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  • Length-Tension Relations for Myocardial Mechanics

    Hello everyone,

    I have some questions of a rather basic nature to submit to the Biomch-L
    Newsgroup. I
    require a manageable muscle model for educational purposes. My first
    search through
    your archives did not reveal similar discussions on my topic. Further
    searches were
    stymied due to a misconfiguration on the server. The rest of this e-mail
    simply contains
    the textual content of the site below, which also displays the relevant
    figures.

    [Myocardial Mechanics
    {http://www.geocities.com/CapeCanaveral/Hangar/3357/}]

    I would like to present a tangible conceptual model of the heart as a
    hollow muscular
    organ to my medical students. My aim is to elucidate the basis of the
    cardiac
    equilibrium curves and work diagram (Figure 1) from first principles by
    drawing from
    Length-Tension relation experiments on skeletal muscle.

    Figure 1.

    Myocardial preparations, with an almost parallel arrangement of their
    muscle fibers,
    can be subjected to classical analytic procedures, and model designs
    originally
    developed for skeletal muscle can be used. My three references on the
    topic[1] [2] [3]
    support a not-so-robust spring model of muscle tissue depicted in Fig.
    2.

    Figure 2.

    In [1], the cardiac passive tension curve shown in Fig. 3 is attributed
    to parallel and
    series elastic elements (P.E. and S.E. respectively) under the form of
    sarcolemmal
    sheaths, filament components like titin and nebulin, and connective and
    tendinous tissue
    fibers. It is also claimed that the contractile element (C.E.) is
    considered freely
    extensible at rest. Thus no tension across the resting C.E. exits.
    Cardiac contraction
    during systole is an all-or-none phenomenon implying that there is no
    partial tonus
    activity persisting during diastole.

    Figure 3.

    There are various points that are, as yet, unclear to me:

    1) If C.E.s are freely extensible at rest, then S.E.s cannot contribute
    to the passive
    tension curve. Wouldn’t this lead to a contradiction of the first
    statement in the
    paragraph above? If this were so, what would be the shape of the
    Length-Tension curve
    for S.E.s in isolation? Are the approximate values of the elasticity
    modulus of P.E.s and
    S.E.s available?

    2) [1] [2] and [3] provide no explanation for the isotonic maxima curve
    in Fig.3. Why
    should a pre-loaded contraction starting at point A (Fig.3) grind to a
    halt at point B?
    What keeps it from shortening to reach a steady state equilibrium of
    forces at C?
    Suppose that a pre-loaded contraction starts at D. Wouldn’t the
    isometric contraction of
    the C.E. be able to ‘relieve’ the P.E.s of some of their tension thus
    enabling them to
    shorten? Wouldn't this improve actin-myosin overlap and eventually
    bring D into the
    active increment envelope, leading to F?

    3) How was data obtained for isometric contractions starting from a
    length shorter than
    the resting one. Was the muscle under study already in a state of
    pre-contraction?

    Thank you for your time.


    Bibliography

    [1] Comprehensive Human Physiology, R. Greger U. Windhorst, Springer
    [2] Human Physiology, R. Schmidt G. Thews, 2nd ed., Springer-Verlag
    [3] Textbook of Medical Physiology, A. Guyton, 9th ed., Saunders


    Dr Bernard Debono MD
    Department of Physiology and Biochemistry
    Biomedical Sciences Building
    University of Malta
    Msida
    Malta
    Tel: +(356) 3290-2286
    Fax: +(356) 310577
    E-mail: bmds@biomed.um.edu.mt


    Hello everyone,

    I have some questions of a rather basic nature to submit to the Biomch-L
    Newsgroup. I
    require a manageable muscle model for educational purposes. My first
    search through
    your archives did not reveal similar discussions on my topic. Further
    searches were
    stymied due to a misconfiguration on the server. The rest of this e-mail
    simply contains
    the textual content of the site below, which also displays the relevant
    figures.

    [Myocardial
    Mechanics {http://www.geocities.com/CapeCanaveral/Hangar/3357/}]
     
    I would like to present a tangible conceptual model of the heart as
    a hollow muscular
    organ to my medical students. My aim is to elucidate the basis of the
    cardiac
    equilibrium curves and work diagram (Figure 1) from first principles
    by drawing from
    Length-Tension relation experiments on skeletal muscle.
     
    Figure 1.

    Myocardial preparations, with an almost parallel arrangement of their
    muscle fibers,
    can be subjected to classical analytic procedures, and model designs
    originally
    developed for skeletal muscle can be used. My three references on the
    topic[1] [2] [3]
    support a not-so-robust spring model of muscle tissue depicted in Fig.
    2.

    Figure 2.

    In [1], the cardiac passive tension curve shown in Fig. 3 is attributed
    to parallel and
    series elastic elements (P.E. and S.E. respectively) under the form
    of sarcolemmal
    sheaths, filament components like titin and nebulin, and connective
    and tendinous tissue
    fibers. It is also claimed that the contractile element (C.E.) is considered
    freely
    extensible at rest. Thus no tension across the resting C.E. exits.
    Cardiac contraction
    during systole is an all-or-none phenomenon implying that there is
    no partial tonus
    activity persisting during diastole.
     
    Figure 3.

    There are various points that are, as yet, unclear to me:

    1)  If C.E.s are freely extensible at rest, then S.E.s cannot contribute
    to the passive
    tension curve. Wouldn’t this lead to a contradiction of the first statement
    in the
    paragraph above? If this were so, what would be the shape of the Length-Tension
    curve
    for S.E.s in isolation? Are the approximate values of the elasticity
    modulus of P.E.s and
    S.E.s available?
     
    2)  [1] [2] and [3] provide no explanation for the isotonic maxima
    curve in Fig.3. Why
    should a pre-loaded contraction starting at point A (Fig.3) grind to
    a halt at point B?
    What keeps it from shortening to reach a steady state equilibrium of
    forces at C?
    Suppose that a pre-loaded contraction starts at D. Wouldn’t the isometric
    contraction of
    the C.E. be able to ‘relieve’ the P.E.s of some of their tension thus
    enabling them to
    shorten? Wouldn't this  improve actin-myosin overlap and eventually
    bring D into the
    active increment envelope, leading to F?
     
    3)  How was data obtained for isometric contractions starting
    from a length shorter than
    the resting one. Was the muscle under study already in a state of pre-contraction?

    Thank you for your time.
     

    Bibliography
     
    [1] Comprehensive Human Physiology, R. Greger U. Windhorst, Springer
    [2] Human Physiology, R. Schmidt G. Thews, 2nd ed., Springer-Verlag
    [3] Textbook of Medical Physiology, A. Guyton, 9th ed., Saunders
     
     
    Dr Bernard Debono MD
    Department of Physiology and Biochemistry
    Biomedical Sciences Building
    University of Malta
    Msida
    Malta
    Tel:  +(356) 3290-2286
    Fax: +(356) 310577
    E-mail: bmds@biomed.um.edu.mt

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