Announcement

Collapse
No announcement yet.

RESPONDS TO: emg & muscle: force-length,force-velocity relationship

Collapse
This topic is closed.
X
X
 
  • Filter
  • Time
  • Show
Clear All
new posts

  • RESPONDS TO: emg & muscle: force-length,force-velocity relationship

    Hello!

    I've received many answers to my question and I think it is a good thing to
    collect the answers an repost them for everyone to read, so here it comes.

    First of all, the question, followed by another explanation that came to my
    mind a few days ago:

    === THE QUESTION ================================================== =======

    've made an observation while recording emg values that I cannot match with
    information I gathered from publications:
    While the subject is standing he's lifting and lowering his thigh (shank is
    pointing down) quite slowly (roughly 2 sec per direction) and the signal is
    recorded from the m. iliopsoas.
    When I compare the rms (or low-pass filtered) values at the same angle
    (between trunk and thigh) from
    a) the upward movement and
    b) from the downward movement

    the values from b) are always larger then the values from a) (factor 1.1 to
    1.5 roughly).
    Also when I add a case
    c) upward movement again (right after b), no recovering for the muscle)
    the values from b) are still larger than those recorded during b).

    Why is this the case?

    After reading some publications I came to the following conclusions:
    - muscle fatigue cannot be the reason, since I can repeat a) and b) right
    after one another again and again and get the same results: values from b)
    are larger than those recorded during a)/c)
    - force-length relationship cannot be important here, since the length of the
    muscle is the same for the same angle no matter if the thigh is lifted or put
    down (or is it not?? any effects I didn't consider?)
    - force-time relationship: the movement is so slow that it can be neglected
    also (the elastic element will be stretched in almost the same manner whether
    the movement is a) or b))

    - force-velocity relationship: first I thought that this might explain it, but
    if I make no mistake in my reasoning, my observations show it just the other
    way round:
    The muscle is shortening during a), so the normalized velocity of the muscle
    is v < 0.
    Hill,Zajac,Hatze,Happee and Delp all propose functions for the
    force-velocity-factor that give results < 1.0 for v < 0 and results >= 1.0
    for v >= 0.

    Wouldn't this mean, that the muscle needs to be stimulated more during a) (v <
    0) to produce the same force as during b) (because the force-velocity-factor
    is smaller for v < 0)?
    But if it needed to be stimulated more, then I would record higher rms
    values...

    Either I've made a mistake in my reasonings or there's another effect I didn't
    consider.
    Can anyone shed some light on this matter? :-)

    === ANOTHER THOUGHT OF MINE ============================================

    The low-pass filter I used to smoothen the rectified
    EMG-values had too a small low-cut frequency ( read more about this?
    Search for references to Stegeman and Blok, and Stegeman and
    Roeleveld
    Good luck again,
    At
    -------------------------------------------------------------------------------------

    Do you also have EMG recordings of the opposing muscles?
    Subjects might be co-activating the muscles to control the downward
    movement. In the upward movement gravity is stabilizing the movement while
    in the downward movement it destabilizes the movement. In order to make the
    system controllable it might be favourable to co-activate more. I agree with
    you idea that force-length and force-velocity charateristics are probably
    not the cause of your findings.

    If you do have emg recordings, please let me know if I'm right!

    Greeting Luc

    -------------------------------------------------------------------------------------



    Both iiacus and psoas are rather deep muscles. I don't know much about EMG
    application, but I suppose that in order to measure their activity
    separately from other hip muscles one would need to use a fine wire
    electrode inserted into the muscle.

    If you were using surface electrodes then I might suggest that the
    contraction of different muscles during the raising and lowering movements
    would alter the distance between the muscle producing the signal and the
    measuring electrode.

    Probably this is not of much help. However, I would be interested to find
    out what other EMG experiments you are carrying out here in Berlin. Maybe we
    might have some common interests.

    best wishes

    Mark Thompson

    -------------------------------------------------------------------------------------
    Could other hip flexors (e.g., rectus femoris, sartorius, tensor fascia
    latae) be contributing force to the upward movement, but not the
    downward movement?

    Susan Larson

    -------------------------------------------------------------------------------------

    Looking at the left hand side of the force-velocity curve (eccentric portion)
    you will see the muscle force continues to increase past the isometric
    (zero-velocity) muscle force, and the eccentric muscle force increases to a
    plateau that is somewhat higher than that of the isometric muscle force. EMG
    signals have also been reported to be larger during eccentric muscle action
    than compared to concentric. I cant recall the exact Herzog reference, but
    Dr. Walter Herzog has written papers on this. From what I can gather from the
    description of your movement, the (b) portion of the movement is when the
    iliopsoas is eccentrically activated, lowering the thigh against gravity.
    Therefore, the increased EMG may be explained through the eccentric muscle
    action.

    Regards,

    Kathleen Costa, ABD
    -------------------------------------------------------------------------------------

    I enjoyed your posting. Nice to see someone express their logic flow so
    concisely.

    Regarding the Force-Velocity relationship. I think perhaps you need to
    reconsider the sign of contraction velocity. A concentric (shortening)
    contraction should be a positive velocity, and negative for the eccentric
    (lengthening) contraction.
    In addition to Hill et al's work, you might be interested in the following
    classic article:
    Bigland, B. and Lippold, O.C.J. The relation between force, velocity
    and integrated electrical activity in human muscles. Journal of
    Physiology (London), 1954, 123: 214-224.

    Take care,
    Mike

    -------------------------------------------------------------------------------------

    After I replied to your first posting, I quickly reviewed Bigland and
    Lippold's paper, and there may be something there that could cause some
    distress on your part. They show that I-EMG values for the same absolute
    velocity were less in the eccentric condition, than in the concentric. I
    believe this is one of the more interesting aspects of muscle activation ...
    that Eccentric force production can be higher, while requiring less neural
    activation. You will find in your review of the literature that the
    musculotendinous system can produce passive tension when stretched. Pretty
    interesting function.

    Have a great weekend.

    Mike

    -------------------------------------------------------------------------------------

    This may be naïve, but couldn't the difference be attributable to the fact
    that the person is performing an eccentric contraction (higher values) during
    thigh lowering and a concentric contraction (lower values) during thigh
    raising. I believe that some have stated that more fast-twitch/high tension
    fibers are recruited during eccentric contractions and, thus, greater EMG
    values. Perhaps I'm misunderstanding your data?

    Kimberly B. Harbst, P.T., Ph.D.

    -------------------------------------------------------------------------------------

    See the work of Peter Huijing such as:1-3

    1. Huijing, P.: Muscular force transmission: a unified, dual or
    multiple system? A review and some explorative experimental results.
    Arch Physiol Biochem, 107(4): 292-311, 1999.
    2. Huijing, P. A., and Baan, G. C.: Extramuscular myofascial force
    transmission within the rat anterior tibial compartment: proximo-distal
    differences in muscle force. Acta Physiol Scand, 173(3): 297-311, 2001.
    3. Huijing, P. A., and Baan, G. C.: Myofascial force transmission
    causes interaction between adjacent muscles and connective tissue:
    effects of blunt dissection and compartmental fasciotomy on length force
    characteristics of rat extensor digitorum longus muscle. Arch Physiol
    Biochem, 109(2): 97-109, 2001.


    Muscles are interconnected and do not work independently. Also: EMGs
    show only active contraction and do not indicate muscle tone. The muscle
    may be isotonic and exert considerable force with no EMG indication of
    any activity.

    Stephen M. Levin

    -------------------------------------------------------------------------------------
    Could it be because lowering the thigh is a lengthening (eccentric)
    contraction?


    raju
    -------------------------------------------------------------------------------------

    The interconnectedness of muscles is covered in the articles by
    Huijing. You might want to get a hold of Hubb Maas' PhD thesis in book
    form, /Myofascial Force Transmission/, that puts it all together.
    Contact him through his email: hmass@fbw.vu.nl .

    Muscle is never flaccid; there is always a certain amount of tension or
    'muscle tone' in the system. This tension varies with posture, activity,
    excitement and other factors. For instance, the muscle tone is higher
    when standing then lying down but, once standing, the EMG s are the
    same. The acumulated isotonic tension may be considerable, but you
    would never know it from looking at the EMGs. Check the O2 consumption
    and you would see a difference. EMGs only show increasing tension. When
    a muscle is isotonic, EMGs are flat even though there is tension of the
    muscle. A flat EMG does not mean there is no tension, just that there is
    no increasing tension. That tension, (muscle tone), can do 'work', for
    instance, it keeps you standing. Think of the spokes of a bicycle wheel.
    Once you set the tension, the tension remains constant no matter what
    the load on the bicycle. I have never seen this discussed in the
    literature, but the facts are indisputable.

    P.S. Your English is a lot better than my German!

    Best regards,

    Steve

    -------------------------------------------------------------------------------------
    >
    > I've made an observation while recording emg values that I cannot
    > match with information I gathered from publications: While the subject
    > is standing he's lifting and lowering his thigh (shank is pointing
    > down) quite slowly (roughly 2 sec per direction) and the signal is
    > recorded from the m. iliopsoas.
    How do you do this? It is commonly assumed that it is not
    possible to record surface EMG from psoas. You need some 20
    cm (!) long needles to perform this.

    When I compare the rms (or low-pass
    > filtered) values at the same angle (between trunk and thigh) from a)
    > the upward movement and b) from the downward movement
    >
    > the values from b) are always larger then the values from a) (factor
    > 1.1 to 1.5 roughly). Also when I add a case c) upward movement again
    > (right after b), no recovering for the muscle) the values from b) are
    > still larger than those recorded during b).
    >
    > Why is this the case?
    >
    > After reading some publications I came to the following conclusions: -
    > muscle fatigue cannot be the reason, since I can repeat a) and b)
    > right after one another again and again and get the same results:
    > values from b) are larger than those recorded during a)/c) -
    > force-length relationship cannot be important here, since the length
    > of the muscle is the same for the same angle no matter if the thigh is
    > lifted or put down (or is it not?? any effects I didn't consider?) -
    > force-time relationship: the movement is so slow that it can be
    > neglected also (the elastic element will be stretched in almost the
    > same manner whether the movement is a) or b))
    >
    > - force-velocity relationship: first I thought that this might explain
    > it, but if I make no mistake in my reasoning, my observations show it
    > just the other way round: The muscle is shortening during a), so the
    > normalized velocity of the muscle is v < 0. Hill,Zajac,Hatze,Happee
    > and Delp all propose functions for the force-velocity-factor that give
    > results < 1.0 for v < 0 and results >= 1.0 for v >= 0.
    >
    > Wouldn't this mean, that the muscle needs to be stimulated more during
    > a) (v < 0) to produce the same force as during b) (because the
    > force-velocity-factor is smaller for v < 0)? But if it needed to be
    > stimulated more, then I would record higher rms values...
    >

    Yes this is entirely correct. Usually you see it this way. I can see
    two confounders.
    1) You may have recorded from the wrong muscle. Maybe rectus
    femoris? This is a hip flexor, but also a knee extensor, so when the
    knee is free hanging it should give no signal. But this is
    theoretically, it may well be different. Sartorius is also possible.
    2) Sometimes you see high rhythmic (8-10 Hz) bursts in eccentric
    contractions, resulting in 'incorrect' high rms values.
    > Either I've made a mistake in my reasonings or there's another effect
    > I didn't consider. Can anyone shed some light on this matter? :-)
    >

    -------------------------------------------------------------------------------------

    Thanks again!
    Christian

    -
    Dipl.-Ing. Christian Fleischer
    Technical University of Berlin
    Computer Engineering and Microelectronics
    Sekr. EN 10 - Einsteinufer 17 - 10587 Berlin - Germany
    Fon:+49 (0)30 314-73114 - mailto:fleischer@cs.tu-berlin.de
    Fax:+49 (0)30 314-21116

    -----------------------------------------------------------------
    To unsubscribe send SIGNOFF BIOMCH-L to LISTSERV@nic.surfnet.nl
    For information and archives: http://isb.ri.ccf.org/biomch-l
    Please consider posting your message to the Biomch-L Web-based
    Discussion Forum: http://movement-analysis.com/biomch_l
    -----------------------------------------------------------------
Working...
X