/tud.html

9) Carolyn Anglin  Carolyn.Anglin@sulzer.ch
As you have described, the descriptions used for the long bones cannot
be easily adapted to the scapula. Van der Helm's group in the
Netherlands has done a lot of work and thinking on this topic. I would
therefore support using their method in order to standardize the
reporting of data, which greatly simplifies comparing studies.
The technique is described in:
Van der Helm FCT & Pronk GM (1995) Threedimensional recording
and description of motions of the shoulder mechanism. J. Biomechanical
Engineering 117:2740.
Another reference for your interest is:
Peterson B (1994) On a model of the upper extremity. Advances
in the Biomechanics of the Hand and Wrist. Schuind F [ed.]. Plenum
Press, New York.
Carolyn Anglin
Sulzer Orthopedics Ltd.
P.O. Box 65
CH 8404 Winterthur
Switzerland
Tel: +41 (52) 262 68 32
Fax: +41 (52) 262 01 87
Email: carolyn.anglin@sulzer.ch


To unsubscribe send UNSUBSCRIBE BIOMCHL to LISTSERV@nic.surfnet.nl
For information and archives: http://www.bme.ccf.org/isb/biomchl
