RESEARCH Open Access

Quadriceps muscle weakness influences
the gait pattern in women with knee
osteoarthritis
Deborah Hebling Spinoso1,5*, Natane Ceccatto Bellei2, Nise Ribeiro Marques3 and Marcelo Tavella Navega4

Abstract

Background: Osteoarthritis is the most prevalent rheumatic disease in the population and is characterized by
limitation of main functional activities of daily living, as the gait. Muscle strength is a variable that may be related to
performance in daily tasks.Therefore, we to analyze the gait pattern in individuals with knee osteoarthritis (KOA) and
to determine associations of gait variables with the level of muscle strength of knee extensors.

Methods: Sixty-seven female volunteers divided into 2 groups, a KOA group (KOAG, n = 36, 66.69 ± 7.69 years) and
control (n = 31, 63.68 ± 6.97 years), participated in the study. The volunteers walked on a 10-m platform at their
usual gait speed, using 2 pressure sensors positioned at the base of the hallux and calcaneus. The mean step time,
support and double support times, swing time and gait speed were calculated. The evaluation of the quadriceps
isometric torque was performed in an extensor chair, with hip and knee flexion at 90°. The procedure consisted of
three maximal contractions of knee extension. Peak torque was determined by the highest torque value obtained
after the onset of muscle contraction. For statistical analysis, one-way ANOVA and Pearson’s correlation were used,
with p < 0.05.

Results: The KOAG had a 54.76% longer support time, a 13% longer step time (p < 0.001), a 30% decrease in swing
time (p < 0.001) and a 10.7% decrease in gait speed (p = 0.001) compared with controls. The quadriceps isometric
torque was 34% (p = 0.001) lower in the KOAG. There was a correlation between kinematic variables and quadriceps
torque.

Conclusion: Weakness of the quadriceps muscle in women with KOA influences gait pattern, resulting in reduced
speed associated with a shorter swing time and longer support time.

Keywords: Kinematics, Torque, Falls

Background
Osteoarthritis (OA) is the most prevalent rheumatic dis-
ease in the population, characterized by progressive de-
generation of cartilage and periarticular tissue, which
results in changes in joint mechanics and may result in
functional disability [1]. OA has a high incidence in the
population; at least 30% of men and women over 65 years
old have some radiographic alterations, and one-third of
them are symptomatic [2]. In addition, in the age group

of over 75 years old, the incidence increases to 85% be-
cause the older the population, the greater the number
of individuals affected by the disease [3].
It is estimated that 4% of the Brazilian population has

OA in at least one joint [4]. In 37% of these cases, the
knee is the main affected region because in occupational
and leisure activities, it is exposed to maximal compres-
sive loads that can exceed three times that produced by
the individual’s body weight during walking. This stress
favors high injury rates and cartilage degeneration, con-
tributing to a greater incidence of OA in this joint [4].
Approximately 25% of individuals with knee osteoarth-

ritis (KOA) cannot perform the main activities of daily
living due to pain, muscle weakness, reduced balance,

* Correspondence: deborahebling@yahoo.com.br
1Department of Physical Education, São Paulo State University, UNESP, Rio
Claro, SP, Brazil
5Departamento de Fisioterapia e Terapia Ocupacional, Universidade Estadual
Paulista, Avenida Hygino Muzzi Filho, 737, CEP, Marília, SP 17525-000, Brazil
Full list of author information is available at the end of the article

Advances in Rheumatology

© The Author(s). 2018 Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0
International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and
reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to
the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver
(http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Spinoso et al. Advances in Rheumatology  (2018) 58:26 
https://doi.org/10.1186/s42358-018-0027-7

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proprioception deficits, reduced joint range of motion
and joint instability [5, 6]. Among the possible limita-
tions caused by KOA, gait difficulty has great clinical
relevance because it is the most performed daily life ac-
tivity and ensures functional independence [7].
The gait is a complex task and requires a perfect har-

mony of the sensory, motor and cognitive systems to
produce a stable, efficient and safe gait pattern [8]. Bio-
mechanical gait pattern changes, such as reduction of
gait speed, step length and width, increase of the double
support phase time, shorter swing phase time and reduc-
tion of heel contact with the ground, among other pa-
rameters, can be observed through kinematic gait
analysis [8]. These gait pattern changes are often re-
ported in the elderly, and the causes are multifactorial,
but the main factor related to gait performance is de-
creased muscular strength of the lower limbs [9].
In individuals with KOA, the reduction of the knee ex-

tensor strength has been noted as the main symptom of
the disease because there is a reduction of approximately
50–60% of quadriceps maximum torque in relation to
the young population, possibly resulting from atrophy by
disuse, secondary to joint pain and arthrogenic muscle
inhibition [10–12]. This loss of strength is more signifi-
cant than that presented by the healthy population in
the same age group that reaches 30 to 40% of maximum
capacity [12]. The quadriceps weakness observed in this
population can decrease the shock absorption capacity
during walking, leading to accentuated symptoms and,
consequently, gait pattern alteration as a strategy to
minimize pain and maintain functionality [9, 13].
Previous studies have noted that the quadriceps is one

of the main muscle groups responsible for increasing
gait speed and has an important role in maintaining
functional mobility. Weakness of this muscle group may
be responsible for increased metabolic expenditure dur-
ing functional activities, which limits the intensity and
duration of these tasks [14, 15]. Therefore, reduced abil-
ity to generate quadriceps strength, characteristic in pa-
tients with KOA, can negatively affect gait pattern, with
a greater probability of becoming dependent on daily
tasks, which leads to a decrease in quality of life and an
increase in public expenditures to care services for this
population [12, 13].
In this sense, gait analysis in patients with KOA

can help identify changes in the gait pattern caused
by the disease and, consequently, can help guide
treatment and prevention programs for functionality
loss in this population. The aim of the present study
was to analyze the gait patterns of healthy individuals
with KOA and to test for associations of gait vari-
ables with the strength level of the knee extensor
muscles. We hypothesize that individuals with KOA
will show decreased gait speed and swing time and

longer step time in relation to controls and that these
modifications are associated with lower knee extensor
muscle strength in this population.

Methods
Subjects
Seventy-one female subjects, divided into a knee osteo-
arthritis group (KOAG) and a control group (CG), par-
ticipated in this study. For the KOAG (n = 38, 66.4 ±
7.6 years), the individuals presented radiological diagno-
sis of tibiofemoral OA, confirmed according to the cri-
teria of the American College of Rheumatology, and
with grades II-III, based on the radiological grading scale
of osteoarthritis described by Kellgren-Lawrence and
WOMAC [16] pain scores greater than 21. For the CG
(n = 31, 64.5 ± 7.1 years), the subjects had no history of
changes related to chronic-degenerative diseases in the
lower limbs. The sample size was determined by the
G*Power program and was based on data obtained from
pilot studies (effect = 0.85, power = 0.95, error α = 0.05,
sample N = 15).
The eligibility criteria for this study were as follows:

age between 50 and 75 years, able to walk without gait
devices and no other rheumatic diseases in the lower
limbs, patellofemoral osteoarthritis, total or partial knee
and/or hip arthroplasty, lesions in the lower limbs in the
6 months preceding the study or other diseases that
made it impossible to perform the tests.
The present study was approved by the local ethics

committee (n. 9032/2015), and obtained written in-
formed consent from the patients for publication of data
and images.

Evaluation procedures
The procedures for data collection were performed on 2
days, with an interval of two to 7 days between the col-
lection days [17]. On the first day, anamnesis was per-
formed to characterize the sample according to the
anthropometric data and applying the WOMAC ques-
tionnaires to the KOAG. Subsequently, subjects were fa-
miliarized with isometric knee torque evaluation. On the
second day, the isometric muscle strength of the knee
and the gait were evaluated.

Gait evaluation
The gait evaluation was performed on a 14-m-long and
2-m-wide catwalk, with the first 2 m and the last 2 m of
the catwalk being disregarded for data analysis to avoid
possible influences from the gait acceleration and decel-
eration process [18, 19].
After being familiarized with the gait test, the volun-

teers were instructed, through verbal stimulation, to
walk on the catwalk at the speed they performed their

Spinoso et al. Advances in Rheumatology  (2018) 58:26 Page 2 of 6



daily activities [20, 21]. Five attempts to evaluate the gait
were performed.
FootSwitch (Noraxon®) pressure sensors positioned bi-

laterally on the calcaneus and at the hallux base were
used to determine gait phases, as shown in Fig. 1.

Evaluation of knee extensor torque
The evaluation of knee extensor torque was performed
on the affected lower limb for KOAG and on the domin-
ant lower limb for the CG. Before the beginning of the
evaluation protocol, a familiarization with the equip-
ment, consisting of 2 submaximal contractions and 2
maximal contractions of the muscle group to be evalu-
ated, was performed [22]. There was a 5-min interval

between the familiarization and the beginning of the
data collection procedures to avoid fatiguing the evalu-
ated muscle group.
The evaluation protocol consisted of 3 maximal volun-

tary isometric contractions for the movement of the
knee joint extension for a period of 5 s, with a 30-s
interval between each contraction [23]. The volunteers
were seated in the chair extensor with hip and knee at
90° flexion (0° of full extension). The trunk and the
contralateral lower limb were stabilized by belts. A load-
ing cell (Noraxon®) was coupled to the extensor chair
lever for acquiring joint torque data. Figure 2 shows the
positioning of the volunteer. The volunteers were
instructed and encouraged to perform the movement as
strongly and as quickly as possible.
The calculation of knee extensor torque was calculated

from the following equation:

Knee extensor torque ¼ Force Nð Þ x Distance
� sen 90o

Data analysis
Cardoso, B.C et al. [24]for gait data analysis, 40 steps
and a 4th-order Butterworth filter with a cutoff fre-
quency of 6 Hz were used. The mean step time (i.e., the

Fig. 1 Positioning of pressure sensors for gait analysis

Fig. 2 Positioning of the volunteer for evaluation of muscle torque

Spinoso et al. Advances in Rheumatology  (2018) 58:26 Page 3 of 6



time between the touch of the right calcaneus until the
same limb touched the ground again), support time (i.e.,
the time between the touch of the right calcaneus and
the touch of the hallux of the same limb), swing time
(i.e., the time between removal of the right hallux and
the next touch of the calcaneus of the same limb),
double support time and gait speed were calculated.
Muscle torque data were processed in routines devel-

oped in the Matlab environment (Mathworks®) using a
4th-order Butterworth filter with cutoff frequency of
15 Hz [25]. Torque data were normalized for the volun-
teers’ body mass. Peak torque was determined from the
highest torque value obtained after the onset of muscle
contraction.

Statistical analysis
For statistical analysis, the program PASW statistics
18.0® (SPSS) was used. After verifying the normality of
the data, one-way ANOVA for comparisons between the
groups and Pearson’s correlation were applied, consider-
ing p < 0.05.

Results
Table 1 presents the characteristics of the study partici-
pants. There were no differences between groups for an-
thropometric characteristics. Regarding the limb affected
by the disease, 32 volunteers presented diagnosis in the
dominant limb and 6 in the non-dominant limb.
The one-way ANOVA showed a significant difference

between the groups, with the KOAG presenting a
54.76% (p < 0.001) greater support time and a greater
step time (p < 0.001). In addition, the swing time and
the gait speed were 30% (p < 0.001) and 10.7% (p =
0.001) lower, respectively, than those of the control vol-
unteers. The double support time in the KOAG was 33%
greater than the CG (p = 0.02), as shown in Table 2.
Regarding the muscle torque of knee extensors, the

KOAG presented a 34% (p = 0.001) reduction in peak
torque compared with healthy individuals.

There were correlations between the knee extensor
torque and the support time (r = − 0.552, p = 0.03), step
time (r = − 0.492, p = 0.017) and gait speed (r = 0.442, p
= 0.04), as shown in Table 3.

Discussion
The results of this study corroborate the initial hypoth-
eses that individuals with KOA show impairments in all
gait kinematic parameters compared with healthy volun-
teers, and these biomechanical changes are correlated
with knee extensor weakness.
Changes in the movement patterns during gait occur

with advancing age and are well established in the litera-
ture. However, in individuals with KOA, these changes
are more pronounced and have a negative impact on the
independence level in performing daily tasks [9]. Muscle
pain and weakness are the main symptoms of the disease
associated with changes in the spatial-temporal gait pa-
rameters that aim to minimize pain and protect the knee
joint [9]. In the present study, women in the KOAG had
a 34% decrease in knee extensor strength compared with
the control. According to Park et al. [12], the muscle
strength deficit in KOA affects all lower limbs and is
more pronounced in the knee extensors, being 40%
lower in relation to individuals of the same age group
without KOA. Strength levels also showed a negative
correlation with support/step time, indicating that
muscle weakness results in gait temporal changes that
lead to reduced gait speed. These findings corroborate
studies by Resende et al. (2011) and Feber et al. (2016),
who observed that gait pattern changes are associated
with knee pain symptoms and weakness of the anterior
thigh muscles [10, 11, 26].

Table 1 Sample characterization

KOAG (n = 38) CG (n = 33) P

Age (years) 66.49 ± 7.64 64.52 ± 7.12 0.36

Body weight (kg) 76.51 ± 14.77 67.42 ± 11.39 0.22

Height (m) 1.56 ± 0.06 1.55 ± 0.05 0.88

BMI (kg/m2) 31.01 ± 4.86 27.94 ± 4.58 0.96

WOMAC questionnaire

Pain intensity (0–20) 8.87 ± 2.93 0.33 ± 0.56 < 0.001*

Stiffness (0–8) 3.08 ± 1.61 0 < 0.001*

Physical fitness (0–68) 30.70 ± 6.06 5.70 ± 2.33 < 0.001*

Total (0–96) 42.66 ± 8.61 6.04 ± 2.36 < 0.001*

Mean values ± standard deviation, KOAG knee osteoarthritis group, CG control
group, kg kilograms, m meters

Table 2 Comparison of gait kinematic variables and quadriceps
strength in subjects with KOA and healthy subjects

KOA Healthy subjects P

Speed (m/s) 1.00 ± 0.13 1.12 ± 0.15 0.001

Support time (s) 0.65 ± 0.20 0.42 ± 0.10 < 0.001

Swing time (s) 0.42 ± 0.13 0.60 ± 0.13 < 0.001

Step time (s) 1.13 ± 0.12 1.00 ± 0.10 < 0.001

Knee extensor torque (Nm/kg) 0.96 ± 0.35 1.44 ± 0.42 0.001

Mean values ± standard deviations, m meters, s seconds, Nm/kg Newton
meters per kilogram

Table 3 Correlation between knee extensor torque and gait
variables

Support time Step time Swing time Gait speed

Torque

R2 −0.552 − 0.492 − 0.318 0.442

P 0.003 0.017 0.08 0.04

Spinoso et al. Advances in Rheumatology  (2018) 58:26 Page 4 of 6



According to Ploutz-Snyder et al. [27] and Manini et
al. (2010), individuals with knee extensor torque values
below 1.5 Nm/kg are classified as having mobility limita-
tions and difficulty in performing daily tasks due to less
capacity to generate force in the quadriceps [27, 28]. In
the present study, the volunteers with KOA showed ex-
tensor torque values that were 36% below the threshold
proposed by those authors, and the CG presented values
that were 4% below proposed values, which indicates
greater functionality impairment of these individuals ob-
served through the score obtained in the WOMAC
questionnaire.
The muscles around the knee produce movement but

also provide stability and control the load imposed on
the joint; therefore, these muscles are related to the de-
velopment and progression of KOA [12, 29, 30]. Accord-
ing to Kean et al. [31], maximal knee joint loads during
gait occur because of muscle weakness, especially of
knee extensors, which compromise the lower limb decel-
eration function before contact with the ground to re-
duce impact. Therefore, the strategy adopted by KOA
patients is to reduce gait speed.
According to Kaufman et al. [32], patients with KOA

tend to walk at slower speeds and with greater joint stiff-
ness to avoid high external joint movements on the
joint, i.e., the gait speed reduction is a strategy to de-
crease the vertical component of the soil reaction force
imposed on the knee joint, reducing the functional de-
mand in this joint. The lower usual gait speed observed
in the KOAG can be considered a compensatory re-
sponse to reduce joint stress during movement.
The literature establishes an ideal value for gait speed

of 1.2–1.4 m/s to perform daily tasks, including street
crossing [33]. The women with KOA who participated
in the present study had an average speed below the
threshold value for what is considered safe, corroborat-
ing the findings of Tas et al. [34] and Gill et al. [35],
which point to this speed reduction in KOA as a risk
factor for future falls, functional decline and mortality in
this population.
Modifications in the gait kinematic pattern may also

justify the speed reduction observed in the KOAG.
The decrease in the swing time observed in the
KOAG (30% lower) is in agreement with Bennell et
al. (2013), who mentioned that the shorter swing time
is due to weakness of the knee extensor muscles,
which are not able to provide dynamic stability dur-
ing the total weight placed over the limb at that gait
phase. However, the increases in support time, step
time and double support may be related to the possi-
bility of generating a greater load distribution in the
healthy limb. However, this compensatory response
may contribute to joint wear and tear in the long
term. According to Resende et al. (2011), if

individuals with KOA stayed in the support phase
longer, it is possible that the prolonged effect of a
minor overload would be close to the short effect of
an intense joint stress, i.e., the protective neuromus-
cular response may cause pain and joint damage.
Thus, when the strategy of the movement changes
due to pain or reduced capacity to stabilize a seg-
ment, joint overloads and early fatigue occur [13].
The limitations of this study are related to the ap-

proach involving only the knee extensor muscles, as this
muscular group is the most affected by the disease.
However, it is known that muscular weakness affects the
entire lower limb, and studies by Bennell et al. (2010)
and Amiri et al. [29] emphasize the importance of the
hip abductor muscles and plantar flexors, respectively, in
the gait pattern of individuals with KOA as a strategy to
compensate for the deficit of quadriceps strength. There-
fore, future studies should include other muscle groups
of the lower limb to better understand the biomechan-
ical gait changes in KOA.

Conclusion
There is a potential relationship between gait kinematic
variables and knee extensor strength, and the weakness
of the quadriceps muscle influences the gait pattern in
individuals with KOA. This relationship results in the re-
duction of gait speed, associated with greater support/
step time and shorter swing time. Given that KOA has
no cure and changes in gait are progressive and increase
as the degenerative disease progresses, this study aims to
contribute to directing physiotherapeutic interventions
in KOA treatment by identifying the relationships be-
tween knee extensor strength and gait kinematic vari-
ables. Thus, physiotherapy can develop strategies
focused on lower limb strength training, with a greater
emphasis on the quadriceps muscle, which is more com-
promised in this population, and on activities that aim at
gait training, seeking a better distribution of body weight
in both limbs and improvements of range of motion and
muscle recruitment, thereby improving the performance
of the individual during daily tasks and contributing to
slow down the progression of OA.

Acknowledgements
The authors appreciate the participation of all the volunteers of this research
and financial support FAPESP.

Funding
The São Paulo Research Foundation (FAPESP) for financial support.

Availability of data and materials
Data from this manuscript will be available upon request.

Authors’ contributions
Data Collection: D.H. Spinoso and N.C. Bellei. Data Analysis: D.H. Spinoso,
N.C.Bellei, N.R. Marques. Manuscript Writing: D.H. Spinoso, N.R. Marques, and
M.T. Navega. The authors further declare that this manuscript was approved
for publication in the Brazilian Journal of Rheumatology.

Spinoso et al. Advances in Rheumatology  (2018) 58:26 Page 5 of 6



Ethics approval and consent to participate
This study were approved by the Ethics and Research Committee of the
State University of São Paulo (1.503.496/2015) and all participants gave their
written informed consent to participate and publication of the data.

Consent for publication
The authors agree with the publication of this manuscript in the jornal
Advances in Rheumatology and were fully involved in the study and
preparation of the manuscript (below we detailed the part played by each
author).

Competing interests
The authors declare that none had any conflict of interest which could bias
the results of this study and the material in this manuscript has not been
and will not be submitted for publication elsewhere.

Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in
published maps and institutional affiliations.

Author details
1Department of Physical Education, São Paulo State University, UNESP, Rio
Claro, SP, Brazil. 2Department of Physiotherapy and Occupational Therapy,
São Paulo State University, UNESP, Marília, SP, Brazil. 3Department of Health
Sciences, University of the Sacred Heart, USC, Bauru, SP, Brazil. 4Lecturer in
Musculoskeletal Physiotherapy Department of Physiotherapy and
Occupational Therapy, São Paulo State University, UNESP, Marília, SP, Brazil.
5Departamento de Fisioterapia e Terapia Ocupacional, Universidade Estadual
Paulista, Avenida Hygino Muzzi Filho, 737, CEP, Marília, SP 17525-000, Brazil.

Received: 3 July 2018 Accepted: 3 August 2018

References
1. Lim J, Tchai E, Jang SN. Effectiveness of aquatic exercise for obese patients

with knee osteoarthritis: a randomized controlled trial. Am Acad Phys Med
Rehabil. 2010;2(8):723–31.

2. Fernandes WC, Machado A, Borella C, Carpes F. Influência da velocidade da
marcha sobre a pressão plantar em sujeitos com osteoartrite unilateral de
joelho. Rev Bras Reumatol. 2014;54(6):441–5.

3. Neto EMF, Queluz TT, Freire BF. Atividade física e sua associação com
qualidade de vida em pacientes com osteoartrite. Rev Bras Reumatol. 2011;
51(6):539–49.

4. Senna ER, De Barros AL, Silva EO, Costa IF, Pereira LV, Ciconelli RM, et al.
Prevalence of rheumatic diseases in Brazil: a study using the COPCORD
approach. J Rheumatol. 2004;31(3):594–7.

5. Jorge RT, Souza MC, Chiari A, Jones A, Fernandes AD, Junior IL, et al.
Progressive resistance exercise in women with osteoarthritis of the knee: a
randomized controlled trial. Clin Rheabil. 2014;29(3):234–43.

6. Edmonds DW, Mcconnell J, Ebert JR, Ackland TR, Donnelly CJ.
Biomechanical, neuromuscular and knee pain effects following therapeutic
knee taping among patients with knee osteoarthritis during walking gait.
Clin Biomech. 2016;39:28–43.

7. Alkjaer T, Raffalt PC, Dalsgaard H, Simonsen EB, Petersen NC, Bliddal H, et al.
Gait variability and motor control in people with knee osteoarthritis. Gait
Posture. 2015;42:479–84.

8. Jahn K, Zwergal A, Schniepp R. Gait disturbances in old age. Deutsches
Arteblatt International. 2010;107(17):306–16.

9. Clermont CA, Barden JM. Accelerometer-based determination of gait variability
in older adults with knee osteoarthritis. Gait Posture. 2016;50:126–30.

10. Callahan DM, Tourville TW, Slauterbeck JR, Ades PA, Stevens-lapsley J,
Beynnon BD, et al. Reduced rate of knee extensor torque development in
older adults with knee osteoarthritis is associated with intrinsic muscle
contractile deficits. Exp Gerontol. 2015;72:16–21.

11. Davison MJ, Maly MR, Keir PJ, Hapuhennedige SM, Kron AT, Adachi JD, et al.
Lean muscle volume of the thigh has a stronger relationship with muscle
power than muscle strength in women with knee osteoarthritis. Clin
Biomech. 2017;41:92–7.

12. Park SK, Kobsar D, Ferber R. Relationship between lower limb muscle
strength, self-reported pain and function, and frontal plane gait kinematics
in knee osteoarthritis. Clin Biomech. 2016;38:68–74.

13. Kierkegaard S, Jorgensen PB, Dalgas U, Soballe K, Mechlenburg I. Pelvic
movement strategies and leg extension power in patients with end-stage
medial compartment knee osteoarthritis: a cross-sectional study. Arch
Orthop Trauma Sur. 2015;135(9):1217–26.

14. Abreu SSE, Caldas CP. Velocidade de marcha, equilíbrio e idade: um estudo
correlacional entre idosas praticantes e idosas não praticantes de um
programa de exercícios terapêuticos. Rev Bras Fisioter. 2008;12(4):324–30.

15. Marques NR, LaRoche DP, Hallal CZ, Crozara LF, Morcelli MH, Karuka AH,
Navega MT, Gonçalves M. Association between energy cost of walking,
muscle activation, and biomechanical parameters in older female fallers and
non-fallers. Clin Biomech. 2013;28(3):330–6.

16. Murray AM, Thomas AC, Armstrong CW, Pietrosimone BG, Tevald MA. The
associations between quadriceps muscle strength, power, and knee joint
mechanics in knee osteoarthritis: a cross-sectional study. Clin Biomech.
2015;30:1140–5.

17. LaRoche DP, Millett ED, Kralian RJ. Low strength is related to diminished
ground reaction forces and walking performance in older women. Gait
Posture. 2011;33(4):668–72.

18. Doi T, Yamaguchi R, Asai T, Komatsu M, Makiura D, Shimamura M, Hirata S,
Ando H, Kurosaka M. The effects of shoe fit on gait in community-dwelling
older adults. Gait Posture. 2010;32(2):274–8.

19. Hollman JH, Kovask FM, Kubit JJ, Linbo RA. Age-related differences in
spatiotemporal markers of gait stability during dual task walking. Gait
Posture. 2007;26(1):113–7.

20. Bertucco M, Cesari P. Dimensional analysis and ground reaction forces for stair
climbing: effects of age and task difficulty. Gait Posture. 2009;29(2):326–31.

21. Perry CJ, Kiriella JB, Hawkins KM, Shanahan CJ, Moore AE, Gage WH. The
effects of anterior load carriage on lower limb gait parameters during
obstacle clearance. Gait Posture. 2010;32(1):57–61.

22. Costa RA, Oliveira LM, Watanabe SH, Jones A, Natour J. Isokinetic
assessment of the hip muscles in patients with osteoarthritis of the knee.
Clinics. 2010;65(12):1253–9.

23. Hartmann A, Knols R, Murer K, Bruin ED. Reproducibility of an isokinetic
strength-testing protocol of the knee and ankle in older adults.
Gerontology. 2009;55(3):259–68.

24. Cardoso, B.C.; Pimentel, N.L.; Bellei, N.C.; Nishiomoto, D.N.; Navega, M.T.; Spinoso,
D.H. Efeito da bandagem elástica na ativação muscular do quadríceps e torque
isométrico dos extensores de joelho em indivíduos com osteoartrite de joelho.
Revista Brasileira de Educação Física e Esporte, jan/mar, 2017.

25. Crozara LF, Morcelli MH, Marques NR, Hallal CZ, Spinoso DH, Neto AA, et al.
Motor readiness and joint torque production in lower limbs of older
women fallers and non-fallers. J Electromyogr Kinesiol. 2013;23(5):1131–8.

26. Ferber R, Kobsar D, Park S. Relationship between lower limb muscle
strength, self-reported pain and function, and frontal plane gait kinematics
in knee osteoarthritis. Clin Biomech. 2016;38:68–74.

27. Ploutz-Snyder LL, Manini T, Ploutz-Snyder RJ, Wolf DA. Functionally relevant
thresholds of quadriceps Femoris strength. J Gerontol. 2002;57(4):144–52.

28. Manini TM, Newman AB, Fielding R, Blair SN, Perri MG, Anton SD, et al.
Effects of exercise on mobility in obese and nonobese older adults. Obesity
(Silver Spring). 2011;18(6):1168–75.

29. Amiri P, Hubley-Kozey CL, Landry SC, Stanish WD, Astephen-Wilson JL.
Obesity is associated with prolonged activity of the quadriceps and
gastrocnemii during gait. J Electromyogr Kinesiol. 2015;25(6):951–8.

30. Hodges PW, Van Den HW, WRigley TV, Hinman RS, Bowles KA, Cicuttini F, et al.
Increased duration of co-contraction of medial knee muscles is associated with
greater progression of knee osteoarthritis. Man Ther. 2016;21:151–8.

31. Kean CO, Hinman RS, Wrigley TV, Lim BW, Bennell KL. Impact loading
following quadriceps strength training in individuals with medial knee
osteoarthritis and varus alignment. Clin Biomech. 2017;42:20–4.

32. Kaufman KR, Hughes C, Morrey BF, Morrey M, An K. Gait characteristics of
patients with knee osteoarthritis. J Biomech. 2001;34(7):907–15.

33. Lui B, Hu X, Zhang Q, Fan Y, Li J, Zou R, Zhang M, et al. Usual walking
speed and all-cause mortality risk in older people: A systematic review and
meta-analysis. Gait Posture. 2016;44:172–7.

34. Tas S, Güneri S, Baki A, Yildirim T, Kaymak B, Erden Z. Effects of severity of
osteoarthritis on the temporospatial gait parameters in patients with knee
osteoarthritis. Acta Orthop Traumatol Turc. 2014;48(6):635–41.

35. Gill SV, Hicks GE, Zhang Y, Niu J, Apovian CM, White DK. The association of
waist circumference with walking difficulty among adults with or at risk of
knee osteoarthritis: the osteoarthritis initiative. Osteoarthritis Cartilage. 2017;
25(1):60–6.

Spinoso et al. Advances in Rheumatology  (2018) 58:26 Page 6 of 6


	Abstract
	Background
	Methods
	Results
	Conclusion

	Background
	Methods
	Subjects
	Evaluation procedures
	Gait evaluation
	Evaluation of knee extensor torque
	Data analysis
	Statistical analysis

	Results
	Discussion
	Conclusion
	Acknowledgements
	Funding
	Availability of data and materials
	Authors’ contributions
	Ethics approval and consent to participate
	Consent for publication
	Competing interests
	Publisher’s Note
	Author details
	References