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Revista de la Facultad de Medicina

versión impresa ISSN 0120-0011

rev.fac.med. vol.69 no.2 Bogotá abr./jun. 2021  Epub 30-Jun-2021

https://doi.org/10.15446/revfacmed.v69n2.85599 

Original papers

Therapeutic effect of two muscle strengthening programs in patients with patellofemoral pain syndrome. A randomized controlled clinical trial

Efecto terapéutico de dos programas de fortalecimiento muscular en pacientes con síndrome de dolor pátelofemoral. Ensayo clínico controlado aleatorizado

Luisa Fernanda Prieto-García1  2  * 
http://orcid.org/0000-0002-0412-5308

Edgar Cortés-Reyes1  3 
http://orcid.org/0000-0002-3775-846X

Gilberto Lara-Cotacio4  5 
http://orcid.org/0000-0002-7726-4632

Lizeth Catherine Rodríguez-Corredor6 
http://orcid.org/0000-0002-1338-3405

1 Universidad Nacional de Colombia - Bogotá Campus - Faculty of Medicine - Department of Human Body Movement - Bogotá D.C. -Colombia.

2 Fundación Santa Fe de Bogotá - Institute of Physical Medicine and Rehabilitation - Bogotá, D.C. - Colombia.

3 Universidad Nacional de Colombia - Bogotá Campus - Faculty of Medicine - Institute of Clinical Research - Bogotá D.C. - Colombia.

4 Caja de Compensación Familiar CAFAM - Clínica CAFAM - Bogotá, D.C. - Colombia.

5 Hospital Universitario Nacional de Colombia - Orthopedics - Bogotá D.C. - Colombia.

6 Fundación Universitaria de Ciencias de la Salud (FUCS) - Faculty of Medicine - Physical Therapy Program - Bogotá D.C. - Colombia.


Abstract

Introduction:

Patellofemoral pain syndrome (PFPS) is one of the most common musculoskeletal disorders affecting the knee joint. Conservative treatment reduces pain and improves functional capacity in the short and medium-term.

Objective:

To determine the therapeutic effect of two muscle strengthening exercise programs in patients with PFPS from Bogotá, Colombia, aged between 15 and 40 years.

Materials and methods:

Experimental randomized controlled clinical trial conducted in 40 patients with PFPS from Bogotá, Colombia, aged 15-40 years, with a mild to moderate level of physical activity. Participants were randomly distributed into 2 intervention groups: Group A: 8-week-long core, hip and knee muscles strengthening exercises program; Group B: 8-week-long hip and knee muscles strengthening exercises program. The level of pain was measured using the Visual Analog Scale and the Kujala Anterior Knee Pain Scale.

Results:

The addition of core muscle strengthening exercises to the traditional treatment improved the quality of life of participants in the intervention group A, where a significant reduction of pain, with a statistically significant difference in the total score of the Kujala scale (p=0.025) was observed.

Conclusions:

Including core muscle strengthening exercises in the conservative management of PFPS increases its effectiveness to reduce pain and improve the quality of life of these patients.

ClinicalTrials.gov Identifier:

NCT04011436

Keywords: Exercise; Patellofemoral Pain Syndrome; Chondromalacia Patellae; Abdominal Muscles (MeSH)

Resumen

Introducción.

El síndrome de dolor pátelofemoral (SPF) es una de las alteraciones musculoesqueléticas más frecuentes que afectan la articulación de la rodilla. El tratamiento conservador reduce el dolor y mejora la capacidad funcional en el corto y mediano plazo.

Objetivo.

Establecer el efecto terapéutico de dos programas de ejercicios de fortalecimiento muscular en pacientes con SPF de Bogotá, Colombia, con edades entre 15 y 40 años.

Materiales y métodos.

Ensayo clínico controlado aleatorio experimental realizado en 40 pacientes con SPF de Bogotá, Colombia, con edades entre los 15 y 40 años, con nivel de actividad física leve a moderada y que fueron distribuidos de forma aleatoria en 2 grupos de intervención: Grupo A: programa de ejercicios de fortalecimiento de los músculos del core, la cadera y la rodilla con una duración de 8 semanas; Grupo B: programa de ejercicios de fortalecimiento de los músculos de la cadera y la rodilla con la misma duración. El nivel de dolor se midió a través de la Escala Visual Analógica y de la Escala de Kujala para dolor patelofemoral.

Resultados.

La adición de ejercicios de fortalecimiento de los músculos del core al tratamiento tradicional mejoró la calidad de vida de los participantes en el grupo de intervención A, donde se observó una reducción significativa del dolor con una diferencia estadísticamente significativa en la puntuación total de la escala Kujala (p=0.025).

Conclusiones.

Incluir ejercicios de fortalecimiento de los músculos del core al manejo conservador del SPF aumenta su efectividad para reducir el dolor y mejorar la calidad de vida de estos pacientes.

ClinicalTrials.gov Identifier:

NCT04011436

Palabras clave: Ejercicio; Síndrome de dolor patelofemoral; Condromalacia de la rótula; Músculos abdominales (DeCS)

Introduction

Patellofemoral pain syndrome (PFPS) is one of the most common musculoskeletal disorders. It causes pain in the front of the knee and usually affects young adults.1-4 PFPS accounts for 11% to 17% of all knee pain cases, and its prevalence in physically active adolescents and adults ranges from 21% to 45% and from 15% to 33%, respectively,5-7 being higher in women, mainly because their Q- angle is higher than in men.2,8-10

There are several therapeutic alternatives to treat this condition, provided that, in patients with PFPS, healing knee pain is essential to improve their participation rates in physical and sports activities, which in turn will help them improve their body functionality and quality of life.11-13 In this sense, conservative (non-surgical) treatment for PFPS, based on physical therapy exercises, may lead to clinically significant pain level reductions, improvement of the knee functional capacity, and functionality recovery in the short and medium-term. However, the best way for a physical therapist to treat this disorder is still unclear; likewise, it is unknown if conservative management should be used with all patients with PFPS.2,4,14,15

Taking this into account, the objective of the present study was to determine the therapeutic effect of two muscle strengthening exercise programs in patients with PFPS (aged 15-45) from Bogotá, Colombia.

Materials and methods:

Study design

An experimental and randomized controlled clinical trial was conducted in 40 individuals (aged 15-40) who were diagnosed with PFPS from 2015 to 2018.

Sample size

In order to calculate sample size, a contrast non-parametric test of medians between two populations, adapted from Hollander et al.,16 and Delicado,17 was used to check the symmetric distribution of the groups. Finally, the table of critical values of the Mann-Whitney U test18 was used and a sample size of 20 individuals was established for each group. Consequently, out of the 60 patients who initially met the inclusion criteria, 40 were randomly distributed into groups A and B.

Study population: Participants were recruited from patients attending a doctor's visit and who were informed about the study by an orthopedic knee specialist. Upon their acceptance, they were referred to the main researcher to formalize their participation process.

Inclusion criteria

  • Being 15 to 40 years old and being diagnosed with PFPS from 2015 to 2018 (confirmed diagnosis through a CT scan of the knee).

  • Living in Bogotá, D.C.

  • Having clinical signs of patellar pain while resting, sitting for an extended period, or doing any following activities: going up or down stairs, jumping, running, squatting, kneeling.

  • Experiencing pain when moving the kneecap or being afraid of moving it at all.

  • Experiencing crepitus when doing squats.

  • Reporting unilateral or bilateral patellofemoral joint alignment complaints that were confirmed through a CT scan.

  • Having mild to moderate physical activity levels.

Exclusion criteria

  • Having a history of patellofemoral dislocation, subluxation or knee osteoarthrosis.

  • Having connective tissue disorders, knee bursitis, torn meniscus, patellar tendinitis, or synovial plica syndrome in the knee.

  • Having osteoarthrosis secondary to congenital diseases.

  • Having ligament or meniscal injuries.

  • Having undergone any type of lower limb orthopedic surgery.

Selection process

From January to June 2018, 86 people were asked to participate in the study, of which 26 were excluded since they did not meet the inclusion criteria: 12 were older than 40 years, 5 were younger than 15 years, 4 had been diagnosed with a condition other than PFPS (knee osteoarthritis), and 5 had undergone a knee surgery. Finally, based on the sample size previously established, out of the 60 participants who met the inclusion criteria, 40 were randomly selected to participate and complete the intervention programs according to the group into which they were classified. The study population selection process is shown in Figure 1.

SNOSE: sequentially numbered, opaque, sealed envelopes. Source: Own elaboration.

Figure 1 Study population selection process. 

Informed consent and ethical considerations

Before participating in the muscle-strengthening exercise programs, all participants (n=60, pilot test and experimental intervention) signed an informed consent. In addition, this study was granted ethical approval by the Research Ethics Committee of the Faculty of Medicine of Universidad Nacional de Colombia, as stated in Minutes 007-078-17 of May 11, 2017. Likewise, all procedures performed were in agreement with the ethical principles for medical research involving human subjects outlined by the Declaration of Helsinki19 and the scientific, technical and administrative standards for health research established in Resolution 8430 of 1993,20 issued by the Colombian Ministry of Health.

Pilot test

A pilot test was conducted in 20 participants who met the inclusion criteria and expressed their willingness to participate in the study, but they were not included in the final sample due to the size previously established (20 participants per group). It should be noted that all patients who met the inclusion criteria (n = 60) were randomly selected to be part of the experimental study or the pilot test using the sequentially numbered, opaque, sealed envelopes (SNOSE) method,21 and that said method was also used for group distribution. Taking this into account, participants selected for the pilot test were randomly assigned to both intervention groups: A (n=10) and B (n=10). The pilot test lasted 4 weeks and it was used to standardize the strengthening exercise protocol by identifying the degree of difficulty of the exercises, the execution speed, the characteristics of the rest periods to be implemented between each exercise series and the commands to be used to ask participants to start performing each exercise series. It must be noted that none of data collected during this phase was considered for statistical analysis. The prescription of the exercises was adjusted after conducting the pilot test, taking into account the training phases and the principles of the prescription.

Additionally, the 20 participants of the pilot test completed the remaining four weeks of the treatment proposed at the start of the study in compliance with the ethical principles established for conducting this study, but only the results of the first month of intervention were analyzed to make the necessary adjustments to the experimental protocol. It should be noted that all the subjects who took part in this study, both in the pilot test and in the experimental protocol, were evaluated at the beginning and at the end of the 8 weeks of intervention by a physical therapist different from the one who carried out the training sessions or physical exercises.

Intervention

All participants (n=40) were randomly distributed into two experimental groups using the SNOSE method (n=20): the intervention group, in which a core muscle, hip and knee muscle strengthening exercise program was implemented (group A, n=20) and the control group, where a hip and knee muscle strengthening exercise program was used (group B, n=20).

Likewise, they were asked to complete each muscle- strengthening exercise program according to the group they were assigned to. Both exercise protocols lasted eight weeks and each session (45 to 60 minutes) consisted of four phases: warming-up, strengthening, neuromuscular training, and stretching (Figure 2).

* Fora detailed description of each exercise, see Prieto-García.22 Source: Own elaboration.

Figure 2 Muscle strengthening exercise programs implemented in each group. 

Exercise sessions took place at the Physical Rehabilitation Center of CAFAM IPS (Health Service Provision Institution) as follows: Three sessions per week during eight weeks, for a total of 24 sessions; each session was attended by the participants in groups of four people and was monitored by a physical therapy specialist, who was in charge of verifying that each exercise was properly performed, as well as teaching them the fundamentals of proper breathing techniques during the first two weeks of the intervention (anatomical conditioning phase), and providing them with feedback throughout the intervention. In addition, this specialist was also responsible for ensuring participants' posture was adequate for performing each exercise, thus avoiding low back pain as a consequence of using the wrong training method and increased intra-abdominal pressure due to inadequate breathing techniques when engaging in strength training.

Participants' adequate hydration during each training session was also ensured and, right before starting the intervention, they were informed about the importance of wearing appropriate footwear and sportswear for training. Also, during the first two weeks of the intervention, they were asked to wear training shorts so that the physical therapist specialist could see the position of their knees while performing the exercises. Then, they were asked to wear ankle length spandex pants to avoid any skin abrasion due to the rubbing effect of the TheraBand™; likewise, they were instructed to bring to the location where the sessions were held only a bottle of water for hydration and a towel to wipe their sweat, and to avoid wearing any item that could cause an injury during the sessions, such as bracelets or necklaces.

Study variables

  • Dependent variable: Anterior knee pain.

  • Independent variables: Muscle strengthening programs: Groups A (core, hip and knee muscles strengthening exercises) and B (hip and knee muscle strengthening exercises only).

  • Intervening variables: Age, sex, BMI, physical activity level, Q-angle, muscle strength, flexibility and unipedal balance.

Anthropometric measurements and assessment of physical activity levels and quality of life

The following anthropometric variables were measured for all participants: height, weight, body mass index (BMI), body fat percentage, muscle mass percentage, visceral fat percentage, basal metabolic rate, and metabolic age. Their level of physical activity was also measured using the International Physical Activity Questionnaire (IPAQ). Furthermore, anterior knee pain was measured using the visual analogue scale (VAS) and the Kujala anterior knee pain scale. The latter scale was used to assess participants' quality of life since this tool is specifically designed to measure the quality of life in people with PFPS by means of 13 questions grouped into 3 domains: pain and physical alteration, limb mobility limitations, and participation in sports activities.

Finally, a Microsoft Excel® sheet was created to record participants' data, including pain assessment, Q angle (right and left knee), core muscle strength, hip and knee muscle strength, muscle length, static balance, and postural assessment.10,23-27

Statistical analysis

Before conducting the statistical analysis, the database (the Microsoft Excel Sheet) was filtered by organizing the data collected according to each study variable. Then, a univariate analysis was performed to determine absolute and relative frequencies, followed by a bivariate analysis to compare the scores obtained in each of the domains of the Kujala scale. Furthermore, the Spearman's correlation coefficient was used to assess the correlation between Q-angle and anterior knee pain.

On the other hand, in order to assess whether there were differences or not regarding the study variables between both groups after completing the intervention, a comparison of the scores obtained after the administration of the Kujala scale and the Visual Analogue Scale (VAS) in both groups and the measurements obtained from the number of squats performed by each participant, their Q-angle, balance data, physical activity levels and core muscles strength measurements, was performed. In addition, normal distribution of data was evaluated using graphical and numerical methods. Finally, two-tailed statistical hypothesis tests were performed using a Cronbach's alpha coefficient of 0.05. STATA 14.0 was used to perform all statistical analysis.

Results

As mentioned above, 40 people with PFPS were randomly distributed into group A (n=20) and group B (n=20); however, only 19 participants of each group were able to complete the intervention program since one person in Group A presented with patellar luxation and a person in Group B withdrew from the study as a result of a concomitant condition that made impossible the proper execution of the exercises. Out of the 40 participants, only 4 (10%) were men; 26 (65%) had normal weight (BMI<25), and 14 (35%) were overweight (BMI≥25). Participants' average age was 32in Group A, and 29 in group B. The basic demographic characteristics of the study population, as well as their baseline (pre-intervention) measurements and scores for each study variable, are shown in Table 1. There were no significant differences between both groups at this stage.

Table 1 Basic demographic data and baseline measurements and scores of the study population by intervention group. 

IPAQ: International Physical Activity Questionnaire; PA: Physical Activity; VAS: Visual Analog Scale.

* CI:95%.

† Mann-Whitney U.

‡ Chi square test.

Source: Own elaboration.

Post-intervention results

Table 2 shows the differences of the medians (post-intervention changes or differences in pain, knee alignment, core muscles, hip and knee strength, and balance) per intervention group for each study variable measured before and after the intervention.

Table 2 Effects of muscle strengthening exercise programs on participants' pain, knee alignment, core, hip and knee strength and balance by intervention groups. 

IPAQ: International Physical Activity Questionnaire; VAS: Visual Analog Scale.

* The Mann-Whitney U test was used to obtain the measurements of the difference of the median between groups.

Source: Own elaboration.

When core muscle strengthening exercises are added to the conservative (non-surgical) management of patients with PFPS or anterior knee pain, their quality of life, measured with the Kujala scale, improves since a significant pain reduction was reported in the present study in the group where these exercises were implemented. In addition, a statistically significant difference (p=0.025) was found between both groups in the total score of the Kujala scale, as participants in group A, in average, scored 5 points more than participants in group B (23.0 vs. 17.0), which shows that patients who were asked to perform core strength exercises had a better outcome regarding the improvement of their quality of life after completing the exercise program.

An increase in core muscle strength was also observed in group A after the intervention, especially in the case of side planks since the holding time in group A increased 30 seconds in average for both sides, while in group B it only increased 7 and 5 seconds in average for the right and left side, respectively, with a statistically significant p-value (p<0.001) in both groups.

On the other hand, differences regarding total pain scores according to the VAS were also observed between both groups: -6 (IQR: (-10)-(-4)) and -4 (IQR: (-7)-(-3)), respectively. Although these differences were not statistically significant, they were clinically relevant. In the case of hip and knee strength, measured through the squat test, no statistically significant differences were found in the median deltas between both groups, yet all participants, regardless of the intervention group they were in, increased their hip and knee strength after completing the program as a result of performing strengthening exercises for these muscle groups.

Discussion

According to the results obtained here, adding core muscle strengthening exercises to conventional management of PFPS (based on hip and knee strengthening exercises) is more effective to reduce pain in these patients than using only hip and knee muscles strength exercises.

Regarding hip and knee muscles strengthening, Neal et al.,28 state that typical exercise interventions performed in rehabilitation centers, and based on the strengthening of the muscles of the knee and the hip, have a positive impact on pain reduction and improve knee functionality, which is similar to the findings of the present study, where, according to the total score of the Kujala scale, all participants in both groups experienced pain reduction after completing the intervention program. Pain reduction in the total score of this scale has also been described in other studies, such as those conducted by Moradi et al.29 and Kettunen et al.30

On the other hand, Behm et al.,24 Anderson et al.,31 and Anh et al.9 have described that balance training using unstable surfaces increases central muscle activation, for activities that emphasize neuromuscular coordination involving the movement of the whole body are effective to increase balance. Therefore, performing unipedal standing balance exercises (when the base of support is reduced) and unilateral exercises increases the superficial muscular activation of core muscles. In this sense, a similar finding was observed in the present study since it was found that posture can be controlled with less effort, better coordination, and greater muscular efficiency after training by activating core and postural muscle. Thus, progressive balance training may improve both bipedal and unipedal balance in middle-aged people, especially in balance exercises done with eyes closed.

Furthermore, Oliver et al.32 reported that trunk extension exercises, performed in prone position, as well as the quadruped superman exercise, produced the highest activation levels in core muscles. These authors also described that single leg bridge exercise caused greater muscular activation of the buttocks, especially the gluteus medius, in the leg used to support the weight of the body.32 This finding was also observed in the last two weeks of the intervention program used in the present study, when these exercises were implemented to increase the activation of core muscles, as reported by Shirey et al.,33 Shirazi et al.,34 and Page.35 This activation was visually confirmed by the physical therapy specialist in charge of monitoring the performance of the exercises by observing the alignment of the pelvis when raising one of the two legs, indicating a greater activation of the gluteal and core muscles when the right hemipelvis was at the same height as the left hemipelvis.

Finally, Rabelo et al.,25 Bily et al.36 and Schneider et al.37 showed that implementing closed kinetic chain exercise programs using a proper proprioceptive input is effective to improve body functionality, reduce pain and make people more independent in terms of body movement. This was confirmed in the present study, as it found that improving the strength of core muscles helped reduce anterior knee pain and improve lumbopelvic rhythm, because participants' skills for performing the exercises improved in the last two weeks of the training program, showing a better quality of movement, especially at the lumbar-pelvic level, compared to their performance in the first week of the intervention. This in turn allowed improving body stability at the central level and, thus, achieving better distal motor control, mainly due to muscle activation.38

In general, the results of the present study are consistent with the findings of Alba-Martín et al. ,39 Nakagawa et al.,40 Gaitonde et al.,41 Motealleh et al.,42 Rabelo et al.,25 and Khayambashi et al.,43 who reported that conservative (non-surgical) treatments that use physical exercises help patients with PFPS by reducing their pain and improving their body functionality, and that those based on external rotators and hip abductor muscle strengthening exercises have better effects than those based only on strengthening exercises for the quadriceps femoris.

Limitations and recommendations

Since some of the participants were not only diagnosed with PFPS but also had other conditions, such as unspecified lumbar pain, they found it difficult to perform certain exercises.

Conclusions

Adding core muscle strengthening exercises to traditional exercise programs for strengthening gluteal muscles, vastus medialis oblique and vastus lateralis of the quadriceps femoris increases the program effectiveness to reduce pain and improve knee functionality in people with PFPS.

Static balance training allows individuals to improve selectively their proprioception at the level of the ankle, the sacroiliac joint and the neck (cervical vertebrae) by reducing the base of support and the available visual information, providing greater stability and neuromuscular control of the lower limbs in daily life activities, such as going up and down stairs.

Preferentially, core muscle strengthening exercises should be included in health rehabilitation or training programs since the activation, coordination and selective control of these muscles may result in greater postural stability, mobility of the upper and lower limbs, and less risk of injury.

Based on the findings of this study, patients with PFPS should continue their core, hip, and knee muscle strengthening exercise program after completing the two-month period outlined here, so that their quality of life improves as they continue to participate in the exercise program.

Acknowledgments

To Cafam (Compensation Fund for Family Allowance) and all the patients who participated in the study, to their relatives for supporting their participation, and to Daniel Rodríguez, Sofía Prieto, David Piñeros and Lizeth Rodríguez who checked and confirmed the validity of the statistic component of this study.

References

1. Selfe J, Janssen J, Callaghan M, Witvrouw E, Sutton C, Richards J, et al. Are there three main subgroups within the patellofemoral pain population? A detailed characterisation study of 127 patients to help develop targeted intervention (TIPPs) . Br J Sports Med. 2016;50(14):873-80. https://doi.org/f8ttm9. [ Links ]

2. Clijsen R, Fuchs J, Taeymans J. Effectiveness of Exercise Therapy in Treatment of Patients With Patellofemoral Pain Syndrome: A Systematic Review and Meta-Analysis. Phys Ther. 2014;94(12):1697-708. https://doi.org/f6s68d. [ Links ]

3. Malek MM, Mangine RE. Patellofemoral pain syndromes: a comprehensive and conservative approach. J Orthop Sport Phys Ther. 1981;2(3):108-16. https://doi.org/f7kf. [ Links ]

4. Selfe J, Callaghan M, Witvrouw E, Richards J, Dey MP, Sutton C, et al. Targeted interventions for patellofemoral pain syndrome (TIPPS): classification of clinical subgroups. BMJ Open. 2013;3(9):e003795. https://doi.org/gb3v3p. [ Links ]

5. Kwon O, Yun M, Lee W. Correlation between Intrinsic Patellofemoral Pain Syndrome in Young Adults and Lower Extremity Biomechanics. J Phys Ther Sci. 2014;26(7):961-4. https://doi.org/f7kg. [ Links ]

6. Nijs J, Van Geel C, Van der auwera C, Van de Velde B. Diagnostic value of five clinical tests in patellofemoral pain syndrome. Man Ther. 2006;11(1):69-77. https://doi.org/cg7725. [ Links ]

7. Crossley KM, Stefanik JJ, Selfe J, Collins NJ, Davis IS, Powers CM, et al. 2016 Patellofemoral pain consensus statement from the 4th International Patellofemoral Pain Research Retreat, Manchester. Part 1: Terminology , definitions , clinical examination, natural history, patellofemoral osteoarthritis and patient-reported outcome. Br J Sports Med. 2017;50(14):839-43. https://doi.org/f7kh. [ Links ]

8. Boling M, Padua D, Marshall S, Guskiewicz K, Pyne S, Beutler A. Gender differences in the incidence and prevalence of patellofemoral pain syndrome. Scand J Med Sci Sport. 2010;20(5):725-30. https://doi.org/bzvt36. [ Links ]

9. Ahn JA, Kim JH, Bendik AL, Shin JY. Effects of stabilization exercises with a Swiss ball on neck-shoulder pain and mobility of adults with prolonged exposure to VDTs. J Phys Ther Sci. 2015;27(4):981-4. https://doi.org/f7kj. [ Links ]

10. Van Der Heijden RA, Lankhorst NE, Van Linschoten R, Bierma-Zeinstra SM. Exercise for treating patellofemoral pain syndrome: and abridged version of Cochrane Systematic Review. Eur J Phys Rehabil Med. 2016;52(1):110-33. [ Links ]

11. Boling MC, Bolgla LA, Mattacola CG, Uhl TL, Hosey RG. Outcomes of a Weight-Bearing Rehabilitation Program for Patients Diagnosed With Patellofemoral Pain Syndrome. Arch Phys Med Rehabil. 2006;87(11):1428-35. https://doi.org/bbzkt4. [ Links ]

12. Witvrouw E, Sneyers C, Lysens R, Victor J, Bellemans J. Reflex response times of vastus medialis oblique and vastus lateralis in normal subjects and in subjects with patellofemoral pain syndrome. J Orthop Sports Phys Ther. 1996;24(3):160-5. https://doi.org/f7kk. [ Links ]

13. Fulkerson JP. Patellofemoral Pain Disorders: Evaluation and Management. J Am Acad Orthop Surg. 1994;2(2):124-32. https://doi.org/f7km. [ Links ]

14. Lee TK, Yun SB, Lee AR, Lee YS, Yong MS. Analysis of vastus lateralis and vastus medialis oblique muscle activation during squat exercise with and without a variety of tools in normal adults. J Phys Ther Sci. 2016;28(3):1071-3. https://doi.org/f7kp. [ Links ]

15. Kwon YJ, Park SJ, Jefferson J, Kim K. The Effect of Open and Closed Kinetic Chain Exercises on Dynamic Balance Ability of Normal Healthy Adults. J Phys Ther Sci. 2013;25(6):671-4. https://doi.org/gg243w. [ Links ]

16. Hollander M, Wolfe DA, Chicken E. Nonparametric Statistical Methods. 3rd ed. New York: John Wiley & Sons, Inc.; 2014. [ Links ]

17. Delicado P. Curso de modelos no paramétricos. Catalunya: Departament d'Estadística I Investigación Operativa Universitad Politécnica de Catalunya; 2008. [ Links ]

18. de Winter J, Dodou D. Five-Point Likert Items: t Test Versus Mann-Whitney-Wilcoxon (Addendum added October 2012)," Practical Assessment, Research, and Evaluation. 2010;15:1-16. https://doi.org/ghnhhf. [ Links ]

19. World Medical Association (WMA). WMA Declaration of Helsinki - Ethical principles for medical research involving human subjects. Fortaleza: 64th WMA General Assembly; 2013. [ Links ]

20. Colombia. Ministerio de Salud. Resolución 8430 de 1993 (octubre 4): Por la cual se establecen las normas cientificas, técnicas y administrativas para la investigación en Salud. Bogotá D.C.: octubre 4 de 1993. [ Links ]

21. Doig GS, Simpson F. Randomization and allocation concealment : a practical guide for researchers. J Crit Care. 2005;20(2):187-91. https://doi.org/cgmmbh. [ Links ]

22. Prieto-García LF. Efecto Terapéutico de dos programas de Fortalecimiento Muscular en Pacientes con Síndrome Pátelofemoral de la Ciudad de Bogotá Colombia; Estudio Experimental, tipo Ensayo Clínico Controlado [tesis]. Bogotá D.C.: Facultad de Medicina, Universidad Nacional de Colombia; 2019 [cited 2021 Apr 19]. Available from: Available from: https://bit.ly/2P72jFc . [ Links ]

23. Kujala UM, Jaakkola LH, Koskinen SK, Taimela S, Hurme M Nelimarkka O. Scoring of patellofemoral disorders. Arthroscopy. 1993;9(2):159-63. https://doi.org/dgpb2v. [ Links ]

24. Behm DG, Drinkwater EJ, Willardson JM, Cowley PM. The use of instability to train the core musculature. Appl Physiol Nutr Metab. 2010;35(1):91-108. https://doi.org/c2r3vg. [ Links ]

25. Rabelo NDDA, Lima B, dos Reis AC, Bley AS, Yi LC, Fukuda TY, et al. Neuromuscular training and muscle strengthening in patients with patellofemoral pain syndrome: a protocol of randomized controlled trial. BMC Musculoskelet Disord. 2014;15:157. https://doi.org/f56fnj. [ Links ]

26. Chevidikunnan MF, Al Saif A, Gaowgzeh R, Mamdouh KA. Effectiveness of core muscle strengthening for improving pain and dynamic balance among female patients with patellofemoral pain syndrome. J Phys Ther Sci. 2016;28(5):1518-23. https://doi.org/f7kr. [ Links ]

27. Jalayondeja W, Kraingchieocharn S. Trunk extensor, flexor and lateral flexor endurance time in sedentary workers aged 20-49 years. J Med Assoc Thail. 2015;98(Suppl 5):S23-8. [ Links ]

28. Neal BS, Barton CJ, Gallie R, Halloran PO, Morrissey D. Runners with patellofemoral pain have altered biomechanics which targeted interventions can modify: A systematic review and meta-analysis. Gait Posture. 2016;45:69-82. https://doi.org/f8fc7r. [ Links ]

29. Moradi Z, Akbari M, Ansari NN, Emrani A, Mohammadi P. Strength of hip muscle groups in sedentary women with pa-tellofemoral pain syndrome. J Back Musculoskelet Rehabil. 2014;27(3):299-306. https://doi.org/f6p2dr. [ Links ]

30. Kettunen JA, Visuri T, Harilainen A, Sandelin J, Kujala UM. Primary cartilage lesions and outcome among subjects with patellofemoral pain syndrome. Knee Surg Sports Traumatol Arthrosc. 2005;13(2):131-4. https://doi.org/fdtt2j. [ Links ]

31. Anderson GS, Deluigi F, Belli G, Tentoni C, Gaetz MB. Training for improved neuro-muscular control of balance in middle aged females. J Bodyw Mov Ther. 2016;20(1):10-8. https://doi.org/f7ks. [ Links ]

32. Oliver GD, Stone AJ, Plummer H. Electromyographic examination of selected muscle activation during isometric core exercises. Clin J Sport Med. 2010;20(6):452-7. https://doi.org/bkbm52. [ Links ]

33. Shirey M, Hurlbutt M, Johansen N, King GW, Wilkinson SG. The Influence of core musculatura engagement on hip and knee kinematics in women during single leg squat. Int J Sport Phys Ther. 2012;7(1):1-12. [ Links ]

34. Shirazi ZR, Moghaddam MB, Motealleh A. Comparative Evaluation of Core Muscle Recruitment Pattern in Response to Sudden External Perturbations in Patients With Patellofemoral Pain Syndrome and Healthy Subjects. Arch Phys Med Rehabil. 2017;95(7):1383-9. https://doi.org/f578q9. [ Links ]

35. Page P. Sensorimotor training: A "global" approach for balance training. Journal of Bodywork and Movement Therapies. 2006;10(1):77-84. https://doi.org/ch434j. [ Links ]

36. Bily W, Trimmel L, Mo'dlin M, Kaider A, Kern H. Training Program and Additional Electric Muscle Stimulation for Patellofemoral Pain Syndrome: A Pilot Study. Arch Phys Med Rehabil. 2008;89(7):1230-6. https://doi.org/brsh63. [ Links ]

37. Schneider F, Labs K, Wagner S. Chronic patellofemoral pain syndrome: Alternatives for cases of therapy resistance. Knee Surg Sports Traumatol Arthrosc. 2001;9(5):290-5.https://doi.org/fpj9xc. [ Links ]

38. Earl JE, Hoch AZ. A proximal Strengthening Program Improves Pain, Function, and Biomechanics in women with Patellofemoral Pain Syndrome. Am Orthop Sport Med. 2011;39(1):154-63. https://doi.org/cf6mt5. [ Links ]

39. Alba-Martín P, Gallego-Izquierdo T, Plaza-MAnzano G, Romero-Franco N, Nuñez-Nagy S, Pecos-Martín D. Effectiveness of therapeutic physical exercise in the treatment of patellofemoral pain syndrome: a systematic review. J Phys Ther Sci. 2015;27(7):2387-90. https://doi.org/f7kt. [ Links ]

40. Nakagawa TH, Muniz TB, Baldon RM, Dias-Machiel CD, de Menezes-Reiff RB, Serrão FV. The effect of additional strengthening of hip abductor and lateral rotator muscles in patellofemoral pain syndrome: a randomized controlled pilot study. Clin Rehabil. 2008;22(12):1051-60. https://doi.org/bzf8t7. [ Links ]

41. Gaitonde DY, Ericksen A, Robbins RC. Patellofemoral Pain Syndrome. Am Fam Physician. 2019;99(2):88-94. [ Links ]

42. Motealleh A, Mohamadi M, Moghadam MB, Nejati N, Arjang N, Ebrahimi N. Effects of Core Neuromuscular Training on Pain, Balance, and Functional Performance in Women With Patellofemoral Pain Syndrome: A Clinical Trial. J Chiropr Med. 2019;18(1):9-18. https://doi.org/f7kv. [ Links ]

43. Khayambashi K, Fallah A, Movahedi A, Bagwell J, Powers C. Posterolateral Hip Muscle Strengthening Versus Quadriceps Strengthening for Patellofemoral Pain: A Comparative Control Trial. Arch Phys Med Rehabil. 2014;95(5):900-7. https://doi.org/f52k32. [ Links ]

Prieto-García LF, Cortés-Reyes E, Lara-Cotacio A, Rodríguez-Corredor LC. Therapeutic effect of two muscle strengthening programs in patients with patellofemoral pain syndrome. A randomized controlled clinical trial Rev. Fac. Med. 2021;69(2):e85599. English. doi: https://doi.org/10.15446/revfacmed.v69n2.85599.

Prieto-García LF, Cortés-Reyes E, Lara-Cotacio A, Rodríguez-Corredor LC. [Efecto terapéutico de dos programas de fortalecimiento muscular en pacientes con síndrome de dolor pátelofemoral. Ensayo clínico controlado aleatorizado]. Rev. Fac. Med. 2021;69(2):e85599. English. doi: http://doi.org/10.15446/revfacmed.v69n2.85599.

Conflicts of interest None stated by the authors.

Funding None stated by the authors

Received: March 21, 2020; Accepted: June 09, 2020

*Corresponding Author: Luisa Fernanda Prieto-García. Departamento de Movimiento Corporal Humano, Facultad de Medicina, Universidad Nacional de Colombia. Bogotá D.C. Colombia. Email: lfprietog@unal.edu.co.

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