Spasticity Assessment through Pendulum Testing in Individuals
with Tetraplegia Undergoing Rehabilitation with Neuromuscular
Electrical Stimulation
Eliza Regina Ferreira Braga Machado de Azevedo
1
,
Renata Manzano Maria
1
, Renato Varoto
2
,
Karina Cristina Alonso
1
and Alberto Cliquet Junior
1, 2
1
Biomechanics and Rehabilitation Lab., Department of Orthopedics and Traumatology, Faculty of Medical Sciences,
University of Campinas – Unicamp, Campinas, Brazil
2
Biocybernetics and Rehabilitation Engineering Lab., Department of Electrical Engineering, University of São Paulo,
São Paulo, Brazil
Keywords: Spasticity, Tetraplegia, Pendulum Test, Neuromuscular Electrical Stimulation.
Abstract: Objective: To analyze the effects of different neuromuscular electrical stimulation (NMES) protocols on
spasticity improvement in subjects with tetraplegia. Methods: 13 patients with tetraplegia went through the
pendulum test evaluation before and after NMES treatment. During tests an electrogoniometer was placed
on a leg to measure leg oscillations and knee angles. Individuals were divided in two groups according to
the treatment: gait group with NMES (n=6) and exercise group with NMES (n=7) Results: Relaxation
index, test duration in seconds, angle of the first swing and rest angle of the leg in both legs were assessed
before and after the treatment for both groups. Most differences were observed in the gait group.
Conclusion: Both treatments with NMES have shown to be effective treatments for spasticity improvement
in individuals with tetraplegia.
1 INTRODUCTION
The spinal cord injury brings many complications to
the patients such as recurrent urinary infections,
osteoporosis, cardiovascular defects, muscle atrophy
and spasticity (Carvalho et al, 2001; Carvalho et al,
2006; Carvalho et al 2005; Sepulveda et al, 1997).
Treatments with neuromuscular electrical
stimulation (NMES) can minimize these
complications.
Different NMES techniques have been used from
12 channel stimulation down to 4 channel, which is
considered the minimum to generate gait after a
complete spinal cord injury. In this case, NMES is
applied to quadriceps muscles to promote knee
extension and fibular nerve which generates the
flexion withdrawal reflex (Rose J Gamble JG,
1993).
The spinal cord injury paralyzed muscle is
mainly composed by fast atrophied fibers. And when
it is electrically activated produces smaller force and
goes into fatigue quickly. So, it is necessary to
condition the atrophied and paralyzed muscle before
gait training (Rose J Gamble JG, 1993).
Besides muscle atrophy, spasticity is also
minimized by the use of NMES. Spasticity impacts
on the patients’ quality of life. It is easy to be
detected but difficult to be quantified. A subjective
assessment often used is the Modified Ashworth
Scale (Leitão et al, 2006).
Another assessment that also measures spasticity
but as an objective way is the pendulum test, created
by Wartenberg in 1951. This test version was
modified using an electrogoniometer to capture
variations in range of motions and oscillations of the
knee and has been used in individuals with spasticity
(Badj et al, 1982; Badj et al, 1984).
Recently, a device to perform the pendulum test,
consisting of an electrogoniometer and software for
visualization and data processing was built (Maria et
al, 2013).
Therefore, it becomes rather important to analyze
the effects of different NMES treatments on
spasticity improvement in subjects with tetraplegia.
91
Regina Ferreira Braga Machado de Azevedo E., Manzano Maria R., Varoto R., Cristina Alonso K. and Cliquet Junior A..
Spasticity Assessment through Pendulum Testing in Individuals with Tetraplegia Undergoing Rehabilitation with Neuromuscular Electrical Stimulation.
DOI: 10.5220/0004731100910094
In Proceedings of the International Conference on Biomedical Electronics and Devices (BIODEVICES-2014), pages 91-94
ISBN: 978-989-758-013-0
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
2 METHODS
Thirteen patients, all male with tetraplegia and
lesions over two years old were recruited. The injury
level ranged from C3 to C7. This study was
approved by the local Ethics Committee.
All individuals went through pendulum test
evaluation before and after the treatment at The
Biomechanics and Rehabilitation Laboratory of the
UNICAMP Clinical Hospital. They were positioned
on a chair with the trunk at an angle of 60 flexion
(figure 1). During tests, a flexible fiber optic
electrogoniometer was placed (model Shape Sensor
S700Joint Angle, Meancurand Inc. figure 2a) on a
leg of the patients in order to measure the
oscillations of the leg and angles of the knees (figure
2b).
Figure 1: Patient test position on a chair with the trunk at
an angle of 60º flexion.
The individuals were divided in two groups
according to the treatment: a gait group with NMES
(GG: n=6) and exercise group with NMES (EG:
n=7).
All subjects had their quadriceps femoris and
fibular nerve stimulated by a 4 channel electrical
stimulator with 25Hz, monophasic rectangular
pulses with 300µs duration and a maximum intensity
of 150V. In the EG group each patient was trained
for 20 minutes of knee extension under quadriceps
stimulation and 15 minutes under fibular nerve
stimulation.
In the GG group, individuals went through a
treadmill gait using NMES and body weight support
(40% of body weight reduction) at a speed of 1.2
km/h for 20 minutes. Physiotherapists helped move
the legs through the gait cycle.
All the measurements were performed three
times on both legs before and after the treatment for
subsequent data analysis (mean and standard
deviation).
Figure 2: a) Electrogoniometer Shape Sensor S700, b)
Electrogoniometer positioning.
3 RESULTS
In table 1 and 2 the anthropometric data of gait
group and exercise group, respectively, can be
observed (age, body mass index – BMI, neurological
level, duration of injury and medication).
Through the pendulum test were evaluated:
relaxation index (RI), obtained by the end angle of
the leg divided by the angle of the first swing of the
leg; test duration in seconds; angle of the first swing
that is, the first angle of knee flexion (Fang) and end
angle or angle of rest of the leg (Restang).
All data were analyzed before and after the two
different treatments on both legs and are shown in
tables 3 and 4.
Most differences were observed in the gait
group.
BIODEVICES2014-InternationalConferenceonBiomedicalElectronicsandDevices
92
Table 1: Gait group anthropometric data.
Patients Age
(years)
BMI Neurological
level
Injury
duration
(years)
Medication/
day
1 27 20.78 C5B 8 ‐‐‐
2 29 24.66 C4A 7 Baclofen
1pill
3 39 22.59 C4B 16 ‐‐‐
4 25 16.12 C5C 6 ‐‐‐
5
6
34
45
21.65
23.59
C7A
C4B
11
16
‐‐‐
‐‐‐
Mean/
Sd
33.17/
7.7
21.57/
3.0
‐‐‐‐‐‐‐ 10.67/
4.46
Abbreviations: SD, standard deviation; BMI, body mass index.
Table 2: Exercise group anthropometric data.
Patients Age
(years)
BMI Neurological
level
Injury
duration
(years)
Medication/
day
1 31
22.34 C3A 8 Baclofen
8pills
2 37
28.35 C4A 17 Baclofen2
pills
3 42 26.12 C4A 11 Baclofen2
pills
4 24 22.4 C6A 5 Baclofen8
pills
5
6
7
49
30
42
26.16
21.85
22.59
C5A
C5B
C4A
13
10
12
Baclofen1
pill
Baclofen3
pills
Baclofen3
pills
Mean/
Sd
36.42/
8.62
24.26/
2.56
‐‐‐‐‐‐‐ 10.85/
3.8
‐‐‐‐‐‐
Abbreviations: SD, standard deviation; BMI, body mass index.
Table 3: Right knee pendulum test results.
Groups
mean/
sd
RI Time
(s)
Fang
(⁰)
Restang
(⁰)
GGbefore
GGafter
0.82/
0.32
0.6/
0.09
8.7/
4.06
9.14/
3.27
88.56/
33.22
117.29/
11.13
61.82/
14.48
69.95/
13.15
EGbefore 0.65/
0.06
10.27/
1.27
117.71/
10.57
77.06/
12.59
EGafter 0.62/
0.08
11.31/
3.36
113.02/
12.75
69.31/
9.11
Abbreviations: SD, standard deviation.
Table 4: Left knee pendulum test results.
Groups
mean/
sd
RI Time
(s)
Fang
(⁰)
Restang
(⁰)
GGbefore
GGafter
0.69/
0.12
0.63/
0.06
7.8/
2.09
7.48/
1.14
78.74/
13.58
106.48/
11.74
52.46/
4.66
66.83/
4.75
EGbefore 0.63/
0.08
9.77/
3.37
105.45/
14.17
65.65/
8.54
EGafter 0.6/
0.08
10.84/
2.83
117.99/
13.59
71.66/
9.88
Abbreviations: SD, standard deviation.
4 DISCUSSION
The pendulum test is fast and easy to apply and in
addiction has an objective assessment.
In this study all patients showed some
improvement in spasticity in both legs after
treatments with NMES, evidenced by at least two
different variables. This improvement may have
occured due to neuromodulation, which happens
through the stimulation of agonist muscle directly to
the quadriceps femuralis and indirectly to the
antagonist (hamstrings) through fibular nerve with
flexion withdrawal reflex.
However in EG group this improvement was
more discret, which may have occurred due to all
individuals in this group take antispastic drug
(baclofen) and most aplenty, so the quadriceps
femuralis were more relaxed than in GG group.
Besides that, in GG group, only one patient takes
baclofen and one pill per day. The baclofen is a
gamma-aminobutyric acid (GABA) agonist that is
used to reduce muscle tone. GABA is an important
inhibitory neurotransmitter in the central nervous
system.
Before treatment EG individuals have already
presented better results when compared to GG
group. However, when results after the treatment are
compared between groups both have similar results
in all variables.
Granat et al (1993) analyzed spasticity through
pendulum test after gait with NMES in patients with
incomplete paraplegia and also showed
improvement in spasticity, observed by RI, like in
the present research.
SpasticityAssessmentthroughPendulumTestinginIndividualswithTetraplegiaUndergoingRehabilitationwith
NeuromuscularElectricalStimulation
93
5 CONCLUSIONS
NMES and treadmill gait with NMES are effective
treatments for spasticity improvement in individuals
with tetraplegia. However, further studies would be
interesting towards differentiating the baclofen use
and NMES.
ACKNOWLEDGEMENTS
The authors would like to thank CAPES (Ministry of
Education, Brazil).
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