Don't Get Married Part 2
from
Erik Dalton, Ph.D.
Article as seen in Massage Today Magazine August 2008
Humans are designed to move in order to survive – locomotion must
precede all other activities. The past few decades have witnessed
the emergence of two diverse schools of thought, each with their own
biomechanical explanations detailing the seemingly simple act of
walking.
| Both disciplines generally agree that
cross-patterned gait (opposite arm and leg moving at
the same time) is a normal function of walking and
running. However, advocates of the traditional
"pedestrian model of gait" insist the legs are the
main-event in locomotion and upright walking is a
basic design where the legs propel the passive
passenger – the trunk – through space. Pedestrian
model groupies tend to lump the torso, arms and head
together and generally dismiss the upper body as a
critical player in gait mechanics.
As discussed in
part 1 (Feb. 2008 issue), Canadian nuclear
physicist Serge Gracovetsky, PhD, rebuked the
pedestrian model by declaring that counter-rotation of
the shoulders and pelvis is an essential key to
locomotion and force is not generated by the legs, but
instead arises through a complex muscle/skeletal
interaction propelled by what he calls a "spinal
engine."1 He further explains,
"Evolutionarily, locomotion was first achieved by the
motion of the spine. ... The legs came afterward as an
improvement, not as a substitute."
If Gracovetsky's theory that the spine is the
primary engine driving the pelvis has "legs to stand
on" (no pun intended), then manual therapy assessments
and rehabilitative corrections must be modified
accordingly. Since low back pain is the most common
disability among people under the age of 45, the
consequence of this reinterpretation of spinal
function could be far-reaching. Today, researchers and
clinicians worldwide are experimenting with
Gracovetsky's intriguing hypothesis. |
|
 |
|
Figure 1 |
|
 |
|
Figure 2 |
|
| Since both schools of thought are supported by
sound research in the gait-analysis community, I'm
trying hard not to marry a single model of locomotion.
To prevent the suffering that accompanies divorce,
I've developed assessments and corrections based on
gait studies conducted by two renowned experts in the
field, Serge Gracovetsky and my mentor, Philip
Greenman.2 This osteopathic and physics
collaboration paints a broader, more comprehensive
picture of the walking cycle. Unfortunately, in the
process of marrying the two methods, some of
Gracovetsky's brilliant spinal-engine concepts have
been altered. To avoid misrepresenting the views of
either researcher, the proposed model in part 2 will
simply be referenced as the "myoskeletal engine."
The Myth of Leg Locomotion
Dr. Gracovetsky convincingly asserts, "If the legs
were truly the mobilizing force propelling the body
through space, a competitive sprinter with huge
powerful legs and a small torso should be the
fastest." (Figure 1) Obviously, this
image does not fit the picture we'll see at the
Beijing Olympic Games or even in the photo of a
21-year-old South African double-amputee runner Oscar
Pistorius, who finished second against the world's top
athletes in a 400-meter race at the Golden League Meet
last year in Rome. (Figure 2) |
|
 |
|
Figure 3A |
|
Initial observation of Pistorius' stride
reveals a rhythmic cross-patterned gait and strong
pelvic/shoulder counter-rotation that appears as the driving
force propelling his lower extremities. Figures 3A
and 3B illustrate global and core muscle
"slings" that store and release kinetic and elastic energy
that help him run at such high speeds. In the absence of
lower legs and feet, one might conclude these anterior and
posterior spring systems alone provide enough thrust to
propel Pistorius' pelvis and extremities. But apparently,
the International Association of Athletics Federations (IAAF)
disagreed. They voted to ban him from formal competition
based on the conclusion this artificial "springing"
mechanism somehow amplified his interaction with
gravitational ground forces. |
 |
|
Figure 3B |
|
For example, if a car has a low tire and the tread begins
wearing unevenly, the vehicle will begin to shake sooner or
later. As the vibration makes its way through the suspension
system, the tie rods start working loose. If left untreated,
damage spreads to the motor mounts. Eventually, the "shaky"
engine sputters to a halt. Although the low tire was the root of
the problem, it's tempting to blame the engine because the car
no longer runs.
In this regard, it's easy to see how a deflated tire might
perpetuate a chain of events manifesting as compensations
elsewhere. To remove kink(s) from the system, an experienced
mechanic won't immediately pull the hood and begin checking for
loose spark plugs and battery cables. Tracking down the
dysfunction typically starts by consulting with the owner,
conducting a thorough history of onset, symptoms, etc., and then
performing a detailed inspection that leads to the "key lesion"
– the low tire. From information garnered during the evaluation
process, the mechanic is able to systematically work their way
though the suspension system, motor mounts and fuel-injection
system to restore optimal motor functioning.
| The same applies to the client with a flat
foot and short leg. A good body mechanic doesn't treat a
hyperpronated foot in isolation but looks for compensations
along the kinetic chain that might have developed as a
result of the shortened extremity. Kinks traveling from the
head down (TMJ, O-A, scoliosis, cranial distortion, etc.)
are labeled descending syndromes, while asymmetry caused by
pronated feet, short legs, knock-knees, etc. are referred to
as ascending syndromes. (Figure 4) Any
soft-tissue or bony compensation that distorts the vertebral
column's S-shaped curve will overwork the anterior and
posterior spring systems, resulting in stress and pain. |
 |
|
Figure 4 |
|
 |
|
Figure 5 |
|
Stirrup Spring System The
automobile analogy provides a nice segue for introducing a
third biomechanical "sling" critical in driving the
myoskeletal engine. Known as the stirrup spring system (SSS),
this antigravity propulsion pump delivers energy from the
tibialis anterior/peroneus longus stirrup through the biceps
femoris and sacrum to provide rotary torque that "winds up"
intervertebral joints and deep collagen structures.
Figure 5 depicts a few key SSS muscles activated
during running. Although, I agree with Gracovetsky that
efficient movement requires humans to possess some kind of
recovery pulse to avoid loss of kinetic energy into the
ground during gait, the biomechanics of how that pulse is
delivered is debatable.
|
Gait analysis is best understood when viewed just
prior to heel strike, as illustrated in Figure 5. For the
SSS to achieve optimum elastic recoil, two neurologically
driven maneuvers must orchestrate in perfect harmony. With
hip extensors (biceps femoris and G-max) maximally
stretched:
- Muscle spindles and GTOs rapidly transition from
eccentric to concentric contraction to curtail hip
flexion and knee extension.
- Tensional forces send elastic energy spiraling down
the leg through the tibialis/peroneal stirrup to lift
the arch and stabilize the ankle and foot in preparation
for heel strike.
Walking and running trigger various degrees of force
through the stirrup, knee, lateral thigh, biceps femoris
and sacrotuberous ligament. The amount of force at heel
strike determines how much lumbopelvic counter-rotation
takes place and what muscles/ligaments are recruited. Once
the pulse reaches the pelvis, the mechanics become more
complex.
At this point, Gracovetsky and I part ways. He believes
the recovery pulse at right heel strike possesses
sufficient strength to travel unimpeded up the leg,
through the sacrotuberous and long dorsal sacroiliac
ligaments, and into the ipsilateral multifidi, longissimus
and iliocostalis. Erector spinae contraction then causes
right lumbar sidebending and reciprocal pelvic
counter-rotation. Although this intriguing firing order
does play a major role in running, it differs a bit from
my interpretation of Greenman's heel strike mechanics
during walking.
Myoskeletal Engine Possibility
Notice in Greenman's illustration (Box 1,
Figures 1 and 2) at
right heel strike, the sacrum, pelvis and lumbar spine are
all left rotated. This implies that during the
walking cycle, heel strike probably doesn't transmit
adequate force to sidebend the lumbars and counter-rotate
the pelvis, as Gracovetsky infers. A myoskeletal-engine
firing order that seems to best fit Greenman's
illustration has the stirrup pulse traveling through the
biceps femoris and sacrotuberous ligament, tugging on the
lateral sacral angle, and (with help from the quadratus
femoris and G-max), left-rotating the entire pelvic bowl
in a transverse plane.
| |
 |
|
| |
Box 1 |
|
|
Gracovetsky's spinal engine theory is based on the assumption
humans possess no muscles capable of directly rotating the
pelvis. But if one follows the chain of events beginning at heel
strike to the stance phase, it appears the sacrum and pelvis
perform complex maneuvers enhanced by many smaller but extremely
important muscles that do possess the capability to directly and
indirectly rotate the pelvis. At first glance, it seems an
insignificant point, so long as the final result is a smooth
cross-patterned gait. However, it implies the possibility of a
different SSS firing-order pattern traveling through the
lumbopelvis and thus the need for alternative assessment and
treatment sequences.
| Stance Phase Is True Coupled
Motion
The myoskeletal SSS theory relies on Harrison
Fryette's 1st Law of Spinal Motion3
which (paraphrasing) states that in the presence of
normal lumbar lordosis, vertebral and sacral rotation
and sidebending occurs to opposite sides. (Figure
6) Gracovetsky believes this coupled motion
takes place at heel strike and I see it happening
during the stance phase. In my model, the following
actions occur during the one-legged stance phase
(right limb): |
|
 |
|
Figure 6 |
|
 |
|
Figure 7 |
|
- The biceps femoris co-contracts with external hip
rotators (piriformis, gemelli, obturator internis and
quadratus femoris) and the sacral attachments of G-max. (Figure
7) Combined, these tonic "short-lever" muscles
trigger pelvic rotation by pulling the sacrum into left
sidebending/right-rotation, which reciprocally right
sidebends/left-rotates the lumbars. (Box 1,
Figures 3 and 4)
- Instantaneously, Gracovetsky's firing pattern kicks in
as increased weight bearing enhances biceps femoris
contraction that extends through the sacrotuberous and SI
joint ligaments and into the multifidi, longissimus and
iliocostalis. This also causes lumbar right sidebending
and pelvic right-rotation.
- As gravitational forces compress and lock the
intervertebral joints, a rotary torque is stored as
potential energy in the disc's annulus fibers and deep
ligaments.
- Upon recoil, the spine's tightly wound core initiates
a vigorous torsional thrust which counter-rotates the
pelvis and shoulders while stabilizing the head to
maintain balance.
- With all four spring systems working harmoniously,
kinetic, potential and elastic energy are efficiently
stored and released at precise moments to efficiently
propel the body through space.
|
 |
|
Figure 8 |
|
Lateral Spring System Can't Get No
Respect! Last, but not least, the lateral spring
system (LSS) depicted in Figure 8 might be
one of the most unappreciated of all the body's antigravity
structures.
Driven by the hip's abductors, this elegant myofascial
gait-enhancer "cocks' the ipsilateral innominate and, just
prior to push-off, right-sidebends the rotating pelvis so
the other three spring systems can smoothly swing the left
leg through. (Box 1, Figure 5)
All is well if gluteus medius and minimus are properly toned
and firing in correct sequence. Regrettably, this spring
system commonly is skewed as other abductor muscles
overpower the weak glutes.
Figure 9 illustrates the need for
greater contralateral OL recruitment in athletes such as
hurdlers and running backs. However, during normal gait,
both quadratus muscles should be relatively silent. Thus,
the ideal abduction firing-order pattern from stance through
toe-off should be: gluteus medius/minimus; co-contraction of
the ipsilateral adductors; tensor fascia latae; piriformis
(synergistic stabilizer) and quadratus lumborum.
|
 |
|
Figure 9 |
|
|
Box 2
A greatly underestimated source of discogenic and facet
joint pain arises when the ipsilateral QL fires first,
"hip-hikes" the innominate, and forces the ipsilateral leg
to try to swing through |
|
 |
|
Figure 10A |
|
These people walk like a block with a
labored gait. Seen in many golfers and other athletes who
participate in one-sided sports, this common QL substitution
pattern is quite easy to assess and correct. Figures
10A and 10B demonstrate two QL
releases that help drag down a hip-hiked (posteriorly
rotated) ilium. Unfortunately, fixing the QL problem won't
completely restore proper firing order if the glute medius/minimus
are weak. Fast-paced spindle-stim techniques and "clam" home
re-training exercises using resistance tubing are a simple
solution. Although most clients like deep gluteal massage
and stretching, these traditional bodywork maneuvers alter
the hip-abductor firing order and destabilize the pelvis.
Weak glutes = future hip replacements. |
 |
|
Figure 10B
|
|
The theoretical approaches presented in this two-part series
represent an ongoing personal journey into the captivating world
of gait. Attempting to blend Gracovetsky and Greenman's
gait-analysis theories has opened a Pandora's Box of additional
inquiries questioning how ascending and descending syndromes
(flat feet, TMJ, knee injuries, etc.) destabilize pelvic and
lumbar spine balance. What seems clear is the necessity for
restoring perfect coordination and antigravity function to all
four spring systems. Energy conservation during walking or
running demands all systems fire in a precise order at just the
right moment to accomplish this task. I've become married to the
idea that all the body's global and core structures must work
harmoniously to produce rhythmic and effortless movement during
normal activities and athletic endeavors. Try experimenting with
spring system balancing routines and elevate your hurting
clients and competing athletics to a new level of health.
References:
- Gracovetsky S. The Spinal Engine. New York:
Springer-Verlag, 1988.
- Greenman PE. Muscle Energy class handout. Michigan State
College of Osteopathic Medicine, 1986.
- Fryette HH. Principles of Osteopathic Technique.
Indianapolis, 1918.
- Schleip R, Naylor D, Ursu W, et al. Medical Hypotheses,
2006, Vol. 66.
|
