Gwen Ralphs
Thomas R. Lunsford, C.O.
Jack Greenfield, C.O.
Introduction
The conservative management of many
common foot disorders involves the prescription
of shoe inserts. Boulton1 showed
that neuropathic diabetic patients with a history
of foot ulceration have abnormally high
pressures, as high as 20-30 kglcm2, under the
forefoot during walking. These patients are
at risk of recurrent ulceration because of impaired
pain and joint position sensation and
increased pressures under the metatarsal
heads. Broadley2 considers rheumatoid arthritis
as a model for hallux valgus, hammer
toes, flattening of the longitudinal arch, pronation
of the hind foot, metatarsalgia,
thinned skin, and thinned subcutaneous tissues.
Patil3 studied leprotic feet in Hansen's
disease where loss of sensation and muscle
paralysis can lead to physical deformity and
irreversible nerve damage. Excessively high
pressure on the leprotic foot for prolonged
periods causes mechanical damage to skin
and soft tissues without the patient's knowledge.
Patil showed that the feet of leprosy
patients exhibit pressures two to three times
the pressures found under normal feet (9.2-
11.2 kg/cm2).3
Possible solutions to the foot problems of
these and other types of patients include custom
designed shoes and/or inserts. The inserts
can be custom molded or soft unmolded
insoles made from Plastazote® or Spenco®
cut in the shape of the standard sock liner
insert. The custom molded inserts generally
incorporate force redistributing features.4,5,6
Attempts to reduce excessive plantar pressure
have produced a wide variety of shoe
inserts which are placed between the shoe
insole and the plantar surface of the foot.
Due to the great number of materials and
designs for inserts available, there is a need
for a clinical method of determining which
patients require orthotic inserts and a reasonably
simple and objective method of determining
the effectiveness of a given orthosis
in reducing pressure. Further, because
patients' feet change as well as their inserts,
a simple and objective method is needed to
assess insert efficiency after being worn by
the patient for a given period of time.
Interest in both a qualitative and quantitative
understanding of pressures on the plantar
surface of the foot has inspired many
insightful techniques of measuring the pressures.
Beyerlein7 devised an array of rubber
pyramids which produced an image that was
transmitted to a viewing screen by fiber optics.
Guth8 measured pressure distribution
from an array of spring loaded pins whose
movements were processed by a computer.
Stokes9 placed 12 beams on each of two
strain gauge force transducers on a platform
mounted on a plate in a walkway. Hennig1O
serially connected capacitance force transducers and light emitting diodes, whose light
density depended on the force-dependent
impedance of the capacitors. Shipley11,12
used the "Harris" footprint mat to record
plantar pressures. In general, existing methods
of measuring pressure are costly, time
consuming;, or cannot be performed within
the shoe.13,14,15
C. Itoh & Company (America), Inc. has
developed Fuji Prescale Film for direct observation
of the pressure distribution between
two surfaces (such as the shoe insole
and the plantar surface of the foot). The
pressure is determined by comparing the
shade of red on the film with a color chart
calibrated for pressure. One application of
pressure to the film will produce the same
shade of red as multiple applications. There
are four grades of film which allow pressures
to be measured from 5-700 kg/cm2.16
A previous attempt to evaluate Fuji Prescale Film
was made by Aritomi, et al.7 In this study,
subjects being evaluated stood on a mat containing
5/32" diameter ball bearings under
which were placed the prescale film. The
developed film was an array of red dots with
varying intensity which were transformed
into isopressure contours via computer topography.
Then the authors attempted to
correlate the results of x-ray examinations
with the isopressure charts. Although this
study confirmed the diagnostic properties of
the prescale film with experimental correlations,
it did not demonstrate its clinical usefulness.
It is the purpose of this study to
evaluate the feasibility of using Fuji Prescale
Film as a means of clinically assessing plantar
pressure in a controlled group of subjects
representative of the vast population of patients
for whom inserts are prescribed.
Figure 1. Separate pieces of Fuji A-film and C-fiIm.
Method
Ten patients, eight females and two males,
who had complained of foot pain or had calluses
on their metatarsal heads were selected
as subjects for this study. They ranged in age
from 23 to 51 years and in weight from 135 to
215 pounds. The patients were diagnosed as
having metatarsalgia or pes cavus, and shoe
inserts had been prescribed to relieve their
pain. Impressions were taken of the subjects'
feet and the casts were modified by building
up the metatarsal head area. Custom cork/
Spenco® inserts were fabricated by vacuum
forming thermo-cork and lining with
Spenco® as a sock liner. A second insert,
non-molded Plastazote®, was made by cutting
pieces of 114" thick Plastazote® to fit into
the patients' shoes.
Fuji Prescale Film was placed in each patient's
shoe so that it was compressed by the
metatarsal heads as the subject walked. The
Fuji pressure sensitive film consists of two
sheets, a color forming sheet (A-film) and a
color reactive sheet (C-film). The C-film is a
common grade, having an applicable pressure
range of 5-700 kg/cm2, while the A-film
is available in four grades: super pressure
(70-250 kg/cm2; and high pressure (250-700
kg/cm2). Only the super low and low pressure
grades were used in this study.
Figure 2. Circle on first metatarsal head.
Separate pieces of Fuji A-film and C-film
were cut into matching rectangular strips (1 x
3 inches) and joined together by taping all
sides (Figure 1). This sandwiching ensured
that the appropriate reaction would occur
during weight-bearing. The first metatarsal
head was palpated and marked on the plantar
surface with a circle in order to assure
proper placement of the film patch (Figure
2). The rectangular film patch was taped to
the subject's foot to keep it in place (Figure
3). A shoe was placed on the subject's foot
and the subject walked 30 steps without the
shoe insert. The first film patch was removed
and the shade of red produced was compared
to the color-pressure chart and associated
pressure recorded. A second patch was applied;
the subject walked 30 steps with the
Cork/Spenco® insert, then this patch was removed
and read. Finally, a third film patch
was applied; the subject walked 30 steps with
the 114" thick Plastazote® insert; and this
patch was removed and read. All subjects
wore athletic shoes. In each trial, the film
pressure reading was taken 20 minutes after
exposure as indicated in the instruction manual
for the Fuji film.16
The circle from the metatarsal head was
transferred to the film and the darkest area
within this circle was recorded. The pressure
distribution is readily observable by the color
density pattern formed on the C-film. For
super low pressure Fuji Prescale Film there
are six shades of red which can be related to
pressure (Figure 4). For the low pressure film
there are seven shades (Figure 5). The clinician
selects which color sample on the chart
matches the color on the film, a horizontal
line is projected from the color sample selected
to the curve, and then a line is projected
vertically downward where the associated
pressure is read. A 15% to 20% experimental
error results from not knowing where on
the color sample box to project horizontally
to the curve. However, after a few film
patches were compressed, it was observed
that the shade of red on the film patch exposed
did not match any of the color samples
on the chart, i.e., the exposed film color was
darker than one sample and lighter than the
adjacent sample. Therefore, each color sample
box on the chart was divided into an
upper half and a lower half. The upper half
of the box was selected if the exposed film
was slightly darker than the color in the box
and the lower half was selected if the exposed
film was slightly lighter. The color
samples on the super low and low pressure
charts were divided in half and the corresponding
pressures tabulated (Table 1). The
width of each half box represents the range
for each reading and was determined graphically
by projecting horizontally from the top,
middle, and bottom of each color sample box
on the two pressure charts.
Figure 3. Rectangular film patch taped to subject's foot.
Figure 4. Super low pressure type pressure chart.
Results
The results of evaluating the ten subjects
with no orthosis, a cork/Spenco® shoe insert,
and an unmolded Plastazote® insert are
shown in Table 2. The mean pressures (±
standard deviation) for the ten subjects were
34.2 (±2.4) kg/cm2, 15.9 (±1.2) kg/cm2,
and 16.5 (± 1.2) kg/cm2 for no orthosis,
cork/Spenco®, and Plastazote®, respectively.
Generally, each of the shoe inserts
resulted in less pressure on the metatarsal
heads than was the case with no orthosis
(p7/805). However, the difference between
pressures measured with custom molded
cork/Spenco® insert versus the unmolded
Plastazote® was not significant, 15.9( ± 1.2)
versus 16.5( ± 1.2) kg/cm2. The percent
reduction in pressure for each of the
two inserts was computed and again
the difference was not significant
(Table 3): 53.2( ±4.70) versus 51.1( ±6.13)
percent.
Figure 5. Low pressure type pressure chart.
Table 1. Color Chart Interpretation.
Discussion
Previous clinical experience with custom
molded cork/Spenco® and unmolded Plastazote® shoe inserts confirms the results obtained
with the Fuji Prescale Film. That is,
either of these inserts is better than no orthosis
for relief of metatarsal head pressure.
However, previous clinical experience supports
the use of custom molded cork/
Spenco® versus unmolded Plastazote® inserts.
This was not demonstrated by the Fuji
Prescale Film and the color chart calibration
method of determining pressure.
Perhaps the shades of red were too subtle
to be differentiated visually on the color
charts? Fuji (C. Itoh & CO.)16 has available
an electronic densitometer which reportedly
can resolve closer shades of red.
The color sample boxes along the ordinate
of the calibration curves exceeded the usable
limits of the curve. For example, on the super
low and low pressure film chart, the most
and least dense color boxes could not be
used because horizontal projections with the
curve did not exist.
The charts indicate that the pressure to be
measured must be applied for at least two
minutes. However, this was not considered
practical and the subjects were asked to take
30 steps instead. The error associated with
the variation is unknown. Early experimentation
with small samples of the film indicated
that the time integral related to pressure
being applied for 30 steps was not perceptibly
different from pressure being applied for
two minutes or longer.
It is estimated that in a clinical setting, at
least three film samples will be required per
foot. One sample will be required with no
orthosis to establish the need for the insert,
one with the insert in the shoe to verify its
efficacy, and one several months later as follow-
up. The cost for the three film samples,
at present levels, may preclude its usefulness.
It is estimated that approximately 10
minutes is required by the practitioner at
each plantar pressure sampling.
Small rectangular patches and color charts
were used in this pilot study because the film
and densitometer costs exceeded the limited
funds available for the study. A full scale
clinical study needs to be conducted using a
Fuji densitometer and Fuji Prescale Film
samples which match the entire insole area
of the subjects' shoes.
Authors
Table 2. Metatarsal Head Pressures - Color Chart Interpretation.
Table 3. Percent Reduction In Pressure.
References
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