Extramuscular myofascial force transmission for in situ rat medial gastrocnemius and plantaris muscles in progressive stages of dissection
1 Institute for Fundamental and Clinical Human Movement Sciences, Vrije
Universiteit, Van der Boechorststraat 9, 1081 BT Amsterdam, The
Netherlands
2 Institute for Biophysical and Clinical Research into Human Movement,
Manchester Metropolitan University, Crewe and Alsager Faculty, Cheshire ST7
2HL, UK
3 Integrated Biomedical Engineering for Restoration of Human Function,
Instituut voor Biomedische Technologie, Faculteit Construerende Wetenschappen,
Universiteit Twente, Postbus 217, 7500 AE Enschede, The Netherlands
* Author for correspondence (e-mail: j.rijkelijkhuizen{at}vumc.nl)
Accepted 27 October 2004
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Summary |
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Key words: dissection, epitendinous tissues, extramuscular myofascial force transmission, in situ muscle, neuro-vascular tract, tenotomy.
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Introduction |
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In addition to myotendinous force transmission (i.e. force is transmitted
via the myotendinous junctions to the tendon (e.g.
Tidball, 1984;
Tidball, 1991
), there are
other paths by which force can be transmitted from a muscle. Force can be
transmitted from muscle fibres onto the continuous endomysial fascia of the
muscle (Street and Ramsey,
1965
; Street,
1983
). This type of force transmission is called myofascial force
transmission. Myofascial force transmission can occur via several
pathways. (1) If force is transmitted within a muscle, from the
endomysial-perimysial network onto adjacent fibres (e.g.
Purslow and Trotter, 1994
) or
onto the aponeurosis (Huijing et al.,
1998
; Huijing,
1999a
), it is referred to as intramuscular force transmission. (2)
If force is transmitted via the connective tissue at the interface
between the muscle bellies of adjacent muscles
(Maas et al., 2001
), it is
called intermuscular force transmission. (3) If force is transmitted
via other, extramuscular, connective tissues
(Huijing, 1999b
) (e.g.
compartmental fascia, general fascia or connective tissue reinforcing nerves
and blood vessels), we refer to it as extramuscular force transmission.
Differences between proximally and distally measured forces have been observed
in rat extensor digitorum longus (EDL) muscle when measured within an intact
connective tissue environment (Huijing and
Baan, 2001
), indicating that force is transmitted not only
via the myotendinous junction, but also via myofascial
pathways.
In vivo, skeletal muscles are surrounded by neighbouring muscles and connective tissue. In situ experiments are usually performed on dissected muscles freed from their surrounding tissues with the exception of the neuro-vascular tract (i.e. the nerves, bloodvessels and the surrounding connective tissue). If force is measured at only one tendon of the muscle, usually the distal one, the assumption is made implicitly that extramuscular myofascial force transmission does not occur. However, the intact neuro-vascular tract is at least a potential path for transmission of passive or active force from the muscle (Yucesoy et al., 2003).
The aim of the present study was to test the hypothesis that extramuscular myofascial force transmission occurs for rat medial gastrocnemius (GM) muscle and its neighbouring plantaris (PL) muscle, and that such transmission will decrease in progressive stages of dissection of the GM muscle-tendon complex. In addition, the hypothesis will be tested that force of PL may be exerted on the calcaneal bone via extramuscular connective tissues around GM and PL tendons (epitendinous tissues) and muscle bellies. Active and passive force exerted by GM will be measured not only at its distal tendon, but also simultaneously at its proximal tendon. Any difference between proximally and distally measured forces constitutes evidence for extramuscular myofascial force transmission. To test if the extent of myofascial force transmission via the neuro-vascular tract varied with the position of the muscle belly relative to this tract, effects of moving the GM origin were studied as well.
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Materials and methods |
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Muscle dissection and experimental set-up
Male Wistar rats, Rattus norvegicus albinus Berkenhaut 1769
(N=7; body mass 250-289 g), were anaesthetised with 1.5 g
kg-1 body mass urethane (administered intraperitoneally).
Supplemental injections of 0.63 g kg-1 body mass were given if
necessary. During surgery as well as during the experiment, the animal was
placed prone on a heated pad of 32°C to prevent hypothermia.
The lateral (GL) and medial (GM) parts of the gastrocnemius muscle were exposed by removing the skin and most of the biceps femoris muscle from the limb. Semitendinosus and gracilis posticus muscles were removed as well. The soleus, deep flexors, peroneal muscles and muscles in the anterior crural compartment were left intact, but were denervated. Only extramuscular connections of GM were left intact. GM and GL of the rat are parts of one muscle. GL and GM were separated carefully without separating them from any other surrounding tissues. This was done by cutting the GL loose from the GM in such a way that GM was not damaged. Thus, the intermuscular connection between the GM and GL was severed. The reason that only the GM was studied was to be able to investigate the extent of extramuscular force transmission for in situ rat GM muscle in various stages of dissection. This is of interest because the fully dissected rat GM in situ muscle model is a widely used model. The plantaris (PL) muscle is facing the aponeurosis of GM muscle, which prevents intermuscular connections (i.e. direct connections between two intramuscular connective tissue stromata). Therefore, the connection between GM and PL is extramuscular and was left intact. The rat PL muscle is a muscle of a shape similar to the rat GM muscle, but of smaller size. Around the GM and PL muscle bellies, extramuscular connective tissue (i.e. remnants of the general fascia and epimysium) was left intact.
The tendons of the GL muscle and the soleus muscle were cut from the calcaneal bone without damaging extramuscular tissues around the tendons. This intervention was performed from a proximal direction through the space between the separated GM and GL muscles. These extramuscular tissues around the tendons involve remnants of general fascia, epimysium, neuro-vascular tract and compartmental fascia; these tissues will be further referred to as epitendinous tissues. In contrast to the proximal tendons, the distal tendons of GM and GL are not completely separate. Therefore, the tendon of GL was cut from the tendon of GM. After this intervention, GL and soleus muscles were not connected to the calcaneal bone in any way. The calcaneal bone, with the neighbouring tendons of GM and PL muscles still attached, was cut without removing any of the epitendinous tissues. The calcaneal bone was connected to a force transducer with a small metal rod. A representation of the experimental set-up is shown in Fig. 1.
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To be able to measure force exerted by the GM muscle at its proximal tendon, a piece of the femur with the origin of the muscle attached was cut. This piece of bone was connected to a second force transducer using a small metal rod. The femur was clamped in such a way that the knee could be fixed at an angle of approximately 120°, with the lower leg horizontally. Muscle temperature was controlled by a water-saturated airflow of approximately 33°C around the hind limb. The blood supply remained intact. Within the upper leg, the sciatic nerve was cut as proximally as possible, placed on a bipolar stimulating electrode and used for stimulation. All distal branches of this nerve were cut except for the branches to GM and PL, which were clearly distinguishable from the other branches. By cutting these other distal nerve branches carefully through the space between the separated GM and GL, without pulling on tissues that enclose the GM and PL nerve branches, damaging these nerve branches was prevented. The supramaximal stimulation current was 1 mA with a pulse width of 0.05 ms for maximal stimulation of all fibres of GM and PL. The stimulation frequency used was 200 Hz, which was sufficient to obtain maximal isometric force at the experimental temperature. After the experiments, the rats were killed by cervical dislocation.
The distal force transducer (custom made, compliance 8 µm
N-1) used was part of an isovelocity measuring system (for more
details about this system see (De Haan et
al., 1989). The transducer was mounted on a servomotor. Motor
movements and stimulation were computer controlled. The proximal force
transducer (serial number 17053, compliance 16.2 µm N-1; BLH
Electronics Inc., Canton MA, USA) remained in a constant position. The
proximal and the distal force transducer were positioned in the line of pull
of the GM muscle. Force and length data were digitised (1000 Hz) and stored on
disk for later analysis.
Prior to each experiment, the two force transducers were calibrated to make sure that there were no differences in forces measured. The two force transducers were connected to each other using a metal spring. The output was recorded with the identical measurements system as used in the animal experiment. The slope of the regression line (r2=0.999) of the simultaneously measured forces deviated 0.41% from the expected 45°. Therefore, any differences between proximally and distally measured forces exceeding 0.41% cannot be ascribed to the measurement system used.
Determining force-length characteristics
Force-length characteristics were determined at various muscle-tendon
complex lengths with tetani of 200 ms with a stimulation frequency of 200 Hz.
Optimum length (L0) of the GM was defined as the muscle
length at which proximally measured active force was maximal. Measurements
started from 13 mm below L0 (i.e. near active slack
length). Passive force at this length and position, if any, was indicated as
zero by the measurement system. The actual passive force at the proximal force
transducer was zero at this length and position, but the actual passive force
at the distal force transducer may have been slightly higher because of the
epitendinous tissues left intact around the distal tendon, exerting a passive
force. All forces are expressed relative to this zero value. Before each
contraction, GM was brought to the desired length passively by distal
lengthening using the (computer controlled) distal measurement system. The
proximal force transducer remained at a fixed position. Contractions were
performed for a range from 13 mm below to 3 mm over L0
with 1.0 mm increments). The passive force measured after the contraction was
subtracted from measured total force to obtain active force. After each
contraction, the muscles were allowed to recover at L0-13
mm for 2 min.
Experimental conditions
1. Initial condition
Proximal (GM) and distal (GM+PL) forces were measured after performing the
dissection as described above. Thus, the GM and GL were separated after
removing the biceps femoris muscle. The soleus, deep flexors, peroneal muscles
and muscles in the anterior crural compartment were left intact but were
denervated. The distal tendons of the GM and PL muscles and the epitendinous
tissues were still attached via the calcaneal bone to the distal
force transducer. Only the proximal GM tendon was connected to the proximal
force transducer. An overview of this stage of dissection is presented in
Fig. 2A.
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2. Post PL-tenotomy
After determining the forces of the proximal GM and the distal
GM+PL-complex at different muscle-tendon complex lengths, a distal tenotomy of
PL muscle was performed. The distal tendon was cut from the calcaneal bone
without removing the animal or moving the hind limb within the experimental
set-up. A very small area of the connective tissue around the calcaneal bone
had to be dissected to detach the PL tendon from the calcaneal bone. The PL
tendon retracted after it had been cut. The majority of the epitendinous
tissues was left intact (Fig.
2B). Subsequently, the proximal (GM) and distal (GM) forces
exerted by GM were measured.
3. In the reference position
(A) With connective tissues present exclusively around the GM muscle
belly. Following the previous measurements, all epitendinous tissues
surrounding the distal tendon of GM was dissected without moving the hind limb
within the experimental set-up (Fig.
2C). The proximal (GM) and distal (GM) force-length
characteristics were determined without any connective tissue around the
distal tendon. Connective tissue (i.e. remnants of the general fascia and
epimysium) around the GM and PL muscle bellies was still present
(Fig. 2C). The proximal
reference position of GM was defined as the position in which the origin of
the muscle is situated as the knee angle is set at 120°.
(B) After full dissection of GM muscle. Subsequently, the GM muscle belly was dissected free from extramuscular tissues without removing the hind limb from the experimental set-up. The extent of this dissection is limited, because GM innervation and blood supply need to be kept intact (Fig. 2D). This means that connective tissues associated with the neuro-vascular tract remained connected to the GM muscle at its proximal region. This situation is referred to as the in situ situation.
4. The effects of moving GM origin
Finally, the origin of the fully dissected GM muscle was moved towards a 3
mm more-proximal or a 3 mm more-distal position prior to measuring
force-length characteristics for distal lengthening. Moving the origin of the
fully dissected muscle changes the relative position of the muscle belly with
respect to the neuro-vascular tract. The direction in which the proximal
origin was moved first was imposed randomly for different muscles. After
moving the distal force transducer over an identical distance and direction,
identical initial muscle lengths are obtained but with different positions of
the muscle relative to the neuro-vascular tract.
Statistics
Values are presented as means ±
S.E.M. Two-way analyses of variance (ANOVA)
for repeated measures (factors: proximal/distal location of force exertion and
muscle-tendon complex length) were performed to test for differences between
proximally and distally measured forces and length effects. One-way ANOVA for
repeated measures (factor: muscle-tendon complex length) was used to test for
effects of length on proximo-distal force differences. Differences were
considered significant if P<0.05.
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Results |
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Significant effects (i.e. main effects of location of force exertion and muscle-tendon complex length as well as an interaction) were also found for passive forces (P<0.01). Passive forces measured at the distal force transducer were consistently higher than the proximally measured forces (Fig. 3B,D).
Extramuscular myofascial force transmission from PL
2. Effects of PL-tenotomy
After distal tenotomy of the PL muscle, the GM distal tendon was the only
tendon attached to the distal force transducer. Despite that fact, proximally
and distally measured active forces were not equal at the shortest and longest
lengths studied (Fig. 4A). For
example at L0, proximally exerted active force amounted to
9.2±0.3 N and distally exerted active force was 10.4±0.3 N.
Note, that at long muscle-tendon complex lengths, distal forces dominated
proximal forces. Whereas at the shortest lengths, lower distal forces than
proximal forces were measured. A significant ANOVA main effect of location of
force exertion could not be shown (P=0.08). By contrast, significant
effects of length (P<0.01) and a significant interaction between
effects of the factors location of force exertion and muscle length
(P<0.01) were shown. Expressing the difference between proximal
and distal active forces as a function of muscle length
(Fig. 5A) allows assessment of
the contribution of force of the PL muscle and the significance of this
contribution. This proximo-distal force difference was calculated by
subtracting the proximal force from the distal force. ANOVA showed a
significant length effect on the force difference. At longer GM lengths
(L>-5 mm) such PL contribution for active force rises with
increasing GM length from 0 N to a substantial level of approximately 1 N.
Such levels of force difference correspond to fractions of approximately 0-40%
of the active force difference present with the GM and PL both exerting force
also by myotendinous pathways (shown for comparison in
Fig. 5). It is concluded that
despite the fact that PL distal tendon is no longer connected to the calcaneal
bone, active force exerted by the PL muscle is still transmitted onto this
bone via alternative paths.
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Significant differences were observed between passive forces exerted proximally and distally (P=0.001, Fig. 4B): distal forces being consistently higher. Also, significant effects of length (P<0.01) and a significant interaction between effects of the factors location of passive force exertion and muscle length (P<0.01) were observed.
For GM passive force the proximo-distal force difference ranged from 0 to 0.8 N (Fig. 5B). Except at the shortest lengths, this was no less than 60% of the passive force difference present with both GM and PL exerting force also by myotendinous pathways (shown for comparison in Fig. 5). It is concluded that effects of distally changing GM length differ for proximally and distally exerted active and passive forces.
Extramuscular myofascial force transmission from GM
3. In the reference position
(A) With connective tissues present exclusively around the GM muscle
belly. All epitendinous tissues surrounding the distal tendon of GM were
dissected to isolate the distal tendon fully. After this intervention, the
active force measured distally did not differ significantly from the force
measured proximally (ANOVA: no main effect of location of force exertion
P=0.38). For example at L0
(Fig. 6A), proximal and distal
active forces were 9.1±0.3 N and 9.2±0.3 N, respectively).
However, significant effects of muscle length (P<0.01) and a
significant interaction of location of active force exertion and muscle length
(P<0.01) were observed for active force. This significant
interaction is an indication for some myofascial force transmission from GM.
In accordance, ANOVA also showed a significant length effect on the GM
proximo-distal active force difference (P<0.01). However, for the
present experimental conditions, this effect is considered too small in
absolute and normalised terms (Fig.
6A) to attribute a functional relevance. It is concluded that in
the reference position, the extramuscular connections of the GM belly (i.e.
remnants of the general fascia and epimysium) are hardly capable of sustaining
GM proximo-distal active force differences under these experimental
conditions. This means that most of the proximo-distal active force difference
present after PL-tenotomy, but before dissection of the GM tendon (Figs
4A,
5A), must be ascribed
predominantly to the epitendinous tissues. These tissues are forming the path
for extramuscular transmission of active force from the PL onto the tendon and
calcaneal bone.
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For the passive force, both main effects of location of force exertion and muscle length as well as the interaction between both factors were significant (all P<0.01). Thus, a proximo-distal difference of passive GM force is sustained with the distal GM passive force being consistently higher than proximal GM passive force (Fig. 6B). Despite its small absolute size, the difference remains a sizable fraction of force exerted. For example at L0, the proximo-distal force difference is approximately 56% of the proximal passive force, whereas at shorter muscle lengths, this percentage is even higher. It is concluded that, in contrast to active force transmission, passive GM extramuscular myofascial force transmission persists at a considerable degree.
(B) In situ GM force-length characteristics after full dissection of the GM muscle. The GM muscle was subsequently dissected free from its extramuscular tissues except for its neuro-vascular tract. In such conditions, with the GM origin at the reference position, proximally measured active forces were not different from distally measured forces (no ANOVA main effect for location of force exertion, P=0.14). For example at L0 (Fig. 7A), both proximally and distally measured forces equalled 8.9±0.3 N. A significant effect of muscle length was observed (P<0.01), but no significant interaction effect between location of force exertion and muscle length was found (P=0.14). It is concluded that no evidence was found indicating extramuscular transmission of active GM force.
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Passive forces were still significantly different for the different locations of force exertion (P<0.01; Fig. 7B). A significant effect of muscle length (P<0.01) and a significant interaction effect (P=0.03) were also detected. Therefore, it is concluded that in experimental conditions with fully dissected GM with its origin kept at reference position, myofascial force transmission of active force does not play a role whereas extramuscular myofascial force transmission of passive force still does.
4. Effects of moving GM origin
The origin of the fully dissected GM muscle was moved by 3 mm to a
more-proximal or more-distal position, before measuring force-length
characteristics for distal lengthening. The distal force transducer was moved
over similar distances to obtain identical initial lengths as above. This
changed the relative position of the muscle belly with respect to
extramuscular tissues, i.e. the neuro-vascular tract.
(A) More proximal position. Subsequent to moving the GM origin towards a more proximal position, proximal GM active force exerted was significantly higher than distal GM active force. A main effect of location of force exertion (P=0.02), a significant effect of muscle length (P<0.01) and a significant interaction between effects of location of force exertion and muscle length (P=0.01) were found. For example at L0 (Fig. 8A), proximal and distal active forces were 8.3±0.5 N and 8.0±0.4 N respectively.
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For the passive forces, a main effect of location of force exertion was found (P<0.01), distal GM passive force being higher than proximal GM passive force. Also significant main effects of muscle length (P<0.01) were found, but no significant interaction between these factors could be shown (P=0.13; Fig. 8B).
(B) More distal position. After moving the GM origin towards a more distal position, the distally measured active forces (e.g. 7.7±0.5 N at L0) were higher than the proximally measured forces (e.g. 7.2±0.6 N at L0; Fig. 8C). Despite the fact that qualitatively similar results were found for all muscle lengths studied, we could not show a significant ANOVA main effect for location of force exertion (P=0.095). A significant effect of muscle length was detected (P<0.01). The effect of muscle length was not significantly different for the different locations of force exertion (P=0.08). It is concluded that a proximo-distal difference of active force of fully dissected GM reappears as the relative position of GM with respect to the neuro-vascular tract is altered.
Distal GM passive forces were significantly higher than proximal passive forces at most muscle lengths (Fig. 8D). A significant main effect of location of force exertion (P<0.01), a significant effect of muscle length (P<0.01) and a significant interaction between effects of location of force exertion and muscle length (P=0.01) were observed. Thus, in both conditions distal GM passive forces were higher than proximal GM passive forces.
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Discussion |
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Extramuscular connective tissue
Extramuscular connective tissue is continuous with intramuscular connective
tissue. Muscle fibres are linked to this intramuscular connective tissue
network via connections between cytoskeleton, extracellular matrix
and endomysium (e.g. Berthier and Blaineau,
1997; Patel and Lieber,
1997
). Many studies indicated that these tissues are capable of
transmitting force (Goldberg et al.,
1997
; Huijing,
1999a
; Monti et al.,
2001
; Street and Ramsey,
1965
; Street,
1983
). Therefore, changes in the position of the extramuscular
connective tissue relative to the muscle may also result in changes within
intramuscular connective tissue and muscle fibres (i.e. myofascial force
transmission).
In our present study, only extramuscular connective tissue around the GM and PL was left intact initially and was subsequently removed in phases. The neuro-vascular tract of the GM, consisting of nerves, blood vessels and their surrounding connective tissues, is one of the extramuscular connections and it enters into the GM proximally. Between the PL and GM muscles, no intermuscular connections (i.e. direct link between two intramuscular stromata) are present due to the fact that the PL muscle is ventral to the distal aponeurosis of GM muscle. Ventrally, the epimysium of the GM covers the aponeurosis but is not attached to it, other than via fascicle insertions at the dorsal aspect of this aponeurosis. Therefore, any connective tissue between the aponeurosis of GM and the PL muscle must constitute extramuscular tissue. At the level of the PL and GM tendons, various extramuscular connective tissues (remnants of general fascia, epimysium, neuro-vascular tract and compartmental fascia) form connections between the epitenons of those tendons. These epitendinous tissues also attach to the calcaneal bone.
Extramuscular myofascial force transmission via epitendinous tissues
Because PL exerts force proximally at its origin on the lateral epicondylus
of the femur, this force was not measured in the present experiment.
Therefore, a difference in force exerted on the distal and proximal force
transducers (by summed effects of GM and PL at the calcaneal bone and by the
proximal GM tendon, respectively) was expected and observed with intact
extramuscular connective tissues. However, the fact that a proximo-distal
force difference was still observed after distal tenotomy of PL without
removing the epitendinous tissues indicates extramuscular myofascial force
transmission. At longer GM lengths, the force at the distal transducer was
higher than GM proximal force. Thus, a fraction of the active force generated
by PL was transmitted onto the calcaneal bone via other tissues than
its tendon. This extra force exerted at the distal force transducer was up to
40% of the extra force generated with the PL tendon still attached to the
calcaneal bone.
After dissection of the epitendinous tissues, the force difference
disappeared (Fig. 6A),
indicating that those tissues must have formed the path for myofascial force
transmission. It is concluded that the epimysium of GM and PL are connected to
the epitendinous tissues. Force exerted distally by PL is transmitted
via these epitendinous tissues directly onto the calcaneal bone,
because the tendon does not seem to be connected to its epitenon, and
therefore also no connections exist between the tendon and the epitendinous
connective tissues. This view is compatible with observations that serious
problems do occur within the tendon if such connections are formed
pathologically by collagen fibre reinforcements of nerves and blood vessels
entering the tendons perpendicularly
(Alfredson, 2004). Thus, a
novel result of the present study is that extramuscular myofascial force
transmission also occurs via epitendinous tissues.
Before dissection of epitendinous tissues and even with PL still attached
to the calcaneal bone, at shorter lengths the distal force was lower than GM
proximal force. This surprising result indicates that not all force of both
muscles is exerted at the calcaneal bone, but is partly transmitted in a
distal direction via the extramuscular tissues of the posterior
compartment and the epitendinous tissues to the underlying tissues of the
lower hind limb (Fig. 1B). The
results after PL-tenotomy and after removing the epitendinous tissues indicate
that more force was transmitted via the epitendinous paths than
via other extramuscular tissues, since the effect became much smaller
after removal of the epitendinous tissues. The fact that the proximo-distal
force difference is negative only at short GM muscle lengths
(Fig. 5A) is explained by the
varying position of the epitendinous tissues relative to GM with changes in GM
muscle length. A changed configuration of such connective tissue leads to
changes in the degree and direction of myofascial force transmission
(Huijing and Baan, 2003). At
short GM lengths, the force borne by these connections between the
epitendinous tissues and underlying tissues of the lower hind limb is oriented
in a distal direction but away from the calcaneal bone
(Fig. 9). At long GM muscle
lengths, the direction of the connection is reversed. Therefore, the force
borne by these connections is oriented towards a proximal direction
(Fig. 9).
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Myofascial transmission of passive force
Passive forces are usually assumed to be either very small or absent when
the muscle is below its optimum length. This is true for fully dissected
in situ muscle, but for a muscle surrounded by other muscles and
connective tissue, this may be different. In the present study, passive forces
of approximately 0.3 N were measured on the distal side of the muscle at short
muscle lengths. The passive forces are probably the result of the surrounding
(extramuscular) tissues, which may be at a long length while the muscle is at
a very short length. It could also be a contribution from the PL muscle. At
the proximal side, passive forces were absent because the GM muscle was
dissected free from extramuscular tissues at that side. When the distal side
of the GM muscle was also dissected free from extramuscular tissues, there was
still a small difference between proximally and distally measured passive
forces. The distally measured forces were slightly higher than the proximally
measured forces. Some passive force could be transmitted via the
proximal part of the neuro-vascular tract to GM.
The neuro-vascular tract as a pathway for extramuscular force transmission in dissected in situ GM muscle
In the final stage of preparation in the present study, the GM was
dissected from almost all extramuscular tissues, leaving only the
neuro-vascular tract intact. In this stage of the experiment, this tract
contains the only remaining extramuscular connective tissue. The
neuro-vascular tract is composed of the tibial nerve approaching and entering
GM from the lateral side and the anterior tibial vein and artery approaching
and entering GM from the medial side with a connective tissue sheets
enveloping all. With the knee flexed at 120°, this proximal aspect of
neuro-vascular tract near the GM is positioned almost perpendicular to the
line of pull of the muscle. An important purpose of the collagen fibres within
this tract is to protect the nerves and blood vessels from high strains. To
perform this function, this connective tissue has to be fairly stiff and it
will provide a potential path for myofascial force transmission. In the
reference position of GM, no appreciable myofascial force transmission was
apparent in the present study. This indicates that the neuro-vascular tract is
in such a condition that it is either rather compliant or perpendicular to the
muscle and therefore not able to transmit force.
Changing the relative position of a muscle or its origin will result in a different length and configuration of the connective tissue connecting the muscle with the proximal aspect of the neuro-vascular tract. As the origin of GM was repositioned to a more-proximal or more-distal position, a proximo-distal force difference was present, indicating extramuscular myofascial force transmission via the neuro-vascular tract. The sign of the proximo-distal difference of active force was dependent on the direction of repositioning of the muscle. This is explained by that fact that repositioning the muscle towards a more proximal position causes the proximal aspect of the neuro-vascular tract to approach the muscle from a more-distal direction. Then, some force is transmitted in a distal direction between the neuro-vascular tract and the GM. This extra force constitutes an additional load on sarcomeres located proximally within the GM muscle fibres. As a result, proximal active force is higher than distal active force. By contrast, in both conditions (moving the GM from the reference position towards either a more-proximal or a more-distal relative position) the GM distal passive forces were higher than the GM proximal passive forces. Therefore, it is concluded that the contraction of the GM on activation is responsible for the reversal of the direction of force transmission.
Extramuscular force transmission in vivo
One may question if force is transmitted via extramuscular
pathways in vivo. In the literature, some indications are found that
this in indeed the case. Gregor et al.
(1988) measured forces at the
Achilles tendon during gait of a cat and found that the measured forces were
higher than maximal force of a muscle in a fully dissected in situ
set-up, despite the fact that during gait, the muscles are expected to
contract submaximally. The unexplained high force might be explained by
extramuscular force transmission (Huijing,
1999b
). Furthermore, Riewald and Delp
(1997
) and Asakawa (2002)
found that the rectus femoris muscle was still able to generate an extensor
moment after a distal tendon transfer to the flexor side of the knee. Although
it is not clear if this is the result of extramuscular myofascial force
transmission, it seems plausible that some type of myofascial force
transmission is involved. It may be argued that scar formation after surgical
intervention could alter myofascial force transmission. However, at the long
term, scar formation may also lead to formation of new or regular tissues (for
a review see e.g. Liu et al.,
1995
), presumably leading to new myofascial paths.
In situ experiments
In physiological experiments, many characteristics of muscle have been
studied using fully dissected in situ preparations of animal muscle,
with only the neuro-vascular tract left intact. Dissection is performed on
inter- and extramuscular connective tissues to gain access to the muscle.
Denny-Brown (1929) is one
author who mentioned explicitly that dissection was performed to exclude the
interaction of the surroundings of a muscle with that muscle, but generally,
the effects of connective tissue are not taken into account. For the fully
dissected GM in the present study, it is concluded that no myofascial force
transmission occurred via the neuro-vascular tract in the reference
position. However, after moving the GM origin, some myofascial force
transmission reappeared. From these results, it is concluded that regarding
in situ experiments, one has to be aware of the position of the
muscle with respect to the extramuscular tissues. If an appropriate position
is chosen, myofascial force transmission will not be effective and therefore
not influence the results. However, when applying conclusions of such
experiments to in vivo conditions, it should be realised that
myofascial force transmission may play a role in altering muscular
characteristics (Huijing,
2003
).
In conclusion, extramuscular myofascial force transmission within the posterior compartment of the rat lower leg plays a role even after substantial dissection has been performed on the compartment. With intact extramuscular connective tissues around the whole GM and PL muscle-tendon complex, active force of the PL is transmitted onto the calcaneal bone, even after the PL tendon has been cut from this bone. After dissection of all of the epitendinous and the majority of the epimuscular connective tissues, myofascial transmission of passive force remains important, but myofascial transmission of active force is either absent or becomes so small that its effects may be neglected for most purposes. However, this is only true if the GM origin is kept in a position corresponding to a knee angle of approximately 120°. After moving GM origin from this position, some myofascial transmission of active force occurred.
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